Abstract:
A method for detecting emotional status of an individual, the method including receiving a speech specimen generated by the individual and deriving therefrom intonation information, and generating an output indication of the individual&#39;s emotional status based on the intonation information, wherein the intonation information includes information relating to thorns and wherein the generating step includes computing the individual&#39;s excitement level based on the information relating to thorns and generating an output indication of the excitement level, wherein the intonation information also includes information relating to length of plateaus, and wherein the excitement level includes a decreasing function of (a) the number of thorns in at least a portion of the speech specimen and of (b) the diversity of plateau length within the portion.

Description:
FIELD OF THE INVENTION 
     The present invention relates to apparatus and methods for monitoring emotional states. 
     BACKGROUND OF THE INVENTION 
     Published PCT Application WO 97/01984 (PCT/IL96/00027) describes a method for effecting biofeedback regulation of at least one physiological variable characteristic of a subject&#39;s emotional state, including the steps of monitoring at least one speech parameter characteristic of the subject&#39;s emotional state so as to produce an indication signal, and using the indication signal to provide the subject with an indication of the at least one physiological variable. A system permits the method to be carried out in standalone mode or via the telephone line in which case the indication signal may be derived at a location remote from the subject. Information relating to the subject&#39;s emotional state can be conveyed vocally to a remote party or textually through the Internet, and then processed as required. 
     Published European Patent Application No. 94850185.3 (Publication No. 306 664 537 A2) describes a method and arrangement for determining stresses in a spoken sequence. From a sequence recognized in the spoken speech, a model of the speech is created. By comparing the spoken sequence with the modeled speech, a difference between them is obtained. 
     U.S. Pat. No. 1,384,721 describes a method and apparatus for physiological response analysis. 
     U.S. Pat. No. 3,855,416 to Fuller describes a method and apparatus for phonation analysis leading to valid truth/lie decisions by fundamental speech-energy weighted vibratto component assessment. 
     U.S. Pat. No. 3,855,417 to Fuller describes a method and apparatus for phonation analysis lending to valid truth/lie decisions by spectral energy region comparison. 
     U.S. Pat. No. 3,855,418 to Fuller describes a method and apparatus for phonation analysis lending to valid truth/lie decisions by vibratto component assessment. 
     The disclosures of all publications mentioned in the specification and of the publications cited therein are hereby incorporated by reference. 
     SUMMARY OF THE INVENTION 
     The present invention seeks to provide improved apparatus and methods for monitoring emotional states. 
     There is thus provided, in accordance with a preferred embodiment of the present invention, apparatus for detecting emotional status of an individual, the apparatus including a voice analyzer operative to input a speech specimen generated by the individual and to derive therefrom intonation information, and an emotion reporter operative to generate an output indication of the individual&#39;s emotional status based on the intonation information. 
     Further in accordance with a preferred embodiment of the present invention, the speech specimen is provided over the telephone to the voice analyzer. 
     Still further in accordance with a preferred embodiment of the present invention, the report on the individual&#39;s emotional status includes a lie detection report based on the individual&#39;s emotional status. 
     Further in accordance with a preferred embodiment of the present invention, the intonation information includes multidimensional intonation information. 
     Still further in accordance with a preferred embodiment of the present invention, the multidimensional information includes at least 3-dimensional information. 
     Further in accordance with a preferred embodiment of the present invention, the multidimensional information includes at least 4-dimensional information. 
     Still further in accordance with a preferred embodiment of the present invention, the intonation information includes information pertaining to thorns. 
     Further in accordance with a preferred embodiment of the present invention, the information pertaining to thorns includes the number of thorns in a predetermined time period. 
     Further in accordance with a preferred embodiment of the present invention, the information pertaining to thorns includes the distribution of thorns over time. 
     Additionally in accordance with a preferred embodiment of the present invention, the intonation information includes information pertaining to plateaus. 
