Abstract:
In addition to analysis in the infrared spectra of hydrocarbon group types, it has now been found that certain hydrocarbon species, including preferably aromatic species such as benzene, toluene, xylene, and alkyl benzenes such as ethyl benzene, can be determined by measuring absorption in certain selected wavelengths in the infrared spectra, then manipulating the data, e.g., preferably by taking the first or higher derivative, and applying statistical techniques, preferably multiple linear regression (MLR) to provide an output signal indicative of the concentration of the particular specie. The output signal can be used to control refinery and chemical processes, e.g., reforming, catalytic cracking, alkylation and isomerization. In manufacturing reformulated fuels, government regulations can be complied with by utilizing the invention to blend fuels which have a maximum of benzene or other regulated components.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of application Ser. No. 08/305,233, filed 13 Sep. 1994, now abandoned, which is a continuation-in-part of Ser. No. 07/506,391 filed Apr. 9, 1990 now U.S. Pat. No. 5,349,188, issued Sep. 20, 1994, (attorney docket 6362AUS). 
    
    
     U.S. Pat. No. 5,349, 188, issued Sep. 20, 1994 (attorney docket 6362AUS) and U.S. Pat. No. 5,349,189, issued Sep. 20, 1994, (attorney docket 6362BUS) relate to the general field of the present invention. 
     U.S. Pat. No. 5,349,188, issued Sep. 20, 1994, (attorney docket 6362AUS) teaches the determination of octane generally, and U.S. Pat. No. 5,349,189, issued Sep. 20, 1994, (attorney docket 6362BUS) teach the determination of hydrocarbon groups by group type analysis, e.g., &#34;PIANO&#34; or &#34;PIONA.&#34; PIANO (see procedure taught by Analytical Automation Specialists, Inc., &#34;The Detailed Analysis of Petroleum Naphthas, Reformates, Gasoline and Condensates by High-Resolution Gas Chromatography&#34;, operators manual, P.O. Box 80653, Baton Rouge, La. 70898) and PIONA (see e.g., Eberly, Paul E., U.S. Pat. No. 5,322,619) are both gas chromatographic methods which differ in the selection of absorbent columns for the separation. 
     BACKGROUND OF INVENTION 
     I. Field of the Invention 
     The present invention relates to techniques of analysis, particularly of hydrocarbon and substituted hydrocarbon mixtures, generally classified in U.S. Class 250. 
     II. Description of the Prior Art 
     Prior patents in this field include U.S. Pat. No. 4,963,745 to Maggard issued Oct. 16, 1990 (attorney docket 6353AUS); U.S. Pat. No. 5,223,714 to Maggard issued Jun. 29, 1993 (attorney docket 6360AUS); U.S. Pat. No. 5,243,546 to Maggard issued Sep. 7, 1993 (attorney docket 6379AUS); U.S. Pat. No. 5,145,785 to Maggard and Welch issued Sep. 8, 1992 (attorney docket 6384AUS); international application WO 93/24823 published Dec. 9, 1993 (attorney docket 6411APC). 
     U.S. Pat. No. 5,349,188 to Maggard, issued Sep. 20, 1994, (attorney docket 6362AUS) teaches the determination of octane generally, and U.S. Pat. No. 5,349,189 to Maggard, issued Sep. 20, 1994, (attorney docket 6362BUS) teaches the determination of hydrocarbon groups by group type analysis, e.g., &#34;PIANO&#34;. 
     Prior art teachings of the determination of individual hydrocarbon group types such as paraffins, isoparaffins, aromatics, naphthenes, and olefins (PIANO) can be found in prior literature and patents. A preferred technique is gas liquid chromatography, wherein a sample is injected into an absorbent column swept by an elutriating inert gas, e.g., helium and the elapsed time for arrival at the end of the column is measured for each of the components, e.g., by a flame ionization detector, thermal conductivity, or other detector, as shown in Example 11 and FIG. 8. 
     Conventionally, the percents of each of the individual compounds detected by gas chromatography are grouped under their respective generic classifications in the PIANO classification system, and the relative percentage of each of the compounds (species) is determined in weight percent, volume percent, or mol percent as required. An example of this procedure is that taught by Analytical Automated Specialists, Inc., the detailed analysis of a reformate as shown in Example 11 and Table H. 
     These prior techniques normally require hours and neither provides the fast analysis (less than one minute) available from the present invention. The speed of analysis obtainable by the present invention enables on-line control response times not possible with past prior art chromatographic methods. 
     By speciation (determining the content of individual chemical compounds, e.g., benzene, xylenes, toluene), the spectral analysis of the invention can be applied to provide much of the analysis of specific species which formerly was accomplished primarily by conventional gas liquid chromatography, an inherently slow process because of the need to elutriate a sample through the chromatography column to separate it into its individual species. 
     The repeatability, precision and accuracy of spectral analysis would be valuable if it could be applied to speciation (e.g., to determine individually benzene, toluene, xylene, ethyl-benzene, and other desired species). This would be useful in refining the control of reformers which are conventionally controlled by merely measuring octane, or at most, octane and aromatics. By speciation, reformer control could be converted to become more sensitive to individual species. This would be valuable where a reformer is being run for petrochemical products, e.g., xylenes. It would also be valuable where reformulated fuels mandate maximum content of benzene. By analyzing for the specific species, the control can be more delicately balanced and economics further optimized. 
     SUMMARY OF THE INVENTION 
     I. General Statement of the Invention 
     The present invention utilizes a combination of selected NIR wavelengths together with mathematical techniques and statistical techniques in which measurements of absorption are made and combines these with multiple regression analysis, or other statistical technique and modeling to differentiate the concentration of individual hydrocarbon species. The invention is particularly preferred for the determination of the concentration of individual aromatic species such as benzene, toluene, xylene, alkyl benzenes. Particularly preferred is determination of ethyl benzene. Other hydrocarbon species in concentrations above 0.1%, more preferably above 1.0%, can be determined. 
     Species Concentration Measurement 
     The techniques of the present invention are highly useful for the determination of hydrocarbon species, preferably such as aromatic, paraffin, isoparaffin or olefin species by: 
     a. measuring at at least one wavelength the near infrared absorbance in the bands of: 
     1. For benzene: 2100-2160 nanometers (nm) and/or 1600-1670 nm and/or 1780-1858 nm; and/or 1120-1260 nm; and/or 850-925 nm; 
     2. For toluene: 1600-1670 nm and/or 1780-1858 nm and/or 1214-1230 nm; and/or 2000-2160 nm; and/or 860-910 nm; and/or 975-1000 nm; 
     3. For xylenes: 1320-1530 nm and/or 2000-2040 nm and/or 1600-1670 nm; and/or 1120-1214 nm; and/or 1780-1858 nm; and/or 2100-2160 nm; and/or 850-930 nm; and/or 940-990 nm; and/or 1015-1045 nm; 
     4. For alkyl benzenes: 1156-1264 nm; and/or 1600-1670 nm; and/or 1214-1230 nm; and/or 1320-1480 nm; and/or 850-900 nm; and/or 1015-1045 nm; and/or 1214-1264 nm, and/or 1970-2040 nm; more preferably 1214-1264 nm and 1970-2040 nm; 
     5. For n-pentane, n-hexane n-heptane and/or other n-paraffins: 1156-1264 nm; and/or 1320-1480 nm; and/or 1600-1670 nm; and/or 1780-1858 nm; and/or 1940-2100 nm; 
     6. For isopentane, 2-methyl hexane, 2,2-dimethylbutane, 2,3-dimethylbutane, 2-methylpentane, 3-methylpentane and/or other isoparaffins: 1156-1264 nm; and/or 1320-1500 nm; and/or 1560-1670 nm; and/or 1780-1858 nm, and/or 1900-2160 nm; 
     7. For methylcyclopentane and/or other naphthenes: 1156-1430 nm; and/or 1780-1858 nm; 
     8. For isobutylene and/or other olefins: 1132-1214 nm; and/or 1600-1670 nm; 
     b. taking each of the absorbances measured, or a mathematical function thereof; 
     c. performing multiple regression analysis, partial least squares analysis, or other statistical treatment using the above absorbances or functions as individual independent variables, 
     d. assigning and applying weighting constants or their equivalents to said independent variables, 
     e. applying the above steps using known compositions to calibrate the instrument and determine said weighting constants or equivalents, 
     f. repeating said steps with unknown compositions, applying the weighting constants or equivalents determined during said calibration with known compositions. 
     The hydrocarbon compositions may flow substantially intermittently or continuously past the point where the measurements are being made. The mathematical function may be a first, second, or third or higher derivative of said absorption of said band being measured, the hydrocarbon stream being measured may preferably be a reformer product stream, a catalytic cracker product stream, a gasoline blending component, or a blended gasoline product stream, and the species measured may preferably be benzene, toluene, xylenes, alkyl benzenes, most preferably ethyl benzene, and may also be h n-propyl benzene, heptane, and hexane. 
     As discussed briefly below and in the copending applications aforementioned, the signal may control a fuel blending system feeding blending components having different benzene contents into a common zone, whereby a fuel product having a desired benzene product is produced, or may control blending under a different species other than benzene, e.g., ethyl benzene or xylene, etc. 
     Signal Processing 
     As those skilled in the art will be aware, the absorbance signal from the measurement of the characteristic hydrocarbon species bands, used either solely or in conjunction with other bands, will preferably be mathematically processed to provide derived signals which are indicative of the concentrations (or property) being measured. Preferred techniques for mathematical processing are absorbance base line off-set corrected absorbance data; taking the first, second, third, fourth or higher derivative of the absorbance spectrum; the technique of dividing the absorbance at one wavelength by another; spectral subtraction; and various combinations of these mathematical techniques. Also valuable are the well-known curve fitting techniques of Savitsky-Golay and Kubelka-Munk, and N-point smoothing (signal averaging). Other types of statistical data treatment comprise principle component analysis/regression (PCA/PCR), partial least squares (PLS), Gauss-Jordan Row reduction, etc. In these techniques, correlations are found among the constituent values of interest and one or more mathematically determined equivalent weighting constants. 
     By equivalent weighting constant we mean to include, among other mathematical constructions known to the art, the wavelength coefficients of multiple linear regression, the factors of partial least squares regression, the scores of principal component regression, or the constants obtained from the Gauss-Jordan Row reduction algorithm. (See Harald Martens and Tormod Naes, Multivariate Calibration, John Wiley &amp; Sons; New York, 1989  ISBN 471-90979-3!, and Honigs, D. E., Heiftje, G. M.; Hirschfeld, T., Applied Spectroscopy, 38(3), 1984, p. 317.) Also any constant obtained from any statistical calibration could be used to calculate values for unknown samples. 
     Examples 7 and 9 use multiple linear regression and Examples 8 and 10 use partial least squares. 
     II. Utility of the Invention 
     This invention will find its greatest application in the petroleum refining industry and can be used to monitor the amounts of individual aromatic species in gasoline and middle distillate fuels (e.g., benzene content of gasoline). 
     Another preferred application is to feed the maximum allowable benzene content for reformulated fuel regulations into gasoline blending systems using a blending program such as Ashland Petroleum&#39;s BOSS Blend Optimization and Scheduling System, Chevon&#39;s GINO (Gasoline In-line Optimization), Oil Systems, Inc. MG Blend, or other similar blending optimization programs. Other applications of the invention include various catalytic processes, such as catalytic reforming, where a knowledge of feedstock composition and product composition is preferably used to determine reactor severity, e.g., the hydrogen uptake, temperature, pressure or unit space velocity in the reforming zone. Moreover, the same analysis can be used to predict octane from the reforming step in any of the various modes of octane measurement: pump octane, motor octane, or research octane. 
     Example 1 shows a reformer operating under near infrared analysis to control the severity of the reforming (temperature, hydrogen pressure, hydrogen uptake, and/or unit space velocity) or moisture in the feed. 
     Catalytic isomerization is a process that improves octane number by the conversion of normal paraffins to their isomers. Catalytic isomerization is another application of the invention where a knowledge of feedstock composition and product composition is also preferably used to determine the catalyst activity, the space velocity, the reactor temperature, and the n-paraffin recycle. 
     Speciation of n-paraffins such as n-pentane and n-hexane can be determined in the feed and product and used to monitor conversion efficiency to isopentane and isohexanes, which results in increased octane. Process conditions can be adjusted to optimize the formation of isoparaffins in the reaction. Also, using a feed-forward control system, the optimum space velocity, and/or reactor temperature, and/or unreacted n-paraffin recycle rate can be determined. The mount of product and cracking that occurs during the reaction to form light gases can be predicted using the feed-forward NIR. A multiplexed or multistreamed on-line NIR can be configured so that the feed and product speciation and octane numbers can be determined by a single NIR which alternatively switches between the feed and product streams. 
     Moreover, moisture, which deactivates some catalysts, can be determined in the feed and alert the operators of this problem. 
     The invention can also be applied to catalytic alkylation which involves the reaction of low-molecular-weight olefins with an isoparaffin to form higher-molecular-weight isoparaffins with increased octane numbers and decreased Reid Vapor Pressure. Two commonly used alkylation processes use either sulfuric or hydrofluoric acid as catalysts. Solid acidic catalyst can also be Used. An on-line NIR with closed-loop control can be used to optimize octane and yield, and to minimize polymerization. The envisioned control system would be capable of adjusting the temperature, acid/hydrocarbon ratio, and isoparaffin/olefin ratio, based on NIR measurements in the feed or product streams. 
