Abstract:
In an air traffic control system, an in-line, data cable interface is disclosed for air traffic control signals which provides data access for use by an external computer system while preventing the disruption of the existing air traffic control signals. The interface provides non-intrusive data access even when the conductors of the data cable interface are short circuited. An external computer system has an associated software program capable of compiling received signals from the in-line data cable interface together with signals from other data sources and displaying the signals in, upon instructions of the user, hexadecimal form, polar graphical form or table form or recording the data onto computer or floppy disk. The air traffic control data is compared with data from another source such as a noise detector to monitor aircraft noise. The system provides a step-by-step method of testing and eventually integrating software and hardware into the existing air traffic control system without disrupting ongoing operations.

Description:
FIELD OF THE INVENTION 
     The invention relates to apparatus and method for providing an air traffic control system with data which is non-intrusively received and formatted by computer hardware and software into selected display arrangements. More particularly, it is directed to the non-intrusive receipt of air traffic control data, and comparing it with other data for purposes such as monitoring aircraft noise. 
     BACKGROUND OF THE INVENTION 
     Air Traffic Control is a system that prevents collisions between aircraft, particularly aircraft flying over or near populated areas. Air congestion is most common near airports, where many aircraft of various types may be flying in diverse directions and to distinct destinations at different speeds and altitudes. Air Traffic Control functions, however, to ensure that such aircraft, including private and commercial aircraft flights, are coordinated and proceed safely in an untroubled manner without unnecessary interruptions. 
     The Air Traffic Control centers are continuously provided with and receive flows of various categories of data such as: flight plan data, flight track data and meteorological data. Flight plan data includes aircraft identification, departure airport and destination airport, route plan, desired cruising level, departure time, and estimated time of arrival. Flight track data comprehends each aircraft&#39;s altitude, range, speed and direction of travel. Meteorological information comprises wind speed and direction, visibility, cloud base, air temperature and barometric pressure. All such data received by Air Traffic Control are processed by digital computers to provide the Air Traffic Controllers with the information they need when and as requested. Meteorological data is typically provided from local sources and from meteorological centers. 
     Noise Abatement Divisions of civil airport authorities require the availability of specific information so that airport noise may be monitored and controlled. Such information includes all publicly relatable aircraft track data which involve a particular geographical area of concern, which, generally, includes the airport and vicinity. Flight track information is currently acquired by the airport&#39;s radar system. The geographical area of concern is, however, usually less then that covered by the airport&#39;s radar system. Additionally, the Noise Abatement Division comprehends flight plan data that includes identification of the air carrier (if a commercial aircraft), flight number (if a scheduled flight), and aircraft type. Flight plan data must also be correlated with the flight track data. The Noise Abatement Division then uses the correlated flight plan data and flight track data with existing automated noise evaluation systems to evaluate the noise generated in the geographical area of concern. 
     Furthermore, airport planners, airport operators and local governments are required to address recurring problems of assessing noise impact. The significance of these problems is underscored by increasing public awareness of environmental and safety concerns. 
     To monitor flight track data and airport noise data successfully, a need exists for a reliable non-intrusive data supply system. The data supply source should provide ready access to the data of interest so it may be recorded and used for monitoring and control purposes. But, it is essential that the data interface be non-intrusive to prevent undesirable and potentially disastrous interference with the air traffic control data requisite for an orderly flow of air traffic. 
     It is anticipated that the need for a reliable, accurate Air Traffic Control will increase as airline traffic volume continues to grow. Unquestionably, the present system works quite well although parts of the system are quite old. Modernization of a system that must be operational twenty-four hours a day and which has a demonstrated excellent safety record can prudently be introduced with only the greatest care. Testing and implementing new air traffic monitoring systems must be accomplished without disturbance to existing systems. In particular, not only should new, untested computers and computer programs be operated without disruption of ongoing air traffic operations, but their testing and evaluation must include extended periods of parallel employment with existing systems. 
     Attempts to supersede existing hardware and software applications used in air traffic control by an advanced automation program have been plagued by delays and cost overruns. Moreover, the system is being outpaced by advances in technology. For example, commercial aircraft have onboard processors that can calculate the most advantageous flight paths for fuel efficiency or speed, a capacity which is seldom, if ever, used by air traffic control centers for routing commercial flights. Further, the &#34;NAVSTAR&#34; positioning system can determine the location of an aircraft to within one hundred meters; yet, it is little used in the air traffic control system despite the tremendous advantage it offers. Also, aircraft display modeling and direct-voice inputs provide unique opportunities for interaction with air traffic control system for significant safety and operational advances that are difficult to incorporate into the present air traffic control system, considering its limitations. 