     Further in accordance with a preferred embodiment of the present invention, the information pertaining to plateaus includes the number of plateaus in a predetermined time period. 
     Still further in accordance with a preferred embodiment of the present invention, the information pertaining to plateaus includes information pertaining to length of plateaus. 
     Additionally in accordance with a preferred embodiment of the present invention, the information pertaining to length of plateaus includes an average plateau length for a predetermined time period. 
     Still further in accordance with a preferred embodiment of the present invention, the information pertaining to length of plateaus includes the standard error of plateau length for a predetermined time period. 
     Also provided, in accordance with another preferred embodiment of the present invention, is a lie detection system including a multidimensional voice analyzer operative to input a speech specimen generated by an individual and to quantify a plurality of characteristics of the speech specimen, and a credibility evaluator reporter operative to generate an output indication of the individual&#39;s credibility, including detection of lies, based on the plurality of quantified characteristics. 
     Additionally provided, in accordance with another preferred embodiment of the present invention, is a detection method including receiving a speech specimen generated by an individual and quantifying a plurality of characteristics of the speech specimen, and generating an output indication of the individual&#39;s credibility, including detection of lies, based on the plurality of quantified characteristics. 
     Further in accordance with a preferred embodiment of the present invention, the speech specimen includes a main speech wave having a period and wherein the voice analyzer is operative to analyze the speech specimen in order to determine rate of occurrence of plateaus, each plateau indicating that a local relatively low-frequency wave is superimposed onto the main speech wave, and the emotion reporter is operative to provide a suitable output indication based on the rate of occurrence of plateaus. For example, the emotion reporter may provide a suitable output indication when the rate of occurrence of plateaus is found to change. 
     Similarly, each thorn indicates that a local relatively high-frequency wave is superimposed onto the main speech wave. A particular advantage of analyzing plateaus and thorns as shown and described herein is that substantially all frequencies of the speech wave may be analyzed. 
     Also provided, in accordance with another preferred embodiment of the present invention, is a method for detecting emotional status and including establishing a multidimensional characteristic range characterizing an individual&#39;s range of emotion when at rest by monitoring the individual for a plurality of emotion-related parameters, over a first period during which the individual is in an emotionally neutral state, and defining the multi-dimensional characteristic range as a function of the range of the plurality of emotion-related parameters during the first period, and monitoring the individual for the plurality of emotion-related parameters, over a second period during which it is desired to detect the individual&#39;s emotional status, thereby to obtain a measurement of the plurality of emotion-related parameters, and adjusting the measurement to take into account the range. 
     Also provided, in accordance with another preferred embodiment of the present invention, is a method for detecting emotional status of an individual, the method including receiving a speech specimen generated by the individual and deriving therefrom intonation information, and generating an output indication of the individual&#39;s emotional status based on the intonation information. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The present invention will be understood and appreciated from the following detailed description, taken in conjunction with the drawings in which: 
     FIG. 1A is a pictorial illustration of a system for on-line monitoring of a speaker&#39;s emotional state, 
     FIG. 1B is a simplified flowchart illustration of a preferred method for on-line monitoring of a speaker&#39;s emotional state, 
     FIG. 2 is a graphic illustration of a voice segment including a number of thorns, 
     FIG. 3 is a graphic illustration of a voice segment including a number of plateaus, 
     FIG. 4 is a simplified flowchart illustration of a preferred method for performing step  40  of FIG. 1B, 
     FIG. 5 is a simplified flowchart illustration of a preferred method for implementing the truth/neutral emotion profile building step of FIG. 1B, 
     FIG. 6 is a simplified flowchart illustration of a preferred method for performing step  90  of FIG. 1B on a particular segment, 
     FIG. 7 is a simplified flowchart illustration of a preferred method for performing step  100  of FIG. 1B, 
     FIG. 8 is a simplified flowchart illustration of a preferred method for performing step  105  of FIG. 1B, 
     FIG. 9 is a pictorial illustration of a screen display depicting the form, in design mode, just before starting the application of Appendix A, 
     FIG. 10 is a pictorial illustration of a screen display depicting the form, in the run mode of the system of Appendix A, during calibration to a particular subject, 
     FIG. 11 is a pictorial illustration of a screen display depicting the form, in the run mode of the system of Appendix A, during testing of a subject, and 
     FIG. 12 is a simplified block diagram illustration of a preferred system for performing the method of FIG.  1 B. 