     A specific application of near-infrared, feed-forward control of alkylation can be deduced from discussions by C. J. Ryskamp, N. F. McGee and P. C. Badavas in Hydrocarbon Processing 65(11):113-118, wherein it is stated that alkylate octane number increases, and acid consumption decreases, with increasing isobutane/olefin ratio. However, there is a tradeoff in the form of higher deisobutanizer distillation costs which are the result of the increase in isobutane recycle required to increase the ratio of isobutane to olefin. Therefore, from an economic standpoint, it is often not practical to maximize the isobutane/olefin ratio, but rather to operate at an optimum ratio which can be lower than the maximum attainable ratio. Consequently, control of this parameter is of utmost importance. Calculation of the isobutane/olefin ratio requires acknowledge of the percent isobutane in the olefin charge stream, the isobutane makeup stream and the isobutane recycle stream. Gas chromatographs are often used to determine these parameters. However, as stated above, chromatography is a slow process in comparison to an on-line spectrophotometric method such as NIR. Therefore, it is advantageous to incorporate NIR according to the invention for feed-forward control in these streams. 
     A multiplexed or multistreamed on-line NIR can be configured so that the feed and product speciations, and octane numbers can be determined by a single NIR which alternates between the feed and product streams. The feed forward NIR can determine the purity of the olefin and isoparaffin feeds, and predict the optimum temperature, acid/hydrocarbon ratio and isoparaffin/olefin ratio, for a given acid catalyst purity and water content. At these conditions, the feed-forward NIR can predict product yields of LPG grade propane liquid, normal butane liquid, C5+ alkylate, and polymers. Finally, alkylate quality can be verified by NIR speciation in a feedback on-line mode. Discussions by G. L. Funk and J. A. Feldman in Hydrocarbon Processing 62(11): 92-95 state that octane contributions of alkylate product are open predicted by aid of an Alkylate Quality Factor which is a function of the volume fraction of isobutane in the reactor effluent and which can be calculated according to results obtained by the invention. 
     The invention will find many applications of hydrocarbon species analysis outside of the petroleum industry. An example is the monitoring of individual isomer concentration (e.g., ortho-xylene) during solvent purification in the chemical industry. Also, the invention can be used to monitor the purity of various streams, the concentration changes which occur during a chemical reaction, and even impurity concentration of hydrocarbon constituents. 
     Analytical Equipment 
     Near infrared (NIR) spectrometers, Fourier Transform near infrared (FTNIR) spectrometers, and modified near infrared spectrometers of conventional design may be used with the invention. Preferred modes of operation are transmission, reflectance, and transflectance. More preferred are transmission and transflectance. Most preferred is transflectance. Suitable spectrometers are the NIR System Models 5000 and 6500 (both bench top and on-line versions); LT Industries Model 1200; and the Guided Wave Model 300 Series; and the Perkin Elmer PIONIR models 1024 and 1024P. The spectrometer can be operated in a quality control lab, on a batch basis(receiving signals, e.g., by a sample feeding arrangement), or, more preferably, on a continuous basis in which the fluid to be measured flows through a cell or in which a probe immersed in the flowing fluid transmits optically through a fiber-optic cable to the spectrophotometer. The techniques for sampling, measuring, and signal processing can be conventional and are well known to those skilled in the art. 
     Blending Systems 
     Blending systems for use with the present invention to provide blends having desired species analysis can be of conventional design, usually involving the use of proportioning pumps or automatic control valves which control the addition rate for each of a series of components fed from different tanks or other sources. A computer receiving the output signal from the spectrophotometer can readily process the information to not only provide the target species analysis or octane number in the finished blended hydrocarbon, e.g., gasoline, but also to provide the target blend at minimum cost, given the relative costs and octane or species analysis enhancement values of the components being fed to the blending system. 
     The present invention permits the determination of species analysis components which have previously been determined only by laboratory analysis or by relatively long slow gas chromatography techniques. The invention permits this determination of different components to be made simultaneously and nearly continuously, providing on-line (or at-line) analysis without the need to return samples to control labs in refineries. 
     Examples of preferred blending systems include systems wherein said signal controls a fuel blending system feeding blending components having different benzene compositions into a common zone, whereby a product having a desired benzene composition is produced. 
     Examples of preferred systems include systems wherein the hydrocarbons being monitored are involved in a chemical reaction. 
     Examples of preferred systems include systems said signal is used to control the severity of said catalytic cracking step by adjusting catalyst:oil ratio, temperature, or recycle of naphtha or other cracked product. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a plot of a typical catalytic reforming process, as shown in Gary and Handwerk, Petroleum Refining Marcel Dekker, third edition, 1994 with the preferred near infrared spectrometers of the present invention added to provide control to the heaters and/or the hydrogen recycle compressor. 
     FIG. 2 is a diagram of a control system for a continuous catalytic reformer, another typical reforming step process in a refinery, as shown in Gary and Handwerk, Petroleum Refining Marcel Dekker, third edition, 1994; with feed-forward and feedback, near-infrared control. 
     FIG. 3 is a plot of the second derivative spectrum across the NIR range 1000 to 2500 nm for 52 reformate sample prepared according to Example 1. 
     FIG. 4 is a control diagram for a typical on-line blender in a refinery with both feed-forward and feedback, near-infrared (NIR) control, as described by W. T. Welch in the Proceedings of the National. Petroleum Refiners Association (NPRA), National Fuels and Lubricants Meeting, FL-93-114, 1993. 
     FIG. 5 is a control diagram of a typical isomerization unit in a refinery as shown in Gary and Handwerk, Petroleum Refining, Marcel Dekker, third edition, 1994; with both feed-forward and feedback, near-infrared control. 
     FIG. 6 is a control diagram of a typical hydrogen fluoride (HF) alkylation unit in a refinery, as shown in Gary and Handwerk, Petroleum Refining, Marcel Dekker, third edition, 1994; with both feed-forward and feedback, near-infrared control. 
     FIG. 7 is a control diagram of a typical methyl tert-butyl ether (MTBE) unit in a refinery as shown in Gary and Handwerk, Petroleum Refining, Marcel Dekker, third edition, 1994; with feed-forward, near-infrared control. 
     FIG. 8 is a typical chromatogram used for PIANO analysis of are formate by the prior art chromatographic technique, with detector signal plotted on the vertical axis as a function of time (in minutes) on the horizontal axis. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     EXAMPLE 1 
     (Invention Controlling Fixed Bed Catalytic Reformer) 
     FIG. 1 shows schematically the process flow of a typical semi-regenerative catalytic reforming unit. Fixed-bed reforming units containing typical reforming catalysts are shown in series as 100, 110 and 120. The operation of the unit is generally as described in Gary and Handwerk, Petroleum Refining, under catalytic reforming and isomerization. 
     Referring to FIG. 1, naphtha charge 90 is pumped through economizing heat exchanger 95 into heater 98 which heats it in the range of 496°-524° C. (925°-975° F.) and conducts it to a first fixed bed reforming unit 100 which contains a conventional reforming catalyst of the platinum products from reformer 100 moves sequentially through heater 108 and reformer 110 and heater 118 and reformer 120. The reformed product moves on to hydrogen separator 125 and fractionating column 135 which produces as bottoms a reformate stream high in aromatics. Hydrogen recycle compressor 130 compresses hydrogen from hydrogen separator 125 to feed hydrogen to mix with the naphtha charge 90 under varying pressures and throughputs of hydrogen. 
     According to the invention, an NIR analyzer 140 samples the effluent from the reformer, analyzes it based on calibrations shown in Table A, which sets forth for each specie, the constants k(0), k(1), k(2), k(3), in the equation below and the wavelengths at which absorption is measured together with the correlation, R and the NIR standard error of estimate as compared to the primary method shown: 
     Concentration of Species= 
     
         k(0)+k(1)×(d.sup.2 A/dλ.sup.2).sub.λ1 +k(2)×(d.sup.2 A/dλ.sup.2).sub.λ2 +k(3)×(d.sup.2 A/dλ.sup.2).sub.λ3 
    
     Where k(0)=bias coefficient 
     k(n)=coefficient for wavelength λn 
     (d 2  A/dλ 2 ).sub.λn =second derivative of absorbance at wavelength λn 
     for n=1, 2 and 3 (wavelengths λ1, λ2 , and λ3) 
     The purpose of reforming is primarily to manufacture aromatic species. Therefore, the lower the aromatics content analyzed by NIR instrument 140, the higher the temperature of heaters 98, 108 and 118 must be to increase the &#34;severity&#34; of the reforming process, and thereby to increase the aromatics in the product stream being measured by NIR 140. Isomerization and thermal cracking can both occur to some degree during reforming. NIR 140 can also be used to measure the degree of isomerization as determined by the isoparaffin content and the degree of cracking as determined by olefin content. 
     According to the invention, a near-infrared (NIR) instrument 140 with closed-loop control capability and operating according to the techniques described above, is placed &#34;at line&#34; so that it measures a portion of the reformate product, analyzes it for aromatics and/or octane or other parameter. Noting any differences between the measured value and the preset desired value, the NIP, closed-loop control unit 140 sends a signal to the heaters 98, 108, and 118 to increase or decrease their temperature or the temperature of any one of them. By increasing the temperature, the &#34;severity&#34; of the reforming process is increased which tends to increase the aromatics and/or octane number of the finished reformate product being measured by the NIR unit 140. Alternatively, (or additionally) the signal from NIR unit 140 can be sent to the hydrogen recycle compressor 130 which increases the pressure of hydrogen in the feed, thus increasing the hydrogen uptake during the reforming process. This serves to reduce the amount of aromatics in the reformate product. 
     Similarly, NIR instrument 140 may additionally control hydrogen recycle compressor 130 to adjust the hydrogen pressure as needed to increase the aromatics in the reformate product from the reforming unit. 
     Finally, NIR instrument 140 can be used to monitor catalyst performance as determined by product composition at a given severity. 
     Additionally, or alternatively, a different NIR instrument 92 (or the same NIR instrument 140 multiplexed for either multistreaming or multiplexing with fiber optics so as to analyze both the naphtha charge 90 and the reformate product), measures the naphtha charge and by &#34;feed forward&#34; predicts the temperature and hydrogen pressure which will be needed for heaters 98, 108 and 118, and hydrogen recycle compressor 130 in order to provide the desired product yield and level of aromatics in the reformate product being analyzed. 
     As an additional precaution, the NIR units can also analyze for H 2  O to determine the presents presence of deleterious moisture which can otherwise deactivate the reformer catalysts in reformer units 100, 110 and 120. 
     By the use of the invention, the aromatics species and/or octane number of the reformate can be controlled more closely than with similar methods employing gas chromatography because the NIR instrument 140 and/or 92 can analyze and respond in less than about one minute, providing close control and fast response. If a specific aromatic species such as benzene is especially desired to be increased or minimized in the reformate product, that specific species can be measured by the techniques described above, the measured value then compared with the preset desired value and the corresponding signal sent to the heaters and/or hydrogen compressor. 
     Similarly, space velocity can be increased in response to the NIR unit signal in order to reduce the severity of the reforming operation and reduce the aromatics in the produced reformate. 
     EXAMPLE 2 
     (Invention Controlling A Continuous Catalytic Reformer) 
     FIG. 2 is a diagram of a control system for a continuous catalytic reformer with both feed-forward and feedback, near-infrared (NIP,) control. 
     A UOP-type continuous catalytic reformer (CCR) unit is controlled by the NIR instruments of the present invention. In FIG. 2, R is the reactor, H is the heater, RS is the catalytic regeneration section, LPS is the low pressure separator, HPS is the high pressure separator, C is the hydrogen compressor, and DBU is the debutanizer. 
     Naphtha feed is pumped through heater H and then to reactor R which contains recirculating catalyst. Regenerator RS continuously regenerates the catalyst by burning off carbon, reducing and acidifying the catalyst, and then returning it to the top of reactor R. The product is removed from reactor R to low-pressure separator LPS which removes hydrogen from the product. The removed hydrogen is compressed by hydrogen compressor C. The product is then directed to high-pressure separator HPS which removes additional hydrogen, a portion of which is recombined with the naphtha feed. Product from high-pressure separator HPS is directed to debutanizer DBU which removes butane and lighter hydrocarbons. The bottom fraction from debutanizer DBU is sampled and analyzed by feedback analyzer NIR1 which in turn is used in a feedback mode to control the feed rate, the temperature of heater H and the hydrogen recycle from high-pressure separator HPS. 
     Feed-forward NIR analyzer NIR2 is also used to sample the naphtha feed for control of the feed rate, the temperature of heater H and the hydrogen recycle from high-pressure separator HPS. By use of feed-forward control in this configuration, the severity of the reforming process is adjusted based on the concentrations of aromatic-forming species (such as naphthenes) in the feeds. In this way, aromatics in the product is controlled based on the chemical properties of the feedstocks. In addition, feed-forward NIR analyzer NIR2 alerts the operator to excessive amounts of undesirable species in the feed. 
     NIR2 may be the stone instrument as NIR1 or a different NIR instrument, with feed-forward and feedback functions operating in a multiplexing or multistreaming mode. According to the invention, NIR analyzers NIR1 and NIR2 sample the feed and the stabilizer bottoms, and analyze them based on calibrations such as those shown in Table A, which sets forth the constants k(0), k(1), k(2), k(3), and the wavelengths at which absorption is measured together with the correlation, R and the NIR standard error of estimate as compared to the primary method shown. FIG. 3 shows typical second-derivative spectra used for calibrations such as those shown in Table A. 