     An object of this invention is to provide, non-intrusively, from an existing cable, air traffic control data in hexadecimal, polar graphical or tabular form. The invention should provide the necessary data interface and decoding software program while simultaneously it effectively prevents interference with or interruptions to other data flow systems. 
     A further object of this invention is to provide a parallel, non-intrusive system capable of furnishing previously unavailable data and control into the present air traffic control system for testing and use, temporary or permanent, in parallel or in addition to the existing air traffic control system, without disrupting or in any sense endangering the integrity of the air traffic control system. 
     SUMMARY OF THE INVENTION 
     Part of the present invention is directed to a device that provides a non-intrusive interface with an existing data communication cable. The device prevents interference with or interruptions to the existing data flow. 
     The complete system, however, in addition to the non-intrusive data cable interface, includes a digital personal computer, a custom parallel interface board, a signal repeater card and an associated supporting software program. It, preferably, also includes availability to data sources other than provided through the non-intrusive data cable interface such as, for example, the &#34;NAVSTAR&#34; global positioning system. 
     The in-line cable connector comprises a double ended enclosure having electrical connections on each end of the enclosure. Each electrical connection on the ends of the enclosure is electrically interconnected within the enclosure by twisted wire pairs. A further electrical interface is provided in which data is transmitted into and from the enclosure via its vertical sides or face. This further electrical interface electrically interconnects to the in-line cable between the two end bulkhead connectors. It also incorporates a protective resistor on each of the plurality of electrical conductors that comprise the electrical interface. 
     Each of the electrical connectors used on the in-line cable connector may include multiple electrical conductors. On one end of the in-line cable connector, the bulkhead connector provides a plurality of pins that extend upward and normally from the enclosure and on the opposite end of the in-line cable connector a plurality of corresponding sockets is provided which is also arranged external to the enclosure. The second electrical penetrating interface comprises interconnecting mating halves, one half provided with pins and the other being furnished with sockets. The half of the interface that has pins is mounted inside the electrical enclosure. This invention may comprehend multiple second electrical penetrating interfaces. Each conductor attached to the penetrating interface has a series resistance element. 
     This system provides a non-intrusive interface to satisfy the need to monitor any desired or existing air traffic control data without interfering with or interrupting the data flow of the ongoing system. The complete in-line cable interface is compact and yet houses multiple conductor bundles. The protective resistor elements, provided within the interface circuitry, allow the passage of in-line signals despite a short circuit in the penetrating connection. 
     Combined with the non-intrusive interface into data carried by an existing in-line cable, the invention is directed to an associated supporting software program that receives, decodes and displays data in hexadecimal, polar graphical or tabular form with the option of recording the data to disk. 
     The software program receives the string of binary information transmitted from the non-intrusive interface, reads the information by isolating the information bits in it, decodes them and displays the information received in hexadecimal, polar graphical or tabular form with the option of recording the received information to the hard drive. The information bits usually pertain to beacon signals, radar search signals, sector mark signals, alarm signals or weather signals, but this invention comprehends other signals pertaining the air traffic control. It also comprehends the receipt of information in data form which may be provided independently of air traffic control or mixed with data from the in-line cable for testing and evaluation of new systems including new and/or previously unused computer hardware and software systems and arrangements. 
     These and other features, aspects, and advantages of the present invention will be better understood with regard to the following description, including the appended claims and accompanying drawings wherein: 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a diagrammatic representation of the overall data interface system. 
     FIGS. 2A and 2B illustrate front and side views respectively, of the in-line, non-intrusive data cable interface housing and its interior, including for clarity only two associated electrical connectors. 
     FIG. 3A is a diagrammatic detail of the electrical circuit between the associated electrical connectors. 
     FIGS. 3B and 3C are rear views of connectors mounted in the housing depicted in FIG. 2A. 
     FIG. 3D is an internal representation of the bulkhead connector shown in FIG. 2A. 
     FIGS. 4A, 4A-1, 4B, 4C, 4D and 4E are the program operational flow charts for the invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring to FIG. 1, in which the overall data interface system is illustrated, non-intrusive data cable interface K is connected to the output connectors of a combined sensor receiver and processor (SRAP) and surveillance and communication interface processor (SCIP) designated by reference character A. The interconnection of A with air traffic control centers, designated by reference character C, is referred to herein as data cable B. 