     Attached herewith is the following appendix which aids in the understanding and appreciation of one preferred embodiment of the invention shown and described herein: 
     Appendix A is a computer listing of a preferred software implementation of a preferred embodiment of the invention shown and described herein. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     A portion of the disclosure of this patent document contains material which is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or the patent disclosure, as it appears in the Patent and Trademark Office patent file or records, but otherwise reserves all copyright rights whatsoever. 
     FIG. 1A is a pictorial illustration of a system for on-line monitoring of a speaker&#39;s emotional state. As shown, a speech input arriving over a telephone line, in the illustrated embodiment, is received by the system. The system analyzes the speech input in order to obtain an indication of the speaker&#39;s emotional state which indication is preferably provided to the user in real time, e.g. on the display screen as shown. 
     FIG. 1B is a simplified flowchart illustration of a preferred method for on-line monitoring of a speaker&#39;s emotional state. The method of FIG. 1B preferably includes the following steps: 
     Initialization step  10 : Constants are defined such as the threshold values of various parameters, defining ranges which are considered to be indicative of various emotions, as described in detail below. 
     Step  20 : Record a voice, periodically or on demand. For example, segments of 0.5 seconds of voice may be recorded continuously, i.e. each 0.5 secs. Alternatively, segments of any other suitable length may be considered which may or may not overlap. For example, adjacent segments may overlap almost entirely, except for one or a few samples. 
     Digitize the voice recording. 
     Additionally or alternatively overlapping segments of the recording may be sampled. 
     Step  30 : Analyze voice segment in order to mark the crucial portion of the voice segment, i.e. the portion of the voice segment which is thought to actually contain voice information as opposed to background noise. A suitable criterion for voice information detection is amplitude, e.g. the first instance of amplitude which exceeds a threshold is deemed the beginning of the voice information and the end of the voice information is deemed the point after which no threshold-exceeding sound is found for a predetermined duration. 
     Preferably, the samples in the crucial portion are normalized e.g. by amplifying the samples to take advantage of the entire range of amplitude which can be accommodated in memory, e.g. +/−127 amplitude units if 8-bit memory is employed. 
     Step  40 : Count thorns and plateaus in the crucial portion. Compute length of each identified plateau, and compute average plateau length for the crucial portion and standard error for the plateau length. 
     A “thorn” is a notch-shaped feature. For example, the term “thorn” may be defined as: 
     a. a sequence of 3 adjacent samples in which the first and third samples are both higher than the middle sample, or 
     b. a sequence of 3 adjacent samples in which the first and third samples are both lower than the middle sample. 
     Preferably, a thorn is declared even if the first and third samples differ only very slightly from the middle sample, i.e. there is preferably no minimum threshold value for the difference between samples. However, there preferably is a minimum threshold value for the baseline of the thorn, i.e. thorns occurring at very low amplitude are disregarded because they are considered to relate to background noise rather than to voice. 
     FIG. 2 is a graphic illustration of a voice segment  32 , including a number of thorns  34 . 
     A “plateau” is a local flatness in the voice wave. For example, a plateau may be defined as a flat sequence whose length is more than a predetermined minimum threshold and is less than a predetermined maximum threshold. The maximum threshold is required to differentiate local flatness from a period of silence. A sequence may be regarded as flat if the difference in amplitude between consecutive samples is less than a predetermined threshold such as  5  amplitude units if 8-bit memory is employed. 