     Typical analyses of reformate are shown in Table B, with comparison of the NIR results with results by the primary method (GC-PIANO). 
     EXAMPLE 3 
     (Invention Controlling a Fuel Blender) 
     FIG. 4 is a control diagram for a typical on-line blender in a refinery, with both feed-forward and feedback, near-infrared (NIR) control. 
     In FIG. 4, the use of multistreaming, whereby the component streams are switched sequentially to a single probe using valves, is illustrated; however, multiplexing, whereby a probe is located at each control point; or a combination of both; can also be used. In a multistreaming operation such as that illustrated in FIG. 4, components 410, 420, 430, 440, 450 and 460 are sequentially routed to the sample cell or sample probe of NIR 470 which analyzes each stream for properties or components of interest (e.g., benzene). A signal for each stream (proportional to vol % benzene) is then transmitted to optimizing software such as GINO. The GINO software, resident in blending computer 480, then continuously optimize and update the blend recipe, then downloads the updated recipe to Blend Ratio Control (BRC) software which is resident in Distributed Control System (DCS) 490. The BRC software is capable of controlling DCS 490 which in turn adjusts the position of valves 405, 415, 425, 415, 445, and 455 to change the flow rates of components 410, 420, 430, 440, 450 and 460, respectively. 
     Another NIR 500 can also be used in a feedback mode. A slip stream 465 of the fin/shed blend is directed to the sample probe or sample cell of NIR 500, which analyzes the finished blend for benzene and other properties of interest. DCS 490 then receives the feedback signal from NIR 500 in the same manner as it receives the feed-forward signals from NIR 470. The DCS 490 is configured to allow direct control of valves 405, 415, 425, 435, 445 and 455 by the feedback control loop to override the recipe established by the feed-forward control loop when necessary. 
     NIR 500 may be the same instrument as NIR 470, with feed-forward and feedback functions operating in a multiplexing or multistreaming mode. 
     EXAMPLE 4 
     (Invention Controlling an Isomerization Unit with Pentane Recycle) 
     FIG. 5 is a control diagram of a typical isomerization unit in a refinery, with near-infrared control having both feed-forward and feedback control. 
     In FIG. 5, the feed stream 500 first goes to deisopentanizer 520 which removes the low-boiling isopentane product 680 as the overhead fraction. The bottom fraction 530 is then directed to dryer 540 combined with recycle hydrogen 550, to which makeup hydrogen 560 is added from dryer 570 as needed. The combined stream is directed through economizing heat exchanger 580 to heater 590, then to reactor 600, then to water cooler 610 and then to hydrogen separator 620 for separation of recycle hydrogen 550 from the product stream, which is then directed to stabilizer 630. Propane and light gases are removed from stabilizer 630 as the overhead fraction 670. The bottoms from stabilizer 630 are then directed to splitter 640 for separation of pentanes 650 as the overhead fraction, from product hexanes 660 which are removed as the bottom fraction. Pentanes 650 are recycled to deisopentanizer 520. 
     Feed-forward control is accomplished by the use of NIR 510 to analyze feed 500, recycle pentanes 650 and/or the combined stream composed of both. Use of NIR 510 to speciate paraffins in these streams, more preferably pentanes and hexanes, can provide the refiner with important real-time information for optimization of reactor temperature, feed rate and recycle rate. 
     Feedback control is typically accomplished for both product hexanes 660 and isopentane product 680 by NIR 690. By tracking the amounts of unreacted normal hexanes in product hexanes 660 and unreacted normal pentane in isopentane product 680, product quality is continuously monitored. Similar to the blender operation, the feedback control loop is configured with capability to override the feed-forward control loop. 
     NIR 510 may be the same instrument as NIR 690, with feed-forward and feedback functions operating in a multiplexing or multistreaming mode. 
     EXAMPLE 5 
     (Invention Controlling a Hydrogen Fluoride (HF) Alkylation Unit) 
     FIG. 6 is a control diagram of a typical hydrogen fluoride (HF) alkylation unit in a refinery, with both feed-forward and feedback near-infrared control. 
     In FIG. 6, olefin feed 700 and isobutane feed 710 are directed through dryers A and B, respectively, combined with each other and then with HF acid recycle 720 before reaching acid settler C, which disengages the hydrocarbon overhead fraction 730 and immediately recycles the acid 720 through acid cooler D. Overhead fraction 730 arrives at depropanizer G which removes propane 740 as the overhead fraction and directs it to propane accumulator H, from which any remaining HF is removed in stripper J and propane caustic treater P. The bottom fraction 750 from depropanizer G is directed to deisobutanizer accumulator K, which separates this stream into isobutane overhead fraction 760 and bottom fraction 770. Isobutane 760 is recycled and combined with feed streams 700 and 710. The bottom fraction 770 is then directed to debutanizer M which removes n-butane 780 as overhead from alkylate bottom fraction 790. 
     Feed-forward control of the isobutane/olefin ratio is accomplished by sampling olefin feed stream 700, isobutane feed or makeup stream 710 and isobutane recycle stream. The three streams are directed to NIR 800 in a multistreaming mode, or, alternatively, sampled using separate probes or flow cells in a multiplexing mode. NIR 800 the analyzes the streams for percent isobutane. This value, in combination with flow measurements and the predetermined optimum isobutane/olefin ratio, allows calculation of the flow rate of olefin feed stream 700 required to maintain the desired ratio. 
     Feed-forward control of temperature, acid/hydrocarbon ratio and isoparaffin/olefin ratio can also be accomplished by using the NIR values for percent isobutane in olefin feed 700 and isobutane feed 710 as previously mentioned. 
     Feedback control can involve the determination of the composition of the isobutane content in hydrocarbon overhead 730 from reactor C as well as the composition of alkylate product 790. The percent isobutane in hydrocarbon overhead 730 is used to calculate the previously-mentioned quality factor which is used to predict the contribution of the alkylate product 790 to octane numbers in blends. 
     NIR 800 may be the same instrument as NIR 810, with feed-forward and feedback functions operating in a multiplexing or multistreaming mode. 
     EXAMPLE 6 
     Invention Controlling a Methyl Tertiary Butyl Ether (MTBE) Unit) 
     FIG. 7 is a control diagram of a typical methyl tert-butyl ether (MTBE) unit in a refinery, with both feed-forward and feedback near-infrared control. A useful application of on-line feed-forward control involves a critical calculation of Isobutylene to methanol ratio. 
     Referring to FIG. 7, a UOP design, excess methanol is used to obtain almost complete conversion of the isobutylene. Isobutylene feed 700 and methanol feed 710 are combined with recycle methanol 820 and directed through cooler 720 to the top of primary reactor 730. Most of the effluent from reactor 730 is recycled but a small amount is directed to proprietary (Koch Engineering) Reaction with Distillation (RWD) column 740 which contains a catalyst section just above the feed inlet and serves as a secondary reactor. MTBE product 750 is withdrawn from the bottom of RWD column 740. Unreacted methanol and isobutylene pass through the catalyst-containing section of RWD column 740 and are convened to additional MTBE which also withdrawn from the bottom. The overhead fraction of RWD column 740, consisting mostly of unreacted methanol vapor and butanes from feed stream 700, is split into recycle stream 760 and methanol recovery stream 770. Methanol is extracted with water from recovery stream 770 in water wash column 780. Raffinate 790, consisting mainly of unreacted butanes, is used as feed for other processes. Extract 800 is distilled in tower 810, the water being recycled to wash column 780 and the distilled methanol directed to recycle methanol stream 820. 
     NIR 830 is used in a feed-forward control loop to monitor the composition of isobutylene feed 700 the combined isobutylene/methanol stream being fed to primary reactor 730. By measuring flow rates, the amounts of butanes, butenes and isobutylenes in isobutylene feed stream 700, and percent methanol and isobutylene in combined stream 840, the methanol/isobutylene ratio can be calculated and used to control the flow of isobutylene. The methanol/isobutylene ratio is a critical parameter in this process because it is desirable to use a small excess of methanol. 
     MTBE purity can be monitored using NIR 850. NIR 830 and NIR 850 can be a single instrument in a multiplexing or multistreaming mode. Other ether manufacturing steps (TAME, ETBE, diisopropyl, ether, etc.) can be similarly controlled. 
     EXAMPLE 7 
     (Speciation of Aromatics For Reformer Control According to the Invention Using MLR) 
     Fifty-two samples of hydrocarbons are used for calibration according to the techniques of the present invention. Calibration results are shown in Table A, for PIANO and for speciation of individual compounds. Debutanizer bottoms, obtained from the bottom of the fractionating tower which removes components lighter than butane as overheads, are used as calibration samples. All samples are analyzed by gas liquid chromatography by a procedure taught by Analytical Automation Specialists, Inc., &#34;The Detailed Analysis of Petroleum Naphthas, Reformates, Gasoline and Condensates by High-Resolution Gas chromatography&#34;, operators manual, P.O. Box 80653, Baton Rouge, La. 70898, with results as shown in Table G. 
     The NIR instrument used for the invention is was an NIRSystems on-line Model 5000, near infrared spectrophotometer measuring all of the 52 samples. Wavelengths used and the range of volume percents is shown in Table A. The samples were selected so as to represent an increasing concentration of each of the species or components so that the entire range was covered. 
     A multiple linear regression analysis was performed on the second derivative of the absorbances measured at the indicated wavelengths. Also shown in Table A are the regression coefficients, the multiple coefficients of correlation, and the standard errors of the estimate (calculated for this calibration set by conventional well-known statistical techniques). 
     Nine samples are used as a prediction set for prediction of species and component concentrations in unknown samples. Again, the second derivatives of the absorbances are used as the independent variables in the multiple linear regression equations obtained from the calibration set. Results are shown in Table B. The NIRSystems computer program supplied with the apparatus (NIR Spectral Analysis Software) was used for multiple regression analysis, although SAS or another well-known statistical program could be used as well. These programs multiply the second derivative of each absorbance at each wavelength by its respective weighting constant, then sum the products to provide a weighted value which is characteristic of the predicted percent of each respective species or component. It can be seen that the actual standard error of prediction shows excellent correlation between the model and the actual concentrations in samples not in the calibration set. 
     Table B (reformate) shows that the invention measures concentration of species with accuracy comparable to the slow GC PIANO method, but at much faster control response times. 
     EXAMPLE 8 
     (The Invention Using Species Analysis and Partial Least Squares) 
     The same 52 samples analyzed in Example 6 with multiple linear regression (MLR) results shown in Table B, were reprocessed using partial least squares regression equations (PLS). Results are shown in Table C for each species commonly requiring analysis in refinery practices. As shown under column &#34;R&#34;, the correlation coefficients are as good or better than those obtained according to the invention using the multiple linear regression (Example 7, Table A). NIR values for all of the constituents approach the accuracy of the primary method, GC PIANO, while avoiding the man-hour requirements and delayed control response of the GC PIANO analysis. In general, GC PIANO requires approximately 3-4 hours for an analysis while an on-line NIR analysis of the same constituents with automatic input to a conventional Distributed Control System (DCS) or similar control device; requires only about thirty seconds. Thus the invention provides a substantially faster control response. 
     EXAMPLE 9 
     (Speciation of Aromatics For Blender Control Using Multiple Linear Regression According to the Invention) 
     One hundred forty-three samples of hydrocarbons are used for calibration according to the techniques of the present invention. Calibration results are shown in Table D, for PIANO and for speciation of individual aromatic compounds. All samples are analyzed by gas liquid chromatography by a procedure taught by Analytical Automation Specialists, Inc., &#34;The Detailed Analysis of Petroleum Naphthas, Reformates, Gasoline and Condensates by High-Resolution Gas chromatography&#34;, operators manual, P.O. Box 80653, Baton Rouge, La. 70898, with typical results as shown in Table H. 
     The instrument used for this example of the invention is a Perkin Elmer PIONIR 1024P, near infrared spectrophotometer measuring all of the samples. Wavelengths used and the range of volume percents is shown in Table D. The samples are selected so as to represent an increasing concentration of each of the species or components so that the entire range was covered. 
     A multiple linear regression analysis was performed on the second derivative of the absorbances measured at the indicated wavelengths. Also shown in Table D are the regression coefficients, the multiple coefficients of correlation, and the standard errors of the estimate (calculated for this calibration set by conventional well-known statistical techniques). 
     EXAMPLE 10 
     (Speciation of Aromatics For Blender Control Using Partial Least Squares According to the Invention) 
     One hundred thirty-four samples analyzed in Example 9 with multiple linear regression (MLR) results shown in Table D, were reprocessed using partial least squares regression equations (PLS). Results are shown in Table E for each species commonly requiring analysis in refinery practices. As shown under column &#34;R&#34;, the correlation coefficients are as good or better than those obtained according to the invention using the multiple linear regression (Example 9, Table D). NIR values for all of the constituents approach the accuracy of the primary method GC PIANO, while avoiding the man-hour requirements of the GC PIANO analysis. In general, GC PIANO requires approximately 3-4 hours for an analysis. On the other hand, an on-line NIR analysis of the same constituents with automatic input to a DCS or similar control device, requires only about thirty seconds. Thus the invention provides a substantially faster control response. 
     Nine samples were used as a prediction set for prediction of species and component concentrations in unknown samples. Again, the second derivatives of the absorbances are used as the independent variables in the PLS regression equations obtained from the calibration set. Results are shown in Table F. The NIRSystems computer program was used for partial least squares analysis, although SAS or another well-known statistical program could be used as well. It can be seen that the actual standard error of prediction shows excellent correlation between the model and the actual concentrations in samples not in the calibration set. 