     Non-intrusive data cable interface K is interfaced with a signal repeater 2 via a relatively short non-intrusive interface cable 1. Signal repeater 2 provides additional fault protection. Its output signals are capable of transmission up to seventy-five feet along a signal repeater cable 3. Cable 3 is connected to an interface board 4 which transmits data and handshake signals from signal repeater 2 thereto. Cable 3 also provides power to signal repeater 2 from interface board 4. 
     Interface board 4 receives and buffers bursts of data and transfers them to the internal bus of a computer system 8 at an acceptable rate. Computer system 8 is typically an AT-class machine with a minimum operating speed of twelve MHz. Computer system 8 includes a resident software program that receives user-specified inputs, performs all system initializations, accomplishes data synchronization, recognition, validity checks, reformatting, maintains a user information display, and records the data onto disk. It can also include a plurality of monitors, keyboards and a network. 
     As shown in FIGS. 2A and 2B, a non-intrusive in-line cable connector comprises an enclosure or housing which has mounted thereon an external bulkhead connector 22 with sockets 19 therein below the housing, and a further external bulkhead connector 25 with pins 20 extending vertically above housing 11. A pair of tap connectors 17 and 21 are mounted on housing 11 between bulkhead connectors 22 and 25. These tap connectors include two portions, internal portions 15 that include sockets 16 and 16a respectively, (FIG. 3A, 3B and 3C), and an external portions 18. 
     Bulkhead connector 25 is electrically interconnected to bulkhead connector 22 by insulated conductor pairs 9. Only one of many such pairs is shown in FIG. 2B for clarity. Tap connectors 17 and 21 are electrically interconnected with the bulkhead connector 20 by conductor pairs 7; again only one pair is shown for clarity. 
     Tap connectors 17 and 21 provide access for, and thus interconnect with, the external data monitoring and recording system of data cable B from the SRAP/SCIP A. Separating tap connectors 17 and 21 from bulkhead connector 25 and the data flow conductors 9 are protective resistors 5. The protective resistors 5 are connected to electrical connection receivers 16 and 16a in portions 15 and are connected to conductor pairs 7 via pin connectors 6. 
     FIG. 3A illustrates the electrical conductor interconnections within housing 11 in detail. Each of the individual conductors pairs 9 are connected between the facing internal parts of the bulkhead connectors 25 and 22. They comprise, in essence, a portion of the SRAP/SCIP data cable B. Also illustrated in detail are the conductor pairs 7 connected between connection receivers 16 and 16a and the internal portion 24 of the bulkhead connector 25, the combination being designated 24/25 in the drawing. The protective isolation resistors 5 are shown connected in series between the connection receivers 16 and 16a and the internal portion 24 of the bulkhead connector 25. Illustrating the sockets of the internal portion 24 of the bulkhead connector 25 is FIG. 3D. Sockets of the external portions of tap connectors 17 and 21 are the same as shown in FIGS. 3B and 3C. 
     Housing 11 is typically constructed of metal. The bulkhead connectors 22 and 25 are removably attached to housing 11. Internal portion 24 (see FIG. 3D) of the bulkhead connector 25 includes solder receptacles used to interconnect the twisted pairs 9 and 7. The connection receivers 16 and 16a may also include solder receptacles for the protective isolation resistors 5. 
     FIGS. 3A, 3B, 3C and 3D disclose in detail the connections between the lower bulkhead connector 22 and internal portion 24 of the upper bulkhead connector 25. Further, the connections of the various twisted wires plus a ground wire, between the internal portion 24 of the upper bulkhead connector 25 and the socket connection members 16 and 16a of tap connectors 17 and 21 are also shown. 
     When used, the in-line, non-intrusive data cable interface K is installed in-line with the existing SRAP/SCIP data cable B at a point near a sensor receiver and processor or a surveillance and communication interface processor. Tap points are provided to cable 1 by the system via the tap connectors 17 and 21 to allow monitoring and recording of existing input and output processor data used by flight control personnel at air traffic control centers. 
     Cable 1 is received by the signal repeater 2 that, in turn, relays signals to interface board 4 which buffers bursts of data and relays them to the internal bus of the computer system 8 in which operators can receive ongoing and past information from the non-intrusive data using the associated software program. For safety reasons, it is critical that the in-line interface does not interfere with the existing data flow. Protective resistors 5 provide fault isolation from the existing data flow circuitry. If a short circuit should occur anywhere between and including connection members 16 and 16a to computer system 8, protective resistors 5 prevent the interruption of the existing data flow. Attention is invited to the following Table 1 that includes short circuit current values in the event that a worst case short circuit should occur in a typical system. 