     FIG. 3 is a graphic illustration of a voice segment  36 , including a number of plateaus  38 . In Appendix A, plateaus are termed “jumps”. 
     The system of the present invention typically operates in one of two modes: 
     a. Calibration—building a profile of the subject&#39;s truth/neutral emotional state by monitoring a subject while the subject is not lying and/or is in a neutral emotional state. 
     b. Testing—Comparing a subject&#39;s speech to the profile of the subject&#39;s truth/neutral emotional state as established during calibration, in order to establish emotional state and/or whether or not the subject is being truthful. 
     If the system is to be used in calibration mode, the method proceeds from step  50  to step  60 . If the system is to be used in testing mode, the method proceeds from step  50  to step  80 . 
     Step  60 : If step  60  is reached, this indicates that the current segment has been processed for calibration purposes. Therefore, the thorn and plateau information derived in step  40  is stored in a calibration table. 
     The processes of steps  20 - 50  are termed herein “voice recording entering processes”. If there are more voice recordings to be entered for calibration purposes, the method returns to step  20 . If entry of all voice recordings for calibration purposes has been completed (step  70 ), the method proceeds to step  80 . 
     Step  80 : Build profile of truth/neutral emotional state for the subject who is currently being tested. This completes operation in calibration mode. Subsequently, the system enters testing mode in which the subject&#39;s voice recordings are compared to his truth/neutral emotional profile in order to identify instances of falsehood or heightened emotion. The subject&#39;s profile typically reflects central tendencies of the thorn/plateau information and is typically adjusted to take into account artifacts of the calibration situation. For example, due to natural stress at the beginning of the calibration process, the initial voice recordings may be less reliable than subsequent voice recordings. Preferably, to obtain a reliable indication of central tendencies, extreme entries in the calibration table may be discarded. 
     Steps  90  onward pertain to the testing mode. 
     Step  90 : Compare thorn/plateau information of current segment to the truth/neutral emotion profile computed in step  80 . 
     Step  100 : Threshold the results of the comparison process of step  90  in order to categorize the current segment as being indicative of various emotions and/or of falsehood. 
     Step  105 : Optionally, compensate for carryover. The term “carryover” refers to a residual emotional state carrying over from an “actual” emotional state occasioned by a first perceived situation, wherein the residual emotional state lingers after the first perceived situation has already terminated. An example of a suitable implementation for step  105  is described herein in the flowchart of FIG.  8 . 
     Step  110 : Display a message indicating the category determined in step  100 . 
     Step  120 : If there are additional segments of voice to be analyzed, return to step  20 . Otherwise, quit. Any suitable number m of segments may be used for calibration such as  5  segments. 
     FIG. 4 is a simplified flowchart illustration of a preferred method for performing step  40  of FIG.  1 B. As described above, in step  40 , thorn/plateau information is generated for the crucial portion of a current voice recording segment. 
     The current length of the plateau is termed “jj”. 
     “Jjmap(jj) is the number of plateaus whose length is exactly jj. 
     “Plat” is the counter counting the number of plateaus regardless of length. 
     “Thorn” is the counter counting the number of thorns. 
     n is the number of samples in a crucial portion under test. 
     In step  150 , the thorn and plateau counters are reset. 
     In step  160 , start loop on all crucial portion samples. The loop. is started at the first crucial sample and terminates at the last crucial sample minus  2 . 
     In step  164  the amplitudes of the samples in the loop are recorded. 
     In steps  170  and  180  the thorns are detected, and in steps  190 ,  195 ,  200  and  210  the plateaus are detected. 
     In step  200 , if the length of the candidate plateau is between reasonable bounds, such as between  3  and  20 , increment the number of plateaus of length jj and increment Plat, the total number of plateaus. Otherwise, i.e. if the length of the candidate plateau is less than  3  or more than  20 , the candidate plateau is not considered a plateau. 
     Whether or not the candidate plateau is deemed a “real” plateau, the plateau length, jj, is zeroed (step  210 ). 
