Source: http://www.google.com.hk/patents/USRE35590?hl=zh-TW
Timestamp: 2013-05-26 01:17:42
Document Index: 554251988

Matched Legal Cases: ['art1', 'art2', 'ART1', 'ART1', 'ART2', 'ART1', 'ART1', 'ART2', 'ART1', 'ART1', 'ART2', 'ART1', 'ART1', 'ART2']

�M�Q USRE35590 - Solid state event recorder - Google �M�Q�j�M �Ϥ� �a�� Play YouTube �s�D Gmail ���ݵw�� ��h »�i���M�Q�j�M | �������� | �n�J�i���M�Q�j�M�M�QA solid state event recorder having particular application to railroad locomotives has a plurality of interface modules to allow the collection of desired data over a period of time. Radio downloading of the data provided by a telemetry transmitter to wayside receivers is the primary way of downloading...http://www.google.com.hk/patents/USRE35590?utm_source=gb-gplus-share�M�Q USRE35590 - Solid state event recorder���}��USRE35590 E�X���������v�ӽЮѽs��08/147,835�o�G���1997�~8��19���ӽФ��1993�~11��3�� �u���v���1989�~6��15����L���}�M�Q��US5065321�o��HAngel P. BezosEmilio A. FernandezJr. Joseph I. Field��M�Q�v�HPulse Electronics, Inc.Westinghouse Air Brake CompanyChase Manhattan Bank, ThePulse Electronics, Inc. A Delaware Corporation ���M�Q������455/456.1360/6702/176702/187340/870.41��ڱM�Q������G06F17/40B60L3/12G01D9/00 �X�@����G01D9/005Y02T90/16B60L3/12G06F17/40 �ڬw������G06F 17/40G01D 9/00SB60L 3/12�ѦҤ��m�M�Q�ޥ� (19)�D�M�Q�ޥ� (3)�Q�H�U�M�Q�ޥ� (19)�~���s�����M�Q�ӼЧ� ���M�Q�ӼЧ��M�Q����T�� �ڬw�M�Q��Solid state event recorderUS RE35590 E�K�n A solid state event recorder having particular application to railroad locomotives has a plurality of interface modules to allow the collection of desired data over a period of time. Radio downloading of the data provided by a telemetry transmitter to wayside receivers is the primary way of downloading data. Alternative data downloading are provided by a removable memory module, a portable wireless data extractor and a laptop computer. The removable memory module is provided with its own backup battery power supply but normally derives its power from an inductive coupling to the solid state recorder. Data is read into the removable memory module from the solid state recorder via an inductive coupling, and data is read out of the removable memory module to the telemetry transmitter via another inductive coupling. Both the portable wireless data extractor and the laptop computer are used for maintenance purposes. The solid state recorder can be configured in a variety of ways and connected together as master and slave. For example, one recorder, acting as a master and functioning as the primary of operational recorder, can be connected to a second recorder, acting as a slave time synchronized with the first recorder. This second recorder can serve as a maintenance recorder for collecting long term data and trouble shooting a particular locomotive.
We claim: .[. 1. A solid state event recorder for mounting in and monitoring events on a vehicle comprising: a plurality of event inputs for receiving analog and digital data to be recorded; interface means connected to said event inputs for buffering digital inputs and converting analog inputs to digital values; first microprocessor means connected to said interface means for formatting data provided by said interface means; memory means coupled to said first microprocessor means for receiving and recording formatted data, said memory means including an array of solid state memory devices, and second microprocessor means in communication with said first microprocessor means for receiving formatted data and recording the formatted data in said array of solid state memory devices; a telemetry transmitter for transmitting data recorded in said memory means; telemetry control means interposed between said first microprocessor means and said memory means and between said memory means and said telemetry transmitter, said first microprocessor means controlling said telemetry control means to prevent transmitting data while formatted data is being recorded in said memory means; and a plurality of telemetry receivers located along a path of motion of said vehicle, each of said telemetry receivers receiving transmitted data as said vehicle passes by..]..[.2. The solid state event recorder as recited in claim 1 further comprising a portable wireless receiver for positioning proximate said telemetry transmitter to download data recorded in said memory means..]..[.3. The solid state event recorder as recited in claim 1 further comprising a portable computer for connection to said solid state recorder to download data recorded in said memory means..]..[.4. The solid state event recorder as recited in claim 1 wherein said memory means is removable and includes