     
                       TABLE 1______________________________________SHORT-CIRCUIT CURRENT VALUESShort type     Isolation   Short-circuit current______________________________________Data line/data line     2(1.5) = 3 kΩ                 -5 V /3 kΩ ≈ 1.7 mAData line/chassis     1.5 kΩ                 -5 V/1.5 kΩ ≈ 3.3 mAData line/+5 Vdc     1.5 kΩ                 (-5 V - (5 V))/1.5 kΩ ≈ 6.7______________________________________                 mA 
    
     Table 1 is based on the assumption that each line may provide at least fifty milliamperes of current drive. As indicated by the values in Table 1 the isolation resistors 5, which are each 1.5 K OHMS, effectively prevent the interruption of the existing data flow in the input/output processor data SRAP/SCIP data cable B, irrespective of whether the short is between individual conductors, a conductor or ground (chassis) or a data line and a 5-volt dc source. 
     The in-line connector transmits the data acquired from the SRAP/SCIP system to signal repeater 2 which is capable of further transmitting the data uncorrupted through up to seventy-five feet of signal repeater cable 3 to interface board 4 that powers the signal repeater and receives and buffers bursts of data and transmits the data to a computer system 8. Interface board 4 is preferably also capable of connecting independently, or additionally, to data sensor sources via communications link E for any number of reasons, including testing for air traffic control purposes. The computer system 8 comprises an International Business Machines, Inc. compatible personal computer operating with an 80286 Central Processing Unit with a minimum speed of 12 MHz, input/output resources with a minimum 640 K Random access memory, a main storage unit capable of supporting at least 4 Megabytes, a monitor and a manually operated keyboard operating under a disk operating system of DOS 2.xx or later versions. 
     FIGS. 4A through 4E are program operational flowcharts of the associated software programs. The following Table 2 sets forth the programs in pseudocode and is cross-indexed with FIGS. 4A through 4E. 
     
                       TABLE 2______________________________________                   FLOW                   CHARTPSEUDOCODE              INDEX______________________________________INITIALIZE: program     100OPEN LIBRARIES: stdlib.h, stdio.h, io.h,                   102dir.h, conio.h, fcntI.h, dos.h, bios.h, math.h,graphics.h, atrain.hDEFINE: bit pattern on input message                   102DEFINE &amp; DECLARE: variables &amp;                   102functionsINITIALIZE: variables &amp; arrays                   102DISPLAY: Title header   104READ: Parity Table      106DISPLAY: Command Block  108IF: Keystroke calls- &#34;Help&#34;                   110 DISPLAY: Help Screens and enable EXIT                   120key  IF: keystroke calls for exit, GO TO                   121104IF: Keystroke calls- &#34;Hex&#34;                   110 DISPLAY: Title block for data                   130presentation in hexadecimal form enable EXITkey CALL: interrupt subroutine                   200 ADDRESS &amp; READ: interface input data                   202 DEFINE: variables with input                   204 DISABLE: reading of interface input                   205while processing current input DISPLAY: data          2221  IF: keystroke calls for exit, GO TO                   131104 Scroll screen to display data and GO TO                   132200IF: Keystroke calls- &#34;Rappi&#34;                   110 DISPLAY: Title block for data                   140presentation in polar graphical form andenable exit key INITIALIZE: graphics programs                   142 INITIALIZE: variables  142 DISPLAY: Polar Graphics with sweep                   144 CALL: interrupt subroutine                   200 ADDRESS &amp; READ: interface input data                   202 DEFINE: variables with input                   204 DISABLE: reading of interface input                   205while processing current input IF parity incorrect, correct parity                   208 IF output data not synchronous with input                   210data, GO TO 200 ELSE: Insert &#34;dummy&#34; status                   212 Read DOS time          214 Read 32-bit input from interface                   216 Save 32-bit input      218 Shift message string to ID bits and read                   220 IF MESSAGE: Beacon     230  IF: Not synchronous, GO TO 200                   232  Reformat DOS time     234  IF: Test bit on in message                   236   Make BRTQC label     240  Else: Make BEACON label                   238  Shift message bits to BEACON data                   242inputs  Read BEACON data and reformat                   242  Increment count of total BEACON                   244signals IF Message: Radar      250  IF: Not synchronous, GO TO 200                   252  Reformat DOS time into prograrn                   254memory   IF: Test bit on in message                   256    Make SRTQC label    258   Else: Make SEARCH label                   260  Shift message string to SEARCH input                   262bits and read.  