     Step  220  is the end of the loop, i.e. the point at which all samples in the sequence have been checked. 
     In step  230 , compute the average (AVJ) and standard error (JQ) of the plateau length variable, jjmap. 
     In step  240 , compute SPT and SPJ. SPT is the average number of thorns per sample, preferably suitably normalized. SPJ is the average number of plateaus per sample, preferably suitably normalized. 
     According to the illustrated embodiment, emotional status detection is multi-dimensional, i.e. emotional status is derived from the speech information via a plurality of preferably independent intermediate variables. 
     FIG. 5 is a simplified flowchart illustration of a preferred method for implementing the truth/neutral emotion profile building step of FIG.  1 B. 
     In FIG. 5, SPT(i) is the SPT value for segment i. 
     MinSPT is the minimum SPT value measured in any of the m segments. 
     MaxSPT is the maximum SPT value measured in any of the m segments. 
     MinSPJ is the minimum SPJ value measured in any of the m segments. 
     MaxSPJ is the maximum SPJ value measured in any of the m segments. 
     MinJQ is the minimum JQ value measured in any of the. m segments. 
     MaxJQ is the maximum JQ value measured in any of the m segments. 
     ResSPT is the size of the range of SPT values encountered during calibration. More generally, ResSPT may comprise any suitable indication of the extent of variation in the number of thorns which may be expected, when the subject is in a truth/neutral emotional state. Therefore, if the number of thorns in a speech segment is non-normative, with relation to ResSPT, then the subject can be said to be in a nonneutral emotional state such as an emotional state characterized by excitation or even arousal. ResSPT is, therefore, typically an input to the process of evaluation of SPT values generated during unknown emotional circumstances. 
     ResSPJ is the size of the range of SPJ values encountered during calibration. More generally, ResSPJ may comprise any suitable indication of the extent of variation in the number of plateaus which may be expected, when the subject is in a truth/neutral emotional state. Therefore, if the number of plateaus in a speech segment is non-normative, with relation to ResSPJ, then the subject can be said to be in a nonneutral emotional state, such as an emotional state characterized by a feeling of internal contradiction or cognitive dissonance. ResSPJ is, therefore, typically an input to the process of evaluation of SPJ values generated during unknown emotional circumstances. 
     ResJQ is the size of the range of JQ values encountered during calibration which serves as a baseline value for evaluation of JQ values generated during unknown emotional circumstances. 
     It is appreciated that the baseline need not necessarily be a 4-dimensional baseline as shown in FIG. 5 but may alternatively be even one-dimensional or may have many more than  4  dimensions. 
     FIG. 6 is a simplified flowchart illustration of a preferred method for performing step  90  of FIG. 1B on a particular segment. As described above, in step  90 , thorn/plateau information of a current segment is compared to the truth/neutral emotion baseline computed in step  80 . 
     Step  400  is an initialization step. 
     Step  410  computes the deviation of a current crucial portion from the subject&#39;s previously computed truth/neutral emotional state profile. In the illustrated embodiment, the deviation comprises a four-dimensional value including a first component related to the number of thorns, a second component related to the number of plateaus, a third component related to the standard error in the plateau length and a fourth component related to average plateau length. However, it is appreciated that different components may be employed in different applications. For example, in some applications, the distribution of thorns (uniform, erratic, etc.) over a time interval may be useful in deriving information regarding the subject&#39;s emotional state. 
     “Breakpoint T ” is a threshold value characterizing the acceptable range of ratios between average number of thorns in truth/neutral emotional circumstances, and the particular number of thorns in the current crucial portion. 
     “Breakpoint J ” is a threshold value characterizing the acceptable range of ratios between average number of plateaus in truth/neutral emotional circumstances, and the particular number of plateaus in the current crucial portion. 
     “Breakpoint Q ” is a threshold value characterizing the acceptable range of ratios between average standard error of the number of plateaus in truth/neutral emotional circumstances, and the particular standard error in the number of plateaus in the current crucial portion. 