     Table F (gasoline) shows that the invention measures concentration of species with accuracy comparable to the slow GC PIANO method by a much faster control response time. 
     EXAMPLE 11 
     (Comparative with Species Analysis Using Conventional Gas Liquid Chromatography) 
     Table H is a typical PIANO analysis report as performed using PIANO Software Version 6.06 Serial Number P-0182U (Analytical Automation Specialists, Inc.) The chromatogram for a reformate, shown in FIG. 8, was obtained using a Hewlett-Packard Model 5890 temperature-programmed gas chromatograph with a flame ionization detector and a Supelco Petrocol DH capillary column (fused silica, 100M×0.25 mm i.d., df=0.5 uM). Chromatographic conditions were adjusted according to the standard methods established by the instrument manufacturer and Analytical Automation Specialists, Inc. Table H contains detailed speciation of many paraffins, isoparaffins, aromatics, naphthenes and olefins by this method. Thus it is seen that this prior art method is useful for the determination of individual species as well as compound types, and can serve as the primary method for calibration of the near-infrared instruments used in the present invention. However, as shown in FIG. 8, this method is slow. FIG. 8 shows an elutriation time for the last fractions of 142 min or over two hours. The PIANO method is thus seen to be too slow for efficient use in closed-loop control for many refinery processes. 
     Modifications 
     Specific compositions, methods, or embodiments discussed are intended to be only illustrative of the invention disclosed by this specification. Variation on these compositions, methods, or embodiments are readily apparent to a person of skill in the art based upon the teachings of this specification and are therefore intended to be included as part of the inventions disclosed herein. For example, FTNIR or even Raman IR can be used in place of NIR by conventionally modifying the mathematical conversions and data analysis, so that spectral data obtained by FTNIR or Raman IR are used in place of the near infrared spectral data, and calibrating using one or more mathematical methods as explained above, against the PIANO analysis or other primary method as with an NIR instrument. 
     Reference to  documents! U.S. patents made in the specification is intended to result in such patents  or literature!. 
     
         TABLE A  - Multiple Regression Equations for Reformate using Second Derivative Data  in the 1100-2500 nm Range  Compound Primary Constants Wavelengths (nm)  2 NIR  Volume % Method Range Average k(0) k(1) k(2) k(3) 1 2 3 R R STD ERROR  Total Aromatics GC-PIANO 35.917-68.001 59.758 79.902 93.863 82.716 -105.131 1834 1624 1232 0.999 0.998 0.302     methylene aromatic methyne:t-butyl       or methylene  Benzene GC-PIANO 2.697-5.730 4.394 19.610 -12.233 -75.612 21.631 2128 1624 1834 0.995 0.989 0.0675     aromatic aromatic methylene  Toluene GC-PIANO  8.770-16.169 13.633 11.905 -39.118 86.410 -144.518 1650 1796 1224 0.992 0.983 0.218     aromatic methylene methyne  Total Xylenes GC-PIANO  8.512-19.999 15.596 -108.345 901.434 203.014 488.084 1458 2028 1622 0.989 0.978 0.422     methytene methyl aromatic  m-Xylene GC-PIANO 4.013-9.572 7.657 51.160 -57.877 -476.542 -53.513 1648 1504 1400 0.978 0.956 0.276     aromatic methylene methyl  p-Xylene GC-PIANO 1.802-4.034 3.258 12.589 32.439 111.426 -21.007 1204 1356 1646 0.984 0.967 0.098     methyl methyl aromatic  o-Xylene GC-PIANO 2.697-6.393 5.005 24.885 -46.606 -28.127 -47.216 2148 1854 1646 0.986 0.971 0.178     aromatic methylene aromatic  Ethyl-Benzene GC-PIANO 2.292-3.960 3.259 18.684 -13.659 -18.225 -23.611 1176 1642 1230 0.983 0.966 0.087    methyl aromatic methyne:t-butyl       or methylene  n-Propylbenzene GC-PIANO 0.832-1.297 1.113 6.223 -99.616 -7.656 24.658 1466 1204 1408 0.967 0.936 0.034     methylene methyl methyl  Total Xylenes + GC-PIANO 10.804-23.959 18.855 152.836 239.466 -348.026 71.360 1196 2232 1800 0.990 0.980 0.475  Ethyl-Benzene    methyl methyl methylene  BTX GC-PIANO 19.979-40.253 33.623 81.849 -196.094 84.458 -114.177 1230 1792 1642 0.996 0.992 0.423     methyne:t-butyl methylene aromatic     or methylene  BTEX GC-PIANO 22.271-44.213 36.882 95.748 84.555 -211.572 -128.650 1792 1230 1642 0.993 0.985 0.637     methylene methyne:t-butyl aromatic      or methylene  Olefins GC-PIANO 0.464-1.697 1.083 -3.051 134.146 24.440 104.801 1612 1200 1140 0.978 0.957 0.052     olefin methyl aromatic  Paraffins GC-PIANO  8.355-22.359 11.084 -50.245 217.444 -147.095 264.005 1976 2062 1232 0.997 0.993 0.235     (1) (1) methyne:t-butyl       or methylene  n-Pentane GC-PIANO 0.685-4.823 1.818 -55.911 61.895 -418.774 280.953 1650 1452 1970 0.931 0.867 0.338     aromatic methylene (1)  n-Hexane GC-PIANO 2.673-5.185 3.527 4.362 -25.343 -30.921 -53.680 1844 2014 1624 0.926 0.857 0.179     methylene methyl aromatic  n-Heptane GC-PIANO 1.612-7.484 2.869 25.158 28.376 105.983 235.947 1662 1184 1418 0.990 0.980 0.119     aromatic methyl methyl  Isoparaffins GC-PIANO 20.004-34.565 24.081 103.497 -285.180 109.252 -203.116 2084 1938 1230 0.997 0.993 0.304     olefin (1) methyne:t-butyl       of methylene  Iso-Pentane GC-PIANO 1.058-8.247 2.937 -83.412 444.557 -139.031 404.416 1970 2144 1484 0.917 0.840 0.613     (1) aromatic methylene  2-Methylhexane GC-PIANO 1.883-4.118 2.852 73.421 -45.227 -180.792 -128.404 1804 1592 1244 0.907 0.823 0.156     methylene olefin methylene  2,2-Dimethylbutane GC-PIANO 0.339-1.076 0.0721 -19.744 12.635 85.006 32.918 1828 1332 1162 0.908 0.825 0.0621     methylene methyl methyl  2,3-Dimethylbutane GC-PIANO 0.461-0.850 0.7 -0.070 -19.360 6.277 -15.599 2050 1828 1182 0.873 0.761 0.0408     (1) methylene methyl  2-Methylpentane GC-PIANO 2.625-4.290 3.409 33.716 -34.183 -177.647 -53.891 1844 1256 1620 0.844 0.713 0.191     methylene methylene aromatic  3-Methylpentane GC-PIANO 1.992-3.204 2.595 -4.712 -36.378 -62.348 20.188 1186 2052 1824 0.846 0.716 0.137     methyl (1) methylene  Napthenes GC-PIANO 0.811-6.511 1.772 -17.732 285.844 648.948 67.139 1368 1294 1802 0.986 0.972 0.225     methyl (1) methylene  Methylcyclopentane GC-PIANO 0.165-1.875 0.433 2.228 -53.642 103.606 46.526 1192 1374 1234 0.977 0.973 0.058     methyl methyl methyne:t-butyl       or methylene (1) NOT ASSIGNED 
    
     
                                           TABLE B__________________________________________________________________________Comparision of NIR Results with GC-PIANO ResultsFor Reformates in the 1100-2500 nm RangeTOTAL AROMATICS    OLEFINSSAMPLENIR GC-PIANO          Delta              NIR GC-PIANO                        Delta__________________________________________________________________________4/15/9467.139    66.997          0.142              1.366                  1.401 -0.0354/16/9465.361    64.925          0.436              1.226                  1.416 -0.1904/17/9465.438    65.392          0.046              1.221                  1.359 -0.1384/23/9465.799    65.237          0.562              1.081                  1.337 -0.2564/24/9465.884    65.760          0.124              1.102                  1.302 -0.2004/25/9464.867    64.474          0.393              1.259                  1.435 -0.1764/26/9465.190    64.902          0.288              1.254                  1.492 -0.2384/27/9465.026    65.703          -0.677              1.199                  1.393 -0.1944/28/9465.450    65.602          -0.152              1.238                  1.444 -0.206Average        0.129         -0.181DeltasSEP            0.373         0.065__________________________________________________________________________BENZENE            TOLUENE       XYLENE + ETHYLBENZENESAMPLENIR GC-PIANO          Delta              NIR GC-PIANO                        Delta                            NIR GC-PIANO                                      Delta__________________________________________________________________________4/15/945.222    5.183 0.039              14.843                  15.201                        -0.358                            22.007                                21.115                                      0.8924/16/943.597    3.843 -0.246              14.177                  13.601                        0.576                            21.620                                21.557                                      0.0634/17/943.804    4.143 -0.339              14.381                  14.317                        0.064                            21.275                                21.657                                      -0.3824/23/943.129    3.574 -0.445              13.983                  13.370                        0.613                            21.000                                20.724                                      0.2764/24/942.888    3.377 -0.489              14.037                  13.402                        0.635                            20.999                                21.076                                      -0.0774/25/943.375    3.692 -0.317              14.083                  13.592                        0.491                            21.084                                21.655                                      -0.5714/26/943.548    3.792 -0.244              14.278                  13.781                        0.497                            21.458                                22.065                                      -0.6074/27/943.149    3.444 -0.295              13.907                  13.380                        0.527                            21.229                                21.744                                      -0.5154/28/943.186    3.541 -0.355              14.006                  13.465                        0.541                            21.107                                21.515                                      -0.408Average        -0.299        0.398         -0.148DeltasSEP            0.161         0.330         0.495__________________________________________________________________________ 
    
     
                                           TABLE C__________________________________________________________________________Partial Least Squares Regression Equations for Reformate UsingSecond Derivative Data in the 1100-2500 nm Range                                                      NIRCompound Primary                                  Fac-  2  STDVolume % Method          Range  Average                     Wavelength Range (nm)   tors                                                R  R  ERROR__________________________________________________________________________Total Aromatics    GC-PIANO          35.917-68.001                 59.758                     1214-1260; 1600-1670; 1780-1858                                             5  0.999                                                   0.998                                                      0.3248Benzene  GC-PIANO          2.697-5.730                 4.394                     1120-1260; 1600-1670; 1780-1858;                                             1200-2160                                                1.000                                                   0.999                                                      0.0228Toluene  GC-PIANO           8.770-16.169                 13.633                     1214-1230; 1600-1670; 1780-1858;                                             8000-2160                                                0.997                                                   0.995                                                      0.1294Total Xylenes    GC-PIANO           8.512-19.999                 15.596                     1120-1214; 1320-1530; 1600-1670;                                             1200-2040                                                0.998                                                   0.995                                                      0.215m-Xylene GC-PIANO          4.013-9.572                 7.657                     1320-1430; 1480-1530; 1600-1670;                                             7000-2040                                                0.991                                                   0.981                                                      0.1863p-Xylene GC-PIANO          1.802-4.034                 3.258                     1156-1214; 1320-1430; 1600-1670;                                             1200-2040                                                0.997                                                   0.995                                                      0.0437o-Xylene GC-PIANO          2.697-6.393                 5.063                     1600-1670; 1780-1858; 2000-2040;                                             8100-2160                                                0.995                                                   0.990                                                      0.1098Ethyl-Benzene    GC-PIANO          2.292-3.960                 3.259                     1156-1284; 1600-1670    5  0.983                                                   0.967                                                      0.0869n-Propylbenzene    GC-PIANO          0.832-1.297                 1.113                     1156-1214; 1320-1480; 1600-1670;                                             8970-2040                                                0.987                                                   0.973                                                      0.0232Total Xylenes +    GC-PIANO          10.804-23.959                 18.855                     1120-1214; 1600-1670; 1780-1858; 1970-2040;                     2160-                   13 0.999                                                   0.998                                                      0.1455Ethyl-Benzene             2250BTX      GC-PIANO          19.979-40.253                 33.623                     1214-1260; 1600-1670; 1760-1858;                                             6000-2040                                                0.997                                                   0.994                                                      0.377BTEX     GC-PIANO          22.271-44.213                 36.882                     1156-1214; 1600-1670; 1780-1858; 1970-2040;                     2100-                   5  0.993                                                   0.986                                                      0.6264                     2160Olefins  GC-PIANO          0.464-1.697                 1.083                     1132-1214; 1600-1670    6  0.973                                                   0.947                                                      0.06Paraffins    GC-PIANO           8.355-22.359                 11.084                     1214-1264; 1940-2100    6  0.998                                                   0.996                                                      0.1923n-Pentane    GC-PIANO          0.685-4.823                 1.818                     1430-1480; 1600-1670; 1940-2040                                             7  0.965                                                   0.932                                                      0.2528n-Hexane GC-PIANO          2.673-5.185                 3.527                     1430-1480; 1780-1858    9  0.961                                                   0.923                                                      0.1404n-Heptane    GC-PIANO          1.612-7.484                 2.869                     1158-1214; 1320-1480; 1600-1670                                             8  0.995                                                   0.989                                                      0.0916Isoparaffins    GC-PIANO          20.004-34.565                 24.081                     1214-1264; 1920-2100    7  0.998                                                   0.995                                                      0.2708Iso-Pentane    GC-PIANO          1.058-8.247                 2.937                     1430-1500; 1940-2040; 2100-2160                                             13 0.994                                                   0.988                                                      0.19142-Methylhexane    GC-PIANO          1.883-4.118                 2.852                     1214-1260; 1560-1626; 1780-1858                                             11 0.974                                                   0.949                                                      0.09162,2-Dimethylbutane    GC-PIANO          0.339-1.076                 0.721                     1156-1214; 1320-1430; 1780-1858                                             5  0.923                                                   0.852                                                      0.05822,3-Dimethylbutane    GC-PIANO          0.461-0.850                 0.7 1156-1214; 1780-1858; 2000-2160                                             8  0.957                                                   0.915                                                      0.02562-Methylpentane    GC-PIANO          2.625-4.290                 3.409                     1230-1264; 1600-1670; 1780-1858;                                             9900-2000                                                0.919                                                   0.844                                                      0.1513-Methylpentane    GC-PIANO          1.992-3.204                 2.595                     1156-1214; 1780-1858; 2000-2160                                             8  0.948                                                   0.899                                                      0.0866Naphthenes    GC-PIANO          0.811-6.511                 1.772                     1264-1430; 1780-1858    12 0.998                                                   0.997                                                      0.0849Methylcyclopentane    GC-PIANO          0.165-1.875                 0.433                     1156-1260; 1320-1430    4  0.988                                                   0.975                                                      0.0564__________________________________________________________________________ 
    
     