Format SEARCH input bits for display                   262  Increment count of total searches                   264 IF Message: ALARM      270  IF: Not synchronous, GO TO 200                   272  Reformat DOS time into program                   274memory  Format port # for display                   276  Shift message string to ALARM input                   278bits and read  Format ALARM input bits for display                   278  Clear alarmed processor&#39;s message field                   280  Place End-of-Message bit                   280Increment total ALARM count                   280  IF: Fatal alarm bit set                   281   GO TO 200            282 IF Message: SECTOR MARK                   290  IF: Not synchronous   292   IF: Sector 0 message 294   IF: North Flag set   296    Get current DOS time and                   298Go TO 308   ELSE: Set North Flag, save                   300current time as last sector 0 and Go TO 200    Save current time as last Sector                   2980 message   ELSE: GO TO 200      301  ELSE: Format DOS time for Display                   302and save  Shift message string to SECTOR                   304MARK input and read  IF SECTOR MARK for sector Zero                   306   Compute time difference since last                   308sector mark 0 message   IF NOT within +/- 10% of scan rate                   310    Reset synchronousity and North                   312flag    Increment NO SYNC count                   312and GO TO 200   ELSE: GO TO 314      310  ELSE: GO TO 314       309  Save current time for next Sector 0                   314check  Make Correct SRTQC label                   315  Clear unused fields and put in Port #                   316  Format SECTOR MARK input data for                   318display  Set End-of-Message Bit and increment                   319total SECTOR MARK COUNT IF Message: WEATHER    320  IF: Not synchronous, GO TO 200                   322  Shift message string to WEATHER                   324input bits and read  Increment TOTAL WEATHER count                   326  GO TO 200Write reformatted data to disk buffer                   2242DISPLAY: data           2222 IF: keystroke calls for exit, GO TO 104                   141GO TO 200               330IF: Keystroke calls- &#34;Preview&#34;                   110 Display: Mode 3 option screen and enable                   152exit key Read from keyboard Mode 3 target code                   154or &#34;null&#34; code  IF: &#34;Null code&#34; entered GO TO 156                   154  IF: Mode 3 target code entered                   154   Display Mode 3 target data in                   155nested table and GO TO 156 Display data and error count in table                   156 CALL: interrupt subroutine                   200 ADDRESS &amp; READ: interface input data                   202 DEFINE: variables with input                   204 DISABLE: reading of interface input                   205while processing current input IF parity incorrect, correct parity                   208 IF output data not synchronous with input                   210data, GO TO 200 ELSE: Insert &#34;dummy&#34; status                   212 Read DOS time          214 Read 32-bit input from interface                   216 Save 32-bit input      218 Shift message string to ID bits and read                   220 IF MESSAGE: Beacon     230  IF: Not synchronous, GO TO 200                   232  Reformat DOS time for Display                   234  IF: Test bit on in message                   236   Make BRTQC label     240  Else: Make BEACON label                   238  Shift message bits to BEACON data                   242inputs  Read BEACON data and reformat                   242  Increment count of total BEACON                   244signals IF Message: Radar      250  IF: Not synchronous, GO TO 200                   252  Reformat DOS time into program                   254memory   IF: Test bit on in message                   256    Make SRTQC label    258   Else: Make SEARCH label                   260  Shift message string to SEARCH input                   262bits and read.  Format SEARCH input bits for display                   262  Increment count of total searches                   264 IF Message: ALARM      270  IF: Not synchronous, GO TO 200                   272  Reformat DOS time into program                   274memory  Format port # for display                   276  Shift message string to ALARM input                   278bits and read  Format ALARM input bits for display                   278  Clear alarmed processor&#39;s message field                   280  Place End-of-Message bit                   280  Increment total ALARM count                   280  IF: Fatal alarm bit set                   280   GO TO 200 IF Message: SECTOR MARK                   290  IF: Not synchronous   292   IF: Sector 0 message 294   IF: North Flag set   296    Get current DOS time and                   298GO TO 308   ELSE: Set North Flag, save                   300current time as last sector 0 and GO TO 200    Save current time as last Sector                   2980 message   ELSE: GO TO 200  ELSE: Format DOS time for Display                   302and save  Shift message string to SECTOR                   304MARK input and read  IF SECTOR MARK for sector Zero                   306   Compute time difference since last                   308sector mark 0 message   IF NOT within +/- 10% of scan rate                   310    Reset synchronousity and North                   312flag    Increment NO SYNC count                   312and GO TO 200   ELSE: GO TO 314      310  ELSE: GO TO 314       306  Save current time for next Sector 0                   314check  Make Correct SRTQC label                   315  Clear unused fields and put in Port #                   316  Format SECTOR MARK input data for                   318display  Set End-of-Message Bit and increment                   319total SECTOR MARK COUNT IF Message: WEATHER    320  IF: Not syncbronous, GO TO 200                   322  Shift message string to WEATHER                   324input bits and read  Increment TOTAL WEATHER count                   326  GO TO 200Write reformatted data to disk buffer                   2243DISPLAY: data           2223  IF: Keystroke calls for exit GO TO                   153104 Go TO 200              330IF: Keystroke calls- &#34;Record&#34;                   110 Initialize variables   162 Display subdirectory memory record                   164template and enable exit key Read keyboard input for subdirectory                   166name, time/date and comments Create subdirectory under name, with                   168time/date and comments Display: Mode 3 option screen and enable                   152exit key Read from keyboard Mode 3 target code                   154or &#34;null&#34; code  IF: &#34;Null code&#34; entered GO TO 156                   154  IF: Mode 3 target code entered                   154   Display Mode 3 target data in                   155nested table and GO TO 156 Display data and error count in table                   156 CALL: interrupt subroutine                   200 ADDRESS &amp; READ: interface input data                   202 DEFINE: variables with input                   204 DISABLE: reading of interface input                   205while processing current input IF parity incorrect, correct parity                   208 IF output data not synchronous with input                   210data, GO TO 200 ELSE: Insert &#34;dummy&#34; status                   212 Read DOS time          214 Read 32-bit input from interface                   216 Save 32-bit input      218 Shift message string to ID bits and read                   220 IF MESSAGE: Beacon     230  IF: Not synchronous, GO TO 200                   232  Reformat DOS time into Display                   234format  IF: Test bit on in message                   236   Make BRTQC label     240  Else: Make BEACON label                   238  Shift message bits to BEACON data                   242inputs  Read BEACON data and reformat                   242  Increment count of total BEACON                   244signals IF Message: Radar      250  IF: Not synchronous, GO TO 200                   252  Reformat DOS time into program                   254memory   IF: Test bit on in message                   256    Make SRTQC label    258   Else: Make SEARCH label                   260  Shift message string to SEARCH input                   262bits and read.  Format SEARCH input bits for display                   262  Increment count of total searches                   264 IF Message: ALARM      270  IF: Not synchronous, GO TO 200                   272  Reformat DOS time into program                   274memory  Format port # for display                   276  Shift message string to ALARM input                   278bits and read  Format ALARM input bits for display                   278  Clear alarmed processor&#39;s message field                   280  Place End-of-Message bit                   280  Increment total ALARM count                   280  IF: Fatal alarm bit set                   280   GO TO 200 IF Message: SECTOR MARK                   290  IF: Not synchronous   292   IF: Sector 0 message 294    IF: North Flag set  296Get current DOS time and                   298GO TO 308    ELSE: Set North Flag, save                   300current time as last sector 0 and GO TO 200    Save current time as last Sector                   2980 message   ELSE: GO TO 200  ELSE: Format DOS time for Display                   302and save  Shift message string to SECTOR                   304MARK input and read  IF SECTOR MARK for sector Zero                   306   Compute time difference since last                   308sector mark 0 message   IF NOT within +/- 10% of scan rate                   310    Reset synchronousity and North                   312flag    Increment NO SYNC count                   312and GO TO 200   ELSE: GO TO 314      310  ELSE: GO TO 314       306  Save current time for next Sector 0                   314check  Make Correct SRTQC label                   315  Clear unused fields and put in Port #                   316  Format SECTOR MARK input data for                   318display  Set End-of-Message Bit and increment                   319total SECTOR MARK COUNT IF Message: WEATHER    320  IF: Not synchronous, GO TO 200                   322  Shift message string to WEATHER                   324input bits and read  Increment TOTAL WEATHER count                   326  Go TO 200 Write data to subdirectory and close                   170Write reformatted data to disk buffer                   2244DISPLAY: data           2224  IF: Keystroke calls for exit, GO TO                   167104 GO TO 200              330IF: Keystroke calls- &#34;EXIT&#34;, GO TO DOS                   331______________________________________ 
    
     A starting instruction 100 initiates the program which then calls library functions, declares and defines variables and subroutines and initiate arrays and variables 102. 
     The program then displays on the monitor the title header 104 and generates the parity table for parity checks 106. At this time the command block 108 appears on the screen listing the appropriate command keys and signals that the program awaits an appropriate command 110 through the keyboard from the user. The user then selects from the list of appropriate keyboard commands whether the data should be displayed in hexadecimal, polar graphic, non-recorded tabular or recorded tabular form. Upon choosing the appropriate keyboard command, the program proceeds to the appropriate subroutine. 
     If the user selects, using the appropriate keyboard command, to acquire general information on the program and hardware, various preprogrammed screens 120 are displayed on the monitor screen. Exit back to the title header 104 is enabled and operated by the proper keystroke 121. 
     If the user selects, using the appropriate keyboard command, the data displayed in hexadecimal form, the program proceeds to the subroutine that displays on the monitor screen the title header for hexadecimal data format 130, then to the subroutine 200 (see FIG. 4B) that addresses and reads the input data 202, defines variables with the input 204, disables the program reading of more data while current data is processed 205 and next proceeds to the subroutine that displays the data 2221, (FIG. 4A-1), and then another subroutine that scrolls the screen for the data 132. The program returns to subroutine 200 until the exit key 131 is pressed returning the program to the title header 104. 
     If the user decides to have the data displayed in polar graphical form, the program proceeds to initialize graphic programs and variables, then to the subroutine that displays on the monitor a polar graph with a sweep arm rotating across the screen. The program next proceeds to the subroutine 200, (FIG. 4B), that again addresses and reads the input data 202, defines variables with the input 204, disables the program reading of more data while current data is processed 205, checks the parity 208, checks the synchronousity of the input data with the display of data 210, inserts a &#34;dummy&#34; status at the beginning of each scan 212, reads the DOS time 214, puts the time in the correct format of the program 216, rechecks synchronousity 218, and decodes 220 the data by shifting the pointer to the appropriate data location on the binary string input and reading the information encoded at that location on the binary string. The program then reformats the binary information 242, 262 and 278, (FIG. 4C), and 318, (FIG. 4E), writes the data to the buffer disk 2242, (FIG. 4A-1), and displays the data 2222 in polar graphical form. The program then returns to subroutine 200 to repeat the process until the exit key 141 is pressed returning the program to the title header 104. 
     If the user selects the option of having the data and error count displayed in tabular form, without the option of recording the data to disk, the program proceeds to a subroutine displaying a command block 152 that gives the user the option of having inset into a table of data and error count, tracking data for a particular target identified by a unique code. If the user does not desire this option, the user enters a predefined null code at 154 and the program proceeds to a subroutine 156 that displays on the monitor an appropriate table for the data and error count without a target track information table inset; if the user chooses this option the user enters the unique code at 154 assigned to the target and the program proceeds to subroutine 156 that also displays on the monitor an appropriate table for the data and error count but which now requires a nested target track information table with target track data 155 to be displayed. The program next proceeds to the subroutine 200, (FIG. 4B), that addresses and reads input data 202, defines variables with the input 204, disables the program reading of more data while current data is processed 205, checks the parity 208, checks the synchronousity of the input data with the display of data 210, inserts a &#34;dummy&#34; status at the beginning of each scan 212, reads the DOS time 214, puts the time in the correct format of the program 216, rechecks synchronousity 218, and decodes the data at 220 by shifting the pointer to the appropriate data location on the binary string input and reading the information encoded at that location on the binary string. The program then reformats the binary information 242, 262 and 278, (FIG. 4C) and 318, (FIG. 4E) writes the data to a buffer disk 2243, and displays the data 2223 in tabular form. The program then returns to subroutine 200 to repeat the process until the exit key is pressed 153 returning the program to the title header 104. 
     Should the user desire the option of having the data count and error count displayed in tabular form with the further option of recording the data to a document subroutine, the program proceeds first to a subroutine that initializes the variables 160, then a subroutine that displays an appropriate command block 164 for appropriately identifying the document subroutine, inputting its date and time and allowing for input of comments 166. The program next proceeds to open the new document subroutine 168, give it its given name, writes into it the date and time given plus any comments given and prepare it to receive the incoming data. The program then proceeds to a subroutine 152 that displays on the monitor screen an option for the user of receiving tracking data on the monitor screen for a particular target identified by a unique code. If the user does not desire this option, the user enters a predefined null code at 154 and the program proceeds to a subroutine 156 that displays on the monitor an appropriate table for the data and error count without a target track information table inset; if the user chooses this option the user enters the unique code at 154 assigned to the target and the program proceeds to subroutine 156 that also displays on the monitor an appropriate table for the data and error count but which now requires a nested target track information table with target track data 155 to be displayed. The program next proceeds to the subroutine 200, (FIG. 4B), to address and read the input data 202, defines variables with the input 204, disables the program reading of more data while current data is processed 205, checks the parity 208, checks the synchronousity of the input data with the data displayed 210, inserts a &#34;dummy&#34; status at the beginning of each scan 212, reads the DOS time 214, puts the time in the correct format of the program 216, rechecks synchronousity 218, and decodes at 220 the data by shifting the pointer to the appropriate data location on the binary string input and reading the information encoded at that location on the binary string. The program then reformats the binary information 242, 262 and 278, (FIG. 4C), and 318, (FIG. 4E). The program then writes the data at 170 to the appropriate document subroutine and to the buffer disk 2244, data 2224 being presented on the monitor in tabular form. Finally, the program will continue back to subroutine 200 to repeat the process until the exit key 167 is pressed returning the program to the title header 104. 
     An agent or agents of the Noise Abatement Division of the airport authority concerned may administer the program, although, of course, there may be other users. Normally, the data is displayed on the monitor in polar graphic form, showing all the airborne aircrafts&#39; position in the geographical area of concern on a map of the area with a designated unique code by each aircraft&#39;s position mark. Should the agent receive notice of high noise level for a particular area of the geographical area of concern, the agent then detects the aircraft suspected of causing the high noise. If more than one aircraft is in the area of high noise level, the agent, through appropriate keyboard commands, would preview the flight data of the differing aircraft to distinguish, through its altitude and exact position, the offending aircraft; The agent then, through the appropriate keyboard commands, records the offending aircraft&#39;s flight plan to an appropriate document subdirectory. Further, if the agent desires information on aspects of the program or the hardware necessary to deliver the program, that agent inputs through the keyboard the necessary command or commands to display on the monitor the appropriate &#34;help&#34; screen or screens. Additionally, if that agent has any question toward the integrity of the system, he or she inputs through the keyboard the necessary command or commands to display on the monitor the incoming data in hexadecimal form and the agent then gauges the integrity of the system from observing the form of the incoming data. 
     It will thus be noted that air traffic control system data may be integrated with noise abatement data, as well as other data not comprehended by the air traffic control system data. Further, referring to FIG. 1, incoming data can be provided from a source D, which via a communications link E, provides data to interface board 4. Incidentally, in this respect, it will be appreciated that interface board 4, for this purpose, must be capable of integrating data from at least two different sources and presenting the data in a coordinated fashion to computer system 8. For an example of other data that may be provided, a commercial aircraft may determine its location through the &#34;NAVSTAR&#34; Global Positioning System (GPS) by inboard instrumentation, which is instantaneously transmitted to sensor D at the destination or intermediate air traffic control center which, in turn, is transmitted to an air controller via the computer system 8. Further, either with such information or independently thereof, the aircraft&#39;s onboard computers and navigation systems may calculate the most efficient flight plan for time and/or fuel consumption, which information is transmitted to the appropriate sensor D and via communications link E and interface board 4 to computer system 8 which has also received other traffic information via tap connectors 17 and 21, (FIG. 2A), cable 1, repeater 2, and interface board 4, (FIG. 1). The data is then inspected and interpreted by the air traffic controller who judges the suitability of the route. Given affirmance, the aircraft proceeds on the most efficient route available, saving time and money without loss of safety. To the extent that this can be integrated stepwise into the present national system of air traffic control, the system as a whole becomes more efficient. Thus, the integration of onboard equipment with air traffic control has the potential of saving the airline industry billions of dollars by reducing fuel use, shortening delays and improving operational efficiencies. 
     Although the present invention has been described in detail by reference to certain preferred versions thereof, other versions are possible. Therefore, the spirit and scope of the appended claims should not be limited to the description of the preferred versions contained herein.