     “Breakpoint A ” is a threshold value characterizing the acceptable range of ratios between average plateau length in truth/neutral emotional circumstances, and the particular average plateau length in the current crucial portion. 
     Steps  420 - 470  update the subject&#39;s profile to take into account the new information garnered from the current segment. In the illustrated embodiment, only the ResSPT and ResSPJ values are updated, and only if the deviation of a current crucial portion from the subject&#39;s previously computed truth/neutral emotional state profile is either very large (e.g. exceeds predetermined ceiling values) or very small (e.g. falls below certain typically negative predetermined floor values). If the deviation of the current crucial portion from the truth/neutral profile is neither very large nor very small (e.g. falls between the ceiling and floor values), the subject&#39;s profile is typically left unaltered at this stage. 
     In steps  460  and  470 , if zzSPT and zzSPJ, respectively, are very close to zero, then the system&#39;s sensitivity is increased by decrementing ResSPT and ResSPJ respectively. 
     Step  480  generates suitable, typically application-specific combinations of the deviation components computed in step  410 . These combinations are used as a basis for suitable emotional classification criteria, such as the emotional classification criteria specified in FIG.  7 . The emotional classification criteria of FIG. 7 determine whether or not to classify the subject as exaggerating, as being untruthful, as being evasive, as being confused or unsure, as being excited, or as being sarcastic. However, it is appreciated that different emotional classifications may be employed in different situations. 
     In the illustrated embodiment, the SPT information is mainly used to determine the excitement level. More specifically zzSPT is used to determine the value of crEXCITE, which may also depend on additional parameters as crSTRESS. For example a crEXCITE value of between 70 and 120 may be deemed normal, whereas values of between 120 and 160 may be deemed indicative of medium excitement and values exceeding 160 may be deemed indicative of high level excitement. 
     In the illustrated embodiment, the SPJ information is mainly used to determine feelings of psychological dissonance. For example, a zzSPJ value of between 0.6 and 1.2 may be deemed normal, whereas a value of between 1.2 and 1.7 may be deemed indicative of confusion or uncertainty. A value exceeding 1.7 may be deemed indicative of awareness of voice on the part of the subject, and/or of an attempt of the subject to control his voice. 
     In the illustrated embodiment, the zzJQ and crSTRESS values are mainly used to determine the stress level. For example, a crSTRESS value of between 70 and 120 may be deemed normal, whereas values of over 120 may be deemed indicative of high stress. 
     In the illustrated embodiment, the AVJ information is used to determine the amount of thought invested in spoken words or sentences. For example, if crTHINK exceeds a value of 100 then the amount of thought invested in a last sentence spoken is higher than the amount of thought invested in the calibration phase. This means that the person is thinking more about what he is saying than he did in the calibration phase. If the value is less than 100 the person is thinking less about what he is saying than he did in the calibration phase. 
     In the illustrated embodiment the crLIE parameter is used to determine truthfulness. A crLIE value to 50 may be deemed indicative of untruthfulness, values of between 50 and 60 may be deemed indicative of sarcasm or humor, values of between 60 and 130 may be deemed indicative of truthfulness, values of between 130 and 170 may be deemed indicative of inaccuracy or exaggeration, and values exceeding 170 may be deemed indicative of untruthfulness. 
     Referring back to FIG. 6, the parameters mentioned above may receive the following values: 
     Breakpoint T =Breakpoint J =Breakpoint Q =Breakpoint A =1.1 
     Ceiling T =Ceiling J =1.1 
     Floor J =Floor T =−0.6. 
     Increment T =Increment J =Decrement T =Decrement J =0.1 
     Minimal T =Minimal J =0.1 
     It is appreciated that all of the numerical values are merely examples and are typically application-dependent. 
     FIG. 7 illustrates the method for converting the various parameters in to messages which may be displayed, as shown for example in FIG.  1 . 