                                           TABLE D__________________________________________________________________________Multiple Linear Regression Equations for Gasoline UsingSecond Derivative Data in the 800-1100 nm Range__________________________________________________________________________Compound   Primary          ConstantsVolume %   Method         Range  Average                    k(0)                        k(1) k(2) k(3)__________________________________________________________________________Total Aromatics   GC-PIANO         15.807-53.948                27.184                    -5.997                        849.956                             2093.227                                  -941.626Benzene GC-PIANO         0.209-3.464                1.021                    5.957                        -223.324                             14.679                                  -282.507Toluene GC-PIANO          1.103-16.177                4.418                    -48.597                        875.582                             577.698                                  1586.754Total Xylenes   GC-PIANO          3.869-17.130                6.685                    -10.873                        118.346                             414.531                                  2652.921m-Xylene   GC-PIANO         1.942-9.108                3.250                    -15.071                        148.824                             618.061                                  849.797p-Xylene   GC-PIANO         0.742-3.773                1.333                    -0.891                        331.087                             47.028                                  -218.152o-Xylene   GC-PIANO         1.133-4.728                2.102                    1.238                        -66.080                             -98.546                                  -174.507Ethyl-Benzene   GC-PIANO         0.444-4.110                1.193                    -0.229                        -316.535                             -474.194                                  343.881__________________________________________________________________________    Compound            Wavelengths (nm)                            2   NIR    Volume %            1   2   3   R   R   STD ERROR__________________________________________________________________________    Total Aromatics            1064                854 879.5                        0.983                            0.966                                1.35    Benzene 886 914.5                    871 0.894                            0.799                                0.208    Toluene 884.5                892.5                    989.5                        0.907                            0.823                                0.909    Total Xylenes            920 879 868 0.882                            0.777                                0.955    m-Xylene            906 973 868 0.803                            0.644                                0.599    p-Xylene            867.5                906.5                    857.5                        0.785                            0.616                                0.265    o-Xylene            954.5                880.5                    964.5                        0.967                            0.935                                0.186    Ethyl-Benzene            1028                861 887.5                        0.664                            0.441                                0.329__________________________________________________________________________ 
    
     
                                           TABLE E__________________________________________________________________________Partial Least Squares Regression Equations for GasolineUsing Second Derivative Data in the 800-1100 nm RangeCompound   Primary                            2  NIRVolume %   Method         Range  Average                    Wavelength Range (nm)                               Factors                                   R  R  STD ERROR__________________________________________________________________________Total Aromatics   GC-PIANO         15.807-53.948                27.184                    840-900; 1050-1075                               3   0.985                                      0.969                                         1.2455Benzene GC-PIANO         0.209-3.464                1.021                    850-925    9   0.935                                      0.874                                         0.1723Toluene GC-PIANO          1.103-16.177                4.418                    860-910; 975-1000                               6   0.918                                      0.842                                         0.749Total Xylenes   GC-PIANO          3.869-17.130                6.685                    850-930    9   0.923                                      0.852                                         0.8112m-Xylene   GC-PIANO         1.942-9.108                3.250                    850-925; 965-990                               7   0.864                                      0.747                                         0.5271p-Xylene   GC-PIANO         0.742-3.773                1.333                    850-925    10  0.881                                      0.776                                         0.2141o-Xylene   GC-PIANO         1.133-4.728                2.102                    865-900; 940-975                               8   0.975                                      0.950                                         0.1652Ethyl-Benzene   GC-PIANO         0.444-4.110                1.193                    850-900; 1015-1045                               9   0.844                                      0.712                                         0.2494__________________________________________________________________________ 
    
     
                                           TABLE F__________________________________________________________________________Comparison Between GC-PIANO Results and NIR Results forGasolines in the 800-1100 nm Range Using PLSR__________________________________________________________________________TOTAL AROMATICS     BENZENE        TOLUENE       TOTAL XYLENESSAMPLENIR  GC-PIANO           Δ               NIR GC-PIANO                         Δ                              NIR GC-PIANO                                        Δ                                            NIR GC-PIANO                                                      Δ__________________________________________________________________________cat-1546.261     45.742           0.519               0.720                   0.611 0.109                              1.757                                  2.961 -1.204                                            11.067                                                10.460                                                      0.607cat-2616.234     16.615           -0.381               0.854                   0.649 0.235                              2.328                                  3.397 -1.069                                            4.412                                                4.004 0.408cat-4221.188     21.476           -0.288               1.039                   0.828 0.211                              3.506                                  3.929 -0.423                                            5.764                                                5.372 0.392cat-8624.050     25.780           -1.730               0.761                   0.850 -0.099                              3.756                                  4.966 -1.210                                            5.835                                                5.930 -0.095cat-9924.174     22.954           1.220               0.891                   1.010 -0.119                              4.797                                  2.515 2.282                                            2.843                                                6.248 -3.405cat-11826.510     29.440           -0.930               1.031                   0.937 0.994                              3.625                                  4.258 -0.633                                            7.192                                                7.040 0.152cat-13926.936     27.984           -1.048               0.904                   0.615 0.289                              7.695                                  10.200                                        -2.565                                            6.340                                                5.078 1.262cat-15028.539     27.664           0.875               2.254                   1.982 0.272                              8.107                                  7.508 0.599                                            8.102                                                7.546 0.556cat-16320.481     19.927           0.554               0.761                   1.113 -0.352                              5.387                                  3.877 1.510                                            4.919                                                6.103 -1.184     AVERAGES           -0.134        0.068          -0.295        -0.145     Std Error of           1.100         0.175          1.350         1.300     Pred.__________________________________________________________________________m-XYLENE            p-XYLENE       o-XYLENE      ETHYLBENZENESAMPLENIR  GC-PIANO           Δ               NIR GC-PIANO                         Δ                              NIR GC-PIANO                                        Δ                                            NIR GC-PIANO                                                      Δ__________________________________________________________________________cat-155.027     4.450 0.577               1.846                   1.762 0.084                              4.119                                  4.248 -0.129                                            1.613                                                1.377 0.236cat-262.345     2.041 0.304               0.930                   0.825 0.105                              1.008                                  1.138 -0.130                                            0.914                                                0.847 0.067cat-422.837     2.718 0.119               1.206                   1.099 0.107                              1.587                                  1.555 0.032                                            1.406                                                1.034 0.372cat-862.771     2.918 -0.147               1.109                   1.211 -0.102                              1.696                                  1.801 -0.105                                            0.975                                                1.098 -0.123cat-991.588     3.106 -1.518               1.178                   1.288 -0.110                              2.118                                  1.854 0.264                                            0.381                                                1.191 -0.810cat-1183.621     3.369 0.232               1.448                   1.371 0.077                              2.246                                  2.280 -0.034                                            1.243                                                1.226 0.017cat-1393.661     2.409 1.252               1.409                   0.955 0.454                              1.969                                  1.714 0.255                                            1.189                                                0.789 0.400cat-1502.997     3.911 -0.914               1.622                   1.664 -0.042                              2.155                                  1.971 0.184                                            1.596                                                1.722 -0.126cat-1631.797     3.097 -1.300               0.765                   1.378 -0.613                              1.324                                  1.628 -0.304                                            1.253                                                1.427 -0.174           -0.155        -0.004         0.004         -0.016           0.849         0.188          0.112         0.414__________________________________________________________________________ 
    
     
         TABLE G  - GC-PIANO Results Listing Selected Speciations      Ethyl- n-Propyl-     Iso- Iso- 2-Methyl- Naph- Methyl-     SAMPLE # Aromatics Olefins Benzene Toluene Xylenes m-Xylene p-Xylene o-Xylene benzene benzene Paraffins Pentane Hexane n-heptane Paraffins Pentane hexane thenes cyclopentane  LPCCR-33 35.917 0.464 2.697 8.770 8.512 4.013 1.802 2.697 2.292 0.858 22.189 0.685 5.185 7.484 34.195 1.058 4.118 6.511 1.489  LPCCR-28 50.071 1.072 3.476 11.730 12.518 5.885 2.615 4.018 2.803 0.969 15.436 4.823 4.076 3.546 30.457 8.247 2.820 2.090 0.618  LPCCR-30 56.081 1.172 3.613 12.847 14.286 6.725 2.954 4.607 3.080 1.043 12.231 4.162 3.702 2.953 26.915 7.968 2.487 1.495 0.470  LPCCR-31 57.164 1.221 3.665 13.048 14.610 6.880 3.008 4.722 3.119 1.050 12.899 4.187 3.649 2.800 26.202 7.921 2.429 1.352 0.434  LPCCR-33 59.055 1.042 3.779 12.930 14.944 7.232 3.091 4.621 3.058 1.040 13.730 2.320 2.982 2.519 23.973 3.627 2.677 0.912 0.165  LPCCR-34 58.841 1.067 3.830 12.799 14.834 7.196 3.056 4.582 3.043 1.037 12.790 2.282 3.167 2.648 24.957 3.621 2.809 1.009 0.190  LPCCR-35 61.540 1.016 3.993 13.379 15.441 7.492 3.212 4.737 3.191 1.091 10.697 2.158 3.310 2.835 24.323 3.290 2.997 1.127 0.024  LPCCR-45 43.377 0.511 3.962 11.292 10.319 5.308 2.265 2.746 2.372 0.832 14.768 2.329 4.504 3.923 34.565 3.604 3.639 6.029 1.875  LPCCR-47 49.901 0.669 4.786 12.891 12.041 6.171 2.662 3.208 2.682 0.893 13.626 3.040 4.271 3.123 31.137 4.284 3.180 3.915 1.189  LPCCR-48 52.750 0.796 5.131 13.542 12.835 6.600 2.814 3.421 2.786 0.890 14.512 3.244 4.009 2.597 28.642 4.771 2.772 2.748 0.846  LPCCR-50 60.571 1.064 5.730 15.490 15.419 7.921 3.378 4.120 3.168 0.896 13.373 3.509 3.522 1.660 22.731 4.812 1.941 1.334 0.383  LPCCR-51 59.801 1.099 5.498 15.112 15.256 7.828 3.334 4.094 3.124 0.881 14.670 3.245 3.379 1.612 22.330 4.383 1.883 1.157 0.364  LPCCR-59 52.818 1.440 3.647 12.395 13.335 6.669 2.851 3.815 2.872 0.946 13.962 2.309 3.606 3.362 27.254 3.052 2.895 3.579 0.769  LPCCR-64 51.648 1.599 3.724 12.086 12.932 6.453 2.767 3.712 2.825 0.937 14.141 2.247 3.984 3.622 27.237 2.913 2.917 4.377 0.952  LPCCR-70 49.160 1.697 3.595 11.395 12.258 6.092 2.617 3.549 2.735 0.916 15.102 2.067 4.212 3.849 28.330 2.652 2.949 4.654 1.023  LPCCR-72 50.948 1.293 3.852 11.636 12.388 6.134 2.634 3.620 2.706 0.971 14.720 2.011 4.167 3.581 27.692 2.697 2.860 4.205 0.951  LPCCR-77 58.810 1.053 4.394 12.622 13.856 6.708 2.856 4.292 2.797 1.140 11.836 2.148 3.590 2.538 24.587 3.154 2.452 1.994 0.402  LPCCR-78 58.990 1.049 4.432 12.680 13.890 6.739 2.845 4.306 2.802 1.143 11.769 2.158 3.600 2.537 24.476 3.172 2.451 2.000 0.402  LPCCR-79 58.646 0.871 4.745 12.438 13.355 6.328 2.651 4.376 2.962 1.193 11.750 1.573 3.768 2.982 25.585 2.516 2.979 1.626 0.357  LPCCR-80 60.431 0.904 4.709 12.799 14.276 6.714 2.858 4.704 3.057 1.192 10.755 1.513 3.651 2.802 25.202 2.493 2.837 1.398 0.301  LPCCR-81 62.726 0.841 5.012 13.154 14.458 6.843 2.848 4.767 3.172 1.256 10.335 1.491 3.542 2.715 23.079 2.435 2.770 1.359 0.310  LPCCR-82 60.374 0.812 4.954 12.631 13.676 6.470 2.719 4.467 3.062 1.239 10.576 1.140 3.821 3.060 24.993 1.984 3.010 1.702 0.415  LPCCR-83 59.175 0.786 4.879 12.483 13.253 6.281 2.634 4.338 3.019 1.235 10.622 1.043 3.858 3.340 25.721 1.847 3.158 1.959 0.486  LPCCR-84 56.288 0.818 4.898 12.239 13.073 6.199 2.590 4.284 2.990 1.210 11.093 1.056 4.163 3.341 26.241 1.912 3.153 1.987 0.491  LPCCR-85 51.177 0.917 3.612 12.151 14.591 6.917 2.973 4.701 2.957 1.108 11.849 1.374 3.776 3.408 27.353 2.697 3.314 1.666 0.385  LPCCR-86 63.796 1.332 4.380 14.063 16.487 7.857 3.392 5.238 3.593 1.288 9.559 1.141 3.266 2.852 21.861 1.922 2.511 1.575 0.387  LPCCR-87 63.752 1.236 4.585 14.553 16.500 7.846 3.367 5.287 3.591 1.257 9.457 1.034 3.412 2.989 22.271 1.611 3.020 1.533 0.396  LPCCR-88 64.043 1.187 4.691 14.461 16.817 7.973 3.410 5.434 3.547 1.233 9.399 1.171 3.483 2.807 22.501 2.081 2.987 1.179 0.297  LPCCR-89 65.640 1.128 4.540 14.431 17.209 8.154 3.454 5.601 3.639 1.269 8.821 1.007 3.358 2.870 21.922 1.718 3.027 1.332 0.288  LPCCR-90 63.792 1.109 4.252 13.579 16.897 7.924 3.426 5.547 3.603 1.241 9.240 1.185 3.550 2.998 23.589 2.134 3.200 1.325 0.276  LPCCR-91 67.888 1.293 4.255 15.244 19.049 9.091 3.844 6.114 3.783 1.185 8.938 1.529 3.172 2.189 20.316 2.451 2.472 0.811 0.196  LPCCR-92 67.639 1.333 4.194 14.973 18.918 8.992 3.834 6.092 3.785 1.202 8.697 1.412 3.255 2.330 20.575 2.297 2.582 1.004 0.221  LPCCR-93 67.176 1.277 4.455 15.515 18.764 8.903 3.797 6.064 3.715 1.168 8.925 1.330 3.240 2.465 20.758 2.222 2.712 1.065 0.242  LPCCR-94 67.961 1.304 4.620 15.679 19.210 9.150 3.878 6.162 3.737 1.160 8.504 1.392 3.337 2.344 20.566 2.320 2.620 0.955 0.227  LPCCR-95 66.013 1.335 4.512 14.982 18.352 8.739 3.688 5.925 3.568 1.144 9.502 1.393 3.553 2.356 21.375 2.338 2.627 0.946 0.240  LPCCR-96 66.666 1.348 4.143 14.625 18.698 8.716 3.734 5.927 3.734 1.182 9.047 1.445 3.827 2.345 21.847 2.355 2.601 1.128 0.255  LPCCR-97 66.090 1.412 4.202 14.223 18.377 8.857 3.768 6.075 3.685 1.166 9.239 1.436 3.384 2.322 21.050 2.369 2.601 0.972 0.211  LPCCR-98 67.334 1.361 4.341 15.148 18.733 8.936 3.776 6.021 3.689 1.158 9.155 1.497 3.391 2.210 20.592 2.433 2.480 0.891 0.219  LPCCR-99 66.545 1.181 4.983 16.169 18.582 8.989 3.796 5.795 3.640 1.078 8.546 1.885 3.621 2.401 22.158 2.958 2.671 1.036 0.229  LPCCR-100 55.855 0.968 4.131 12.886 15.009 7.420 3.198 4.391 3.143 0.952 12.904 2.273 3.348 3.165 28.138 3.464 3.489 1.639 0.369  LPCCR-101 68.001 0.847 5.388 15.379 17.104 8.164 3.411 5.529 3.584 1.297 8.897 1.084 2.984 2.441 20.004 1.909 2.656 1.054 0.263  LPCCR-102 67.702 0.930 5.410 15.863 17.542 6.421 3.453 5.668 3.635 1.284 8.414 1.156 2.673 2.607 20.938 2.060 2.867 1.059 0.249  LPCCR-103 66.481 0.935 5.674 15.462 16.978 8.063 3.364 5.551 3.733 1.295 8.922 1.062 3.250 2.786 21.557 1.965 2.987 1.236 0.318  LPCCR-104 66.759 1.150 5.408 15.771 18.065 8.639 3.610 5.816 3.744 1.190 8.688 1.290 3.248 2.661 21.580 2.268 2.927 1.087 0.283  LPCCR-105 67.253 1.181 5.411 15.946 18.275 8.736 3.686 5.853 3.778 1.191 8.846 1.310 3.153 2.560 21.105 2.267 2.825 0.897 0.257  LPCCR-106 66.863 1.189 4.996 15.232 18.615 8.332 3.782 6.001 3.855 1.207 8.716 1.344 3.284 2.610 21.527 2.331 2.885 1.067 0.252  LPCCR-107 67.643 1.174 4.674 15.767 19.324 9.237 3.888 6.199 3.901 1.170 8.555 1.333 2.961 2.651 20.916 2.281 2.915 1.044 0.229  LPCCR-108 66.200 1.249 4.647 15.532 19.434 8.271 3.937 6.226 3.894 1.095 9.015 1.371 3.244 2.673 21.811 2.364 2.954 1.029 0.236  LPCCR-109 66.528 1.203 4.461 15.524 19.511 9.288 3.963 6.250 3.912 1.112 9.148 1.300 2.987 2.716 21.331 2.244 2.974 1.064 0.233  LPCCR-110 66.739 1.230 4.672 15.680 19.553 9.319 3.974 6.260 3.896 1.117 8.803 1.389 3.126 2.671 21.612 2.415 2.970 1.024 0.232  LPCCR-111 66.913 1.147 4.452 15.802 19.999 9.572 4.034 6.393 3.960 1.130 9.029 1.369 2.807 2.706 21.386 2.397 2.997 1.008 0.214  LPCCR-112 67.335 1.201 4.536 15.704 19.507 9.290 3.932 6.285 3.835 1.156 8.976 1.290 3.011 2.602 20.988 2.239 2.868 0.981 0.222 
    
     
                                           TABLE H__________________________________________________________________________P.I.A.N.O. ANALYSISby Analytical Automation Specialists, Inc.Licensed to: Ashland Petroleum Co. - Catlettsburg, KY__________________________________________________________________________Sample:       LPCCR 79       Acquired on: 01-07-1994File:         K168.ATB       Normalized to 100%RI Data File: PRODUCT        Processed 253 PeaksGas Chromatograph:        Hewlett Packard 5890Inj. Temp    220° C. Sample Size 0.2 ulDet. Temp    258° C. Split Ratio 131.8Carrier Gas: Helium         Carrier Pressure                                   38 psiColumn:      Supelco DH-100 100M                       Installed onConditions:  35 deg C.Rate 2:      Methane set to 7.00 min.__________________________________________________________________________Composite ReportHydrocarbon Totals by Group TypeType           Wt %          Vol %                            Mol %__________________________________________________________________________Total Paraffins:          9.722         11.750                            11.615Total Iso-paraffins:          21.692        25.585                            23.531Total Naphthenes:          1.554         1.626                            1.624Total Aromatics:          64.681        58.646                            61.389Total Olefins: 0.763         0.871                            0.878Total C14+     0.492         0.511                            0.252Total Unknowns:          1.097         1.012                            0.711Total:         100.000       100.000                            100.000__________________________________________________________________________Totals by Carbon NumberGroup    Wt %     Vol %                 Mol %    Ave. Mw.                               Ave. Sp Gr.__________________________________________________________________________Methane  0.000    0.000                 0.000    0.000                               0.000Ethane   0.000    0.000                 0.000    0.000                               0.000Propane  0.008    0.012                 0.018    44.097                               0.501Butanes: 1.849    2.555                 3.235    58.097                               0.573Pentanes:    3.500    4.407                 4.943    71.978                               0.629Hexanes: 15.490   16.987                 18.927   83.186                               0.722Heptanes:    24.982   25.553                 26.558   95.610                               0.774Octanes: 23.118   22.128                 21.787   107.849                               0.827Nonanes: 17.900   16.431                 15.086   120.598                               0.863Decanes: 8.429    7.598                 6.393    134.016                               0.879C11&#39;s:   2.266    1.963                 1.570    146.715                               0.914C12&#39;s:   0.868    0.843                 0.521    169.345                               0.815C13&#39;s:   0.000    0.000                 0.000    0.000                               0.000C14+     0.492    0.511                 0.252Unknowns:    1.097    1.012                 0.711Total:   100.000  100.000                 100.000  102.979                               0.779__________________________________________________________________________Types by Carbon Number             Wt %         Vol %                              Mol %__________________________________________________________________________Paraffins:      C1             0.000        0.000                              0.000           C2             0.000        0.000                              0.000           C3             0.008        0.012                              0.018           C4             1.344        1.839                              2.350           C5             1.244        1.573                              1.752           C6             3.137        3.768                              3.700           C7             2.575        2.982                              2.611           C8             0.973        1.097                              0.866           C9             0.253        0.279                              0.201          C10             0.044        0.047                              0.031          C11             0.000        0.000                              0.000          C12             0.145        0.152                              0.086          C13             0.000        0.000                              0.000Iso-paraffins:  C4             0.481        0.684                              0.842           C5             1.971        2.519                              2.776           C6             6.519        7.853                              7.688           C7             8.179        9.460                              8.293           C8             3.508        3.940                              3.123           C9             0.902        0.987                              0.721          C10             0.074        0.080                              0.053          C11             0.000        0.000                              0.000          C12             0.058        0.061                              0.035          C13             0.000        0.000                              0.000Aromatics:      C6             5.266        4.745                              6.852           C7             13.616       12.438                              15.020           C8             17.893       16.316                              17.130           C9             16.737       15.157                              14.158          C10             8.273        7.433                              6.281          C11             2.266        1.963                              1.570          C12             0.629        0.594                              0.378          C13             0.000        0.000                              0.000Naphthenes:     C5             0.200        0.213                              0.290           C6             0.356        0.376                              0.430           C7             0.187        0.197                              0.193           C8             0.728        0.758                              0.654           C9             0.008        0.008                              0.006          C10             0.039        0.038                              0.028          C11             0.000        0.000                              0.000          C12             0.036        0.036                              0.022          C13             0.000        0.000                              0.000Olefins:        C2             0.000        0.000                              0.000           C3             0.000        0.000                              0.000           C4             0.024        0.032                              0.044           C5             0.085        0.102                              0.124           C6             0.212        0.244                              0.256           C7             0.425        0.476                              0.440           C8             0.016        0.017                              0.014           C9          C12             0.000        0.000                              0.000          C13             0.000        0.000                              0.000__________________________________________________________________________Components Listed in Chromatographic Orderpk#   Min.  Index      Component     Area Wt %                             Vol %                                 Mol %                                     Grp.                                        Shift__________________________________________________________________________ 1 7.25  300.0      Propane       737  0.008                             0.012                                 0.018                                     P3 0.00 2 7.66  365.8      i-Butane      46268                         0.481                             0.684                                 0.842                                     I4 0.12 3 7.89  389.7      Butene-1/Isobutylene                    1413 0.014                             0.019                                 0.026                                     O4 1.48 4 8.01  400.0      n-Butane      129163                         1.344                             1.839                                 2.350                                     P4 0.00 5 8.14  410.4      t-Butene-2    626  0.006                             0.008                                 0.011                                     O4 0.05 6 8.19  414.4      2,2-Dimethylpropane                    212  0.002                             0.003                                 0.003                                     I5 0.69 7 8.34  424.8      c-Butene-2    388  0.004                             0.005                                 0.007                                     O4 0.89 8 8.91  457.1      3-Methylbutene-1                    238  0.002                             0.003                                 0.003                                     O5 0.92 9 9.31  474.9      i-Pentane     190540                         1.969                             2.516                                 2.773                                     I5 0.02 10   9.67  488.8      Pentene-1     342  0.003                             0.004                                 0.005                                     O5 0.12 11   9.87  495.5      2-Methylbutene-1                    1671 0.017                             0.020                                 0.024                                     O5 0.05 12   10.01  500.0      n-Pentane     120395                         1.244                             1.573                                 1.752                                     P5 0.00 13   10.24  507.6      t-Pentene-2   1110 0.011                             0.014                                 0.016                                     O5 0.37 14   10.51  515.6      c-Pentene-2   683  0.007                             0.008                                 0.010                                     O5 0.50 15   10.68  520.5      2-Methylbutene-2                    3868 0.039                             0.046                                 0.056                                     O5 0.68 16   11.33  537.1      2,2-Dimethylbutane                    66357                         0.682                             0.832                                 0.805                                     I6 0.22 17   12.15  554.9      Cyclopentene  587  0.006                             0.006                                 0.009                                     O5 0.36 18   12.31  558.1      4-Methylpentene-1                    489  0.005                             0.006                                 0.006                                     O6 0.30 19   12.39  559.8      3-Methylpentene-1                    691  0.007                             0.008                                 0.008                                     O6 0.23 20   12.73  566.1      Cyclopentane/MTBE                    19965                         0.200                             0.213                                 0.290                                     N5 0.29 21   12.81  567.5      2,3-Dimethylbutane                    58898                         0.605                             0.725                                 0.714                                     I6 0.27 22   12.93  569.6      2,3-Dimethylbutene-1                    470  0.005                             0.006                                 0.006                                     O6 0.26 23   13.05  571.6      2-Methylpentane                    285897                         2.939                             3.564                                 3.466                                     I6 0.20 24   13.89  585.2      3-Methylpentane                    222965                         2.292                             2.733                                 2.703                                     I6 0.30 25   14.17  589.2      2-Methylpentene-1                    2847 0.029                             0.033                                 0.034                                     O6 0.54 26   14.23  590.1      Hexene-1      821  0.008                             0.010                                 0.010                                     O6 0.29 27   14.95  600.0      n-Hexane      305189                         3.137                             3.768                                 3.700                                     P6 0.00 28   15.07  601.8      t-Hexene-3    1571 0.016                             0.018                                 0.019                                     O6 0.11 29   15.15  603.0      c-Hexene-3    578  0.006                             0.007                                 0.007                                     O6 0.32 30   15.25  604.5      t-Hexene-2    3141 0.032                             0.037                                 0.038                                     O6 0.24 31   15.41  606.8      2-Methylpentene-2                    4999 0.050                             0.057                                 0.061                                     O6 0.04 32   15.66  610.3      3-Methyl-c-pentene-2                    3606 0.036                             0.041                                 0.044                                     O6 0.09 33   15.82  612.5      O13           194  0.002                             0.002                                 0.002                                     O6 0.19 34   15.93  614.1      c-Hexene-2    1721 0.017                             0.020                                 0.021                                     O6 0.15 35   16.41  620.3      3,3-Dimethylpentene-1                    5129 0.051                             0.058                                 0.053                                     O7 0.24 36   16.75  624.6      2,2-Dimethylpentane                    39185                         0.403                             0.473                                 0.409                                     I7 0.09 37   16.96  627.1      Methylcyclopentane                    33641                         0.338                             0.357                                 0.408                                     N6 0.04 38   17.26  630.7      2,4-Dimethylpentane                    37925                         0.389                             0.458                                 0.394                                     I7 0.29 39   17.74  636.2      2,2,3-Trimethylbutane                    6232 0.064                             0.073                                 0.065                                     I7 0.42 40   18.32  642.6      O17           174  0.002                             0.002                                 0.002                                     O7 0.14 41   18.73  646.8      2,4-Dimethylpentene-1                    807  0.008                             0.009                                 0.008                                     O7 0.22 42   19.07  650.3      Benzene       564898                         5.266                             4.745                                 6.852                                     A6 0.27 43   19.29  652.5      3-Methylhexene-1                    372  0.004                             0.004                                 0.004                                     O7 0.02 44   19.61  655.6      3,3-Dimethylpentane                    38564                         0.395                             0.452                                 0.401                                     I7 0.24 45   19.76  657.0      5-Methylhexene-1                    322  0.003                             0.004                                 0.003                                     O7 0.22 46   19.93  658.7      Cyclohexane   1855 0.019                             0.019                                 0.022                                     N6 0.35 47   20.15  660.6      2-Methyl-t-hexene-3                    1413 0.014                             0.016                                 0.015                                     O7 0.17 48   20.53  664.1      4-Methylhexene-1                    570  0.006                             0.006                                 0.006                                     O7 0.23 49   20.78  687.3      4-Methyl-t/c-hexene-2                    3328 0.033                             0.038                                 0.035                                     O7 0.09 50   20.97  667.9      2-Methylhexane                    249033                         2.552                             2.979                                 2.589                                     I7 0.14 51   21.15  689.5      2,3-Dimethylpentane                    91381                         0.937                             1.067                                 0.950                                     I7 0.01 52   21.47  672.2      1,1-Dimethylcyclopentane                    1935 0.019                             0.020                                 0.020                                     N7 0.01 53   21.98  676.4      3-Methylhexane                    307358                         3.084                             3.555                                 3.126                                     I7 0.01 54   22.37  679.6      3,4-Dimethyl-c-pentene-2                    1367 0.014                             0.015                                 0.014                                     O7 0.05 55   22.73  682.4      1c,3-Dimethylcyclopentane                    3599 0.036                             0.038                                 0.037                                     N7 0.15 56   23.09  685.0      1t,3-Dimethylcyclopentane                    3753 0.038                             0.040                                 0.039                                     N7 0.06 57   23.23  686.1      3-Ethylpentane                    32146                         0.329                             0.374                                 0.334                                     I7 0.11 58   23.43  666.6      1t,2-Dimethylcyclopentane                    5758 0.058                             0.061                                 0.060                                     N7 0.18 59   23.66  669.3      2,2,4-Trimethylpentane                    2549 0.026                             0.030                                 0.023                                     I7 0.12 60   24.40  694.6      3-Methyi-c-hexene-3                    1954 0.020                             0.022                                 0.020                                     O7 0.15 61   24.89  697.9      t-Heptene-3   3190 0.032                             0.036                                 0.033                                     O7 0.29 62   25.20  700.0      n-Heptane     251194                         2.575                             2.962                                 2.611                                     O7 0.00 63   25.46  702.0      c-Heptene-3   8205 0.082                             0.093                                 0.085                                     O7 0.21 64   25.61  703.2      2-Methyl-2-hexene                    3164 0.032                             0.035                                 0.033                                     O7 0.08 65   25.87  705.2      3-Methyi-t-hexene-3                    2497 0.025                             0.029                                 0.026                                     O7 0.45 66   26.11  706.9      3-Ethylpentene-2                    1560 0.016                             0.017                                 0.016                                     O7 0.16 67   26.58  710.4      c-Heptene-2   4265 0.043                             0.048                                 0.044                                     O7 0.23 68   27.21  714.9      2,3-Dimethylpentene-2                    3700 0.037                             0.040                                 0.038                                     O7 0.48 69   28.07  720.8      1c,2-Dimethylcyclopentane                    1624 0.016                             0.018                                 0.017                                     N7 0.36 70   28.21  721.7      Methylcyclohexane                    769  0.008                             0.008                                 0.008                                     N7 0.20 71   28.69  724.9      1,1,3-Trimethylcyclopentane                    18448                         0.185                             0.196                                 0.168                                     N8 0.07 72   30.22  734.6      Ethylcyclopentane                    1159 0.012                             0.012                                 0.012                                     N7 0.18 73   30.49  736.2      2,2,3-Trimethylpentane                    18360                         0.188                             0.208                                 0.167                                     I8 0.04 74   30.83  738.3      2,4-Dimethylhexane                    31948                         0.327                             0.370                                 0.291                                     I8 0.05 75   31.79  743.9      1c,2t,4-Trimethylcyclopentane                    2525 0.025                             0.026                                 0.023                                     N8 0.10 76   32.06  745.4      3,3-Dimethylhexane                    16012                         0.164                             0.183                                 0.146                                     I8 0.22 77   32.90  750.1      ?             184  0.002                             0.002                                 0.002  UNK 78   33.12  751.3      1t,2c,3-Trimethylcyclopentane                    834  0.008                             0.009                                 0.008                                     N5 0.09 79   33.36  752.6      O39           131  0.001                             0.001                                 0.001                                     O7 0.09 80   33.67  754.3      2,3,4-Trimethylpentane                    922  0.009                             0.010                                 0.008                                     I8 0.06 81   34.47  758.5      Toluene       1451924                         13.616                             12.438                                 15.020                                     A7 0.16 82   34.72  759.8      2,3,3-Trimethylpentane                    1464 0.015                             0.016                                 0.015                                     I8 0.03 83   35.24  762.4      O43           233  0.002                             0.003                                 0.002                                     O7 0.09 84   35.75  765.0      2,3-Dimethylhexane                    26195                         0.268                             0.298                                 0.238                                     I8 0.37 85   35.97  766.1      2-Methyl-3-ethylpentane                    4415 0.045                             0.050                                 0.040                                     I8 0.46 86   36.17  767.0      1,1,2-Trimethylcyclopentane                    1431 0.014                             0.015                                 0.013                                     N8 0.20 87   36.97  770.9      2-Methylheptane                    83862                         0.857                             0.972                                 0.762                                     I8 0.05 88   37.24  772.2      4-Methylheptane                    41947                         0.429                             0.482                                 0.381                                     I8 0.25 89   37.41  773.0      3-Methyl-3-ethylpentane                    8542 0.087                             0.097                                 0.078                                     I8 0.06 90   37.51  773.4      3,4-Dimethylhexane                    6607 0.068                             0.074                                 0.060                                     I8 0.03 91   37.99  775.6      1,3c-Dimethylcyclohexane                    396  0.004                             0.004                                 0.004                                     N8 0.12 92   38.43  777.6      3-Methylheptane                    102921                         1.052                             1.180                                 0.936                                     I8 0.22 93   38.61  778.5      1c,2t,3-Trimethylcyclopentane                    25484                         0.256                             0.263                                 0.232                                     N8 0.47 94   40.58  787.1      2,2,5-Trimethylhexane                    2157 0.022                             0.025                                 0.017                                     I9 0.04 95   40.77  787.9      3c-Ethylmethylcyclopentane                    506  0.005                             0.005                                 0.005                                     N8 0.05 96   41.19  789.6      3t-Ethylmethylcyclopentane                    737  0.007                             0.008                                 0.007                                     N8 0.41 97   41.43  790.6      2t-Ethylmethylcyclopentane                    1124 0.011                             0.012                                 0.010                                     N8 0.33 98   41.62  791.4      1,1-Methylethylcyclopentane                    594  0.006                             0.006                                 0.005                                     N8 0.00 99   41.99  792.9      2,2,4-Trimethylhexane                    788  0.008                             0.009                                 0.006                                     I9 0.07100   42.36  794.4      1t,2-Dimethylcyclohexane                    862  0.009                             0.009                                 0.008                                     N8 0.41101   42.62  795.5      t-Octene-4    933  0.009                             0.010                                 0.008                                     O8 0.06102   43.19  797.7      1c,2c,3-Trimethylcyclopentane                    3050 0.031                             0.031                                 0.028                                     N8 0.07103   43.49  798.9      1t,3 Dimethylcyclohexane                    291  0.003                             0.003                                 0.003                                     N8 0.01104   43.77  800.0      n-Octane      95201                         0.973                             1.097                                 0.866                                     P8 0.00105   44.51  803.8      1c,4-Dimethylcyclohexane                    865  0.009                             0.009                                 0.008                                     N8 0.01106   44.85  805.6      Octene-2      616  0.006                             0.007                                 0.006                                     O8 0.01107   45.17  807.2      i-Propylcyclopentane                    1212 0.012                             0.012                                 0.011                                     N8 0.08108   46.17  812.2      ?             414  0.004                             0.004                                 0.004  UNK109   47.15  817.0      2,3,4-Trimethylhexane                    1200 0.012                             0.013                                 0.010                                     I9 0.50110   47.97  820.9      N3            4039 0.041                             0.045                                 0.032                                     N8 0.47111   48.91  825.3      2,3,4 Trimethylhexane                    4448 0.045                             0.046                                 0.041                                     I9 0.39112   49.29  827.0      2,2-Dimethylheptane                    698  0.007                             0.007                                 0.006                                     I9 0.61113   50.23  831.3      N4            1200 0.012                             0.013                                 0.010                                     N8 0.49114   50.47  832.3      2,2,3-Trimethylhexane                    2769 0.028                             0.032                                 0.022                                     I9 0.33115   52.05  839.3      n-Propylcyclopentane                    9004 0.090                             0.092                                 0.082                                     N8 0.26116   52.39  840.7      2,6-Dimethylheptane                    4228 0.043                             0.047                                 0.034                                     I9 0.48117   54.49  849.4      Ethylbenzene  341264                         3.242                             2.962                                 3.104                                     A8 0.34118   54.95  851.3      1c,2t,4t-Trimethylcyclohexane                    754  0.008                             0.008                                 0.006                                     N9 0.59119   56.99  859.4      m-Xylene      726750                         6.905                             6.328                                 6.610                                     A8 0.10120   57.25  860.4      p-Xylene      303352                         2.882                             2.651                                 2.759                                     A8 0.20121   57.56  861.6      2,3-Dimethylheptane                    5225 0.053                             0.058                                 0.042                                     I9 0.12122   58.07  863.5      3,4-Dimethylheptane                    1431 0.015                             0.016                                 0.012                                     I9 0.13123   58.31  864.4      3,4-Dimethylheptane                    2495 0.025                             0.028                                 0.020                                     I9 0.11124   59.01  867.1      I4            3424 0.035                             0.038                                 0.028                                     I9 0.14125   59.93  870.4      4-Methyloctane                    16036                         0.164                             0.180                                 0.130                                     I9 0.43126   60.24  871.6      2-Methyloctane                    17708                         0.181                             0.200                                 0.143                                     I9 0.07127   61.67  876.7      3-Ethylheptane                    5188 0.053                             0.058                                 0.042                                     I9 0.01128   62.09  878.2      3-Methyloctane                    20667                         0.211                             0.232                                 0.167                                     I9 0.57129   63.04  881.5      o-Xylene      511912                         4.864                             4.376                                 4.656                                     A8 0.01130   68.66  900.0      n-Nonane      24833                         0.253                             0.279                                 0.201                                     P9 0.00131   70.45  911.9      i-Propylbenzene                    45800                         0.438                             0.402                                 0.370                                     A9 0.20132   72.45  924.8      2,4-Dimethyloctane                    1350 0.014                             0.015                                 0.010                                     I10                                        0.31133   73.83  933.4      2,5-Dimethyloctane                    520  0.005                             0.006                                 0.004                                     I10                                        0.22134   75.41  943.2      3,3-Dimethyloctane                    589  0.006                             0.006                                 0.004                                     I10                                        0.57135   75.97  946.5      n-Propylbenzene                    135770                         1.298                             1.193                                 1.098                                     A9 0.11136   77.35  954.8      1-Methyl-3-ethylbenzene                    313218                         2.995                             2.744                                 2.533                                     A9 0.09137   77.65  956.5      1-Methyl-4-ethylbenzene                    146039                         1.397                             1.284                                 1.181                                     A9 0.31138   78.61  962.1      1,3,5-Trimethylbenzene                    119399                         1.142                             1.045                                 0.966                                     A9 0.08139   79.00  964.4      I15           812  0.008                             0.009                                 0.006                                     I10                                        0.50140   79.70  968.4      5-Methylnonane                    1011 0.010                             0.011                                 0.007                                     I10                                        0.32141   80.06  970.5      1-Methyl-2-ethylbenzene                    172351                         1.648                             1.482                                 1.394                                     A9 0.17142   80.38  972.3      2-Methylnonane                    2960 0.030                             0.033                                 0.022                                     I10                                        0.29143   80.86  975.0      N35           572  0.006                             0.006                                 0.004                                     N10                                        0.00144   81.40  978.0      N29           3280 0.033                             0.033                                 0.024                                     N10                                        0.18145   82.01  981.4      ?             582  0.006                             0.006                                 0.004  UNK146   82.46  983.9      1,2,4-Trimethylbenzene                    592716                         5.704                             5.158                                 4.824                                     A9 0.10147   84.61  995.6      i-Butylbenzene                    15732                         0.151                             0.140                                 0.115                                     A10                                        0.04148   84.98  997.6      sec-Butylbenzene                    16591                         0.160                             0.147                                 0.121                                     A10                                        0.35149   85.44  1000.0      n-Decane      4291 0.044                             0.047                                 0.031                                     P10                                        0.00150   86.18  1006.7      1,2,3-Trimethylbenzene                    182538                         1.746                             1.546                                 1.476                                     A9 0.01151   86.47  1009.3      1-Methyl-3-i-propylbenzene                    28786                         0.277                             0.255                                 0.210                                     A10                                        0.27152   86.87  1012.9      1-Methyl-4-i-propylbenzene                    8697 0.084                             0.077                                 0.063                                     A10                                        0.10153   87.57  1019.1      2,3-Dihydroindene                    38559                         0.369                             0.303                                 0.317                                     A9 0.03154   88.34  1025.9      ?             2880 0.030                             0.024                                 0.025  UNK155   88.53  1027.6      1-Methyl-2-i-propylbenzene                    1835 0.018                             0.016                                 0.013                                     A10                                        0.33156   89.91  1039.5      1,3-Diethylbenzene                    32931                         0.317                             0.290                                 0.240                                     A10                                        0.04157   90.25  1042.4      1-Methyl-3-n-propylbenzene                    91183                         0.877                             0.806                                 0.664                                     A10                                        0.10158   90.70  1046.3      1-Methyl-4-n-propylbenzene                    53844                         0.518                             0.478                                 0.392                                     A10                                        0.53159   90.81  1047.2      n-Butylbenzene                    29713                         0.286                             0.263                                 0.216                                     A10                                        0.67160   91.08  1049.5      1,3-Dimethyl-5-ethylbenzene                    68764                         0.661                             0.595                                 0.501                                     A10                                        0.30161   91.31  1051.5      1,2-Diethylbenzene                    8226 0.079                             0.071                                 0.060                                     A10                                        0.08162   92.06  1057.8      1-Methyl-2-n-propylbenzene                    49398                         0.475                             0.431                                 0.360                                     A10                                        0.56163   93.27  1067.9      1,4,Dimethyl-2-ethylbenzene                    67411                         0.648                             0.585                                 0.491                                     A10                                        0.06164   93.47  1069.5      s-C5Bz/1,3-DM-4-EtBz                    62923                         0.607                             0.559                                 0.416                                     A11                                        0.11165   93.73  1071.6      ?             402  0.004                             0.004                                 0.003  UNK166   94.16  1075.2      1,2-Dimethyl-4-ethylbenzene                    117136                         1.126                             1.020                                 0.853                                     A10                                        0.15167   94.81  1080.4      1,3-Dimethyl-2-ethylbenzene                    10121                         0.097                             0.087                                 0.074                                     A10                                        0.02168   96.19  1091.5      1-Methyl-4-t-butylbenzene                    6213 0.060                             0.056                                 0.041                                     A11                                        0.34169   96.34  1092.8      1,2-Dimethyl-3-ethylbenzene                    40170                         0.386                             0.343                                 0.292                                     A10                                        0.27170   96.87  1097.0      ?             1540 0.016                             0.014                                 0.012  UNK171   97.08  1098.7      ?             1454 0.015                             0.013                                 0.011  UNK172   97.53  1103.2      ?             2161 0.022                             0.020                                 0.017  UNK173   97.68  1104.8      1,2,4,5-Tetramethylbenzene                    67999                         0.654                             0.583                                 0.495                                     A10                                        0.00174   98.05  1108.9      1,2,3,5-Tetramethylbenzene                    105027                         1.010                             0.898                                 0.765                                     A10                                        0.02175   98.35  1112.3      ?             338  0.003                             0.003                                 0.003  UNK176   98.68  1115.9      ?             1124 0.012                             0.010                                 0.009  UNK177   98.93  1118.7      ?             319  0.003                             0.003                                 0.002  UNK178   99.19  1121.5      1-t-Butyl-2-methylbenzene                    176  0.002                             0.002                                 0.001                                     A11                                        0.73179   99.76  1127.7      5-Methylindan 25105                         0.242                             0.215                                 0.166                                     A11                                        0.13180   100.29  1133.5      A3            8118 0.078                             0.070                                 0.054                                     A11                                        0.12181   100.42  1134.9      ?             1746 0.018                             0.016                                 0.012  UNK182   100.58  1136.6      ?             13557                         0.139                             0.124                                 0.095  UNK183   100.77  1138.7      1-Ethyl-2-n-propylbenzene                    24129                         0.233                             0.207                                 0.160                                     A11                                        0.09184   100.99  1141.1      1-Methyl-3-n-butylbenzene                    1199 0.012                             0.010                                 0.008                                     A11                                        0.38185   101.23  1143.6      s-Pentylbenzene                    35349                         0.341                             0.303                                 0.234                                     A11                                        0.09186   101.72  1148.9      n-Pentylbenzene                    2802 0.027                             0.024                                 0.019                                     A11                                        0.53187   101.89  1150.6      1t-M-2-(4-MP)cyclopentane                    3618 0.036                             0.036                                 0.022                                     N12                                        0.16188   102.19  1153.9      ?             16966                         0.174                             0.172                                 0.107  UNK189   102.62  1158.4      1,4-Di-i-propylbenzene                    8582 0.083                             0.074                                 0.052                                     A12                                        0.77190   102.79  1160.2      ?             10567                         0.108                             0.096                                 0.068  UNK191   103.18  1164.3      ?             518  0.005                             0.005                                 0.003  UNK192   103.46  1167.3      ?             17599                         0.180                             0.161                                 0.113  UNK193   103.65  1169.2      Naphthalene   46942                         0.451                             0.349                                 0.358                                     A10                                        0.12194   104.21  1175.1      ?             641  0.007                             0.005                                 0.005  UNK195   104.65  1179.7      I46           5710 0.058                             0.061                                 0.035                                     I12                                        0.30196   104.77  1180.9      ?             952  0.010                             0.010                                 0.006  UNK197   105.14  1184.7      ?             6019 0.062                             0.065                                 0.037  UNK198   105.53  1188.7      1,3-Di-n-propylbenzene                    1105 0.011                             0.010                                 0.007                                     A12                                        0.20199   105.66  1190.1      A5            21053                         0.204                             0.181                                 0.128                                     A12                                        0.47200   105.81  1191.6      ?             13470                         0.138                             0.123                                 0.086  UNK201   106.63  1200.0      n-Dodecane    14222                         0.145                             0.152                                 0.086                                     P12                                        0.00202   107.47  1210.0      ?             1990 0.020                             0.021                                 0.012  UNK203   108.07  1217.1      ?             701  0.007                             0.008                                 0.004  UNK204   108.17  1218.3      ?             1208 0.012                             0.013                                 0.007  UNK205   108.63  1223.7      ?             1480 0.015                             0.016                                 0.009  UNK206   108.88  1226.6      1,2,4-Triethylbenzene                    5638 0.055                             0.049                                 0.034                                     A12                                        0.16207   109.09  1229.1      ?             217  0.002                             0.002                                 0.001  UNK208   109.71  1236.3      ?             270  0.003                             0.002                                 0.002  UNK209   109.81  1237.5      ?             465  0.005                             0.004                                 0.003  UNK210   110.22  1242.3      1-Methyl-4-n-pentylbenzene                    6208 0.060                             0.054                                 0.038                                     A12                                        0.25211   110.56  1246.2      ?             601  0.006                             0.005                                 0.004  UNK212   110.75  1248.4      ?             410  0.004                             0.004                                 0.003  UNK213   111.39  1255.7      ?             3178 0.033                             0.029                                 0.020  UNK214   111.71  1259.4      ?             1762 0.018                             0.016                                 0.011  UNK215   112.10  1263.8      ?             439  0.005                             0.004                                 0.003  UNK216   112.96  1273.6      A1274         22408                         0.217                             0.227                                 0.120                                     A12                                        0.64217   113.67  1281.6      2-Methylnaphthalene                    41140                         0.397                             0.308                                 0.282                                     A11                                        0.68218   114.05  1285.8      ?             861  0.009                             0.007                                 0.006  UNK219   114.98  1296.1      1-Methylnaphthalene                    27764                         0.268                             0.208                                 0.190                                     A11                                        0.03220   116.12  1400.0      C14+          351  0.004                             0.004                                 0.002                                     +  0.00221   117.55  1400.0      C14+          307  0.003                             0.003                                 0.002                                     +  0.00222   119.04  1400.0      C14+          466  0.005                             0.005                                 0.002                                     +  0.00223   119.98  1400.0      C14+          361  0.004                             0.004                                 0.002                                     +  0.00224   121.51  1400.0      C14+          2623 0.027                             0.028                                 0.014                                     +  0.00225   121.65  1400.0      C14+          798  0.008                             0.008                                 0.004                                     +  0.00226   121.77  1400.0      C14+          1464 0.015                             0.015                                 0.008                                     +  0.00227   122.37  1400.0      C14+          3591 0.036                             0.038                                 0.019                                     +  0.00228   122.51  1400.0      C14+          2865 0.029                             0.030                                 0.015                                     +  0.00229   123.46  1400.0      C14+          9089 0.092                             0.096                                 0.047                                     +  0.00230   123.73  1400.0      C14+          4177 0.042                             0.044                                 0.022                                     +  0.00231   124.93  1400.0      C14+          3559 0.036                             0.037                                 0.019                                     +  0.00232   125.10  1400.0      C14+          1019 0.010                             0.011                                 0.005                                     +  0.00233   125.99  1400.0      C14+          3682 0.037                             0.039                                 0.019                                     +  0.00234   127.69  1400.0      C14+          397  0.004                             0.004                                 0.002                                     +  0.00235   128.38  1400.0      C14+          598  0.006                             0.006                                 0.003                                     +  0.00236   129.12  1400.0      C14+          290  0.003                             0.003                                 0.002                                     +  0.00237   129.55  1400.0      C14+          1338 0.014                             0.014                                 0.007                                     +  0.00238   129.88  1400.0      C14+          261  0.003                             0.003                                 0.001                                     +  0.00239   130.21  1400.0      C14+          659  0.007                             0.007                                 0.003                                     +  0.00240   130.73  1400.0      C14+          513  0.005                             0.005                                 0.003                                     +  0.00241   131.05  1400.0      C14+          1161 0.012                             0.012                                 0.006                                     +  0.00242   131.44  1400.0      C14+          1109 0.011                             0.012                                 0.006                                     +  0.00243   132.47  1400.0      C14+          1028 0.010                             0.011                                 0.005                                     +  0.00244   132.77  1400.0      C14+          1015 0.010                             0.011                                 0.005                                     +  0.00245   133.51  1400.0      C14+          706  0.007                             0.007                                 0.004                                     +  0.00246   133.66  1400.0      C14+          508  0.005                             0.005                                 0.003                                     +  0.00247   133.77  1400.0      C14+          1123 0.011                             0.012                                 0.006                                     +  0.00248   134.71  1400.0      C14+          1493 0.015                             0.016                                 0.008                                     +  0.00249   135.21  1400.0      C14+          379  0.004                             0.004                                 0.002                                     +  0.00250   135.51  1400.0      C14+          279  0.003                             0.003                                 0.001                                     +  0.00251   136.37  1400.0      C14+          409  0.004                             0.004                                 0.002                                     +  0.00252   140.65  1400.0      C14+          269  0.003                             0.003                                 0.001                                     +  0.00253   141.68  1400.0      C14+          601  0.006                             0.006                                 0.003                                     +  0.00__________________________________________________________________________