     FIG. 8 represents a method for fine tuning the truth/neutral emotional state. 
     Appendix A is a computer listing of a software implementation of a preferred embodiment of the invention shown and described herein which differs slightly from the embodiment shown and descnbed herein with reference to the drawings. 
     A suitable method for generating the software implementation is as follows: 
     a. On a PC equipped with a microphone, a sound card and Visual Basic™ Version 5 software, generate a new project. 
     The recording setting of the sound card may operate in accordance with the following parameters: 11 KHz, 8 bit, mono, PCM. 
     b. Place a timer object on the default form which appears in the new project. The timer object is called “timer  1 ”. 
     c. Place an MCI multimedia control object on the form. This object is called “mmcontrol  1 ”. 
     d. Place 5 label objects on the form. These labels are called label 1 , label 2 , label 3 , label 4  and label 6 . 
     e. Create 4 label arrays on the form. Rename the arrays as follows: SPT(0..4), SPJ(0..4), JQ (0..4), AVJ(0..4). 
     f. Place a command button on the form and change its caption property to end. The command button is called “command  1 ”. 
     g. Generate code for the form by keying in the pages of Appendix A which are headed “form  1 ”. 
     h. Add a module to the project. Generate code for the module by keying in the pages of Appendix A which are headed “Feelings_detector”. 
     i. Connect a microphone to the PC. 
     j. Press (F5) or “run” in order to start the application. 
     FIG. 9 is a pictorial illustration of a screen display depicting the form, in design mode, just before starting the application. 
     FIG. 10 is a pictorial illustration of a screen display depicting the form, in run mode, during calibration to a particular subject. 
     FIG. 11 is a pictorial illustration of a screen display depicting the form, in run mode, during testing of a subject. 
     The values of the CoR_msgX variable in Appendix A are as follows: 
     1—truthfulness, 2—sarcasm, 3—excitement, 4—confuision/uncertainty, 5—high excitement, 6—voice manipulation, 7—lie/ false statement, 8—exaggeration/inaccuracy. 
     Variables carrying data of the current crucial portion have names which begin with the following characters: cor_. 
     Baseline factors have names which begin with the following characters: 
     cal_. 
     Breakpoint factors have names which begin with the following characters: 
     bp_. 
     ResSPT and resSPJ are called ResT and ResJ respectively. 
     FIG. 12 is a simplified functional block diagram illustration of a system for detecting emotional states which is constructed and operative in accordance with a preferred embodiment of the present invention and which is operative to perform the method of FIG.  1 B. As shown, the system of FIG. 12 includes a voice input device such as a tape recorder  700 , microphone  710  or telephone  720  which generates speech which is input by an emotion detection workstation  735  via an A/D converter  740 . A voice window recorder  750  typically partitions the incoming speech-representing signals into voice windows or segments which are analyzed by a voice window analyzer  760 . The voice window analyzer compares the voice windows or segments to calibration data stored in unit  770 . The calibration data is typically derived individually for each individual subject, as described in detail above. A display unit or printer  780  is provided for displaying or printing an emotional status report, preferably on-line, for the user of the system. 
     It is appreciated that the software components of the present invention may, if desired, be implemented in ROM (read-only memory) form. The software components may, generally, be implemented in hardware, if desired, using conventional techniques. 
     It is appreciated that the particular embodiment described in the Appendix is intended only to provide an extremely detailed disclosure of the present invention and is not intended to be limiting. 
     It is appreciated that various features of the invention which are, for clarity, described in the contexts of separate embodiments may also be provided in combination in a single embodiment. Conversely, various features of the invention which are, for brevity, described in the context of a single embodiment may also be provided separately or in any suitable subcombination. 
     It will be appreciated by persons skilled in the art that the present invention is not limited to what has been particularly shown and described hereinabove. Rather, the scope of the present invention is defined only by the claims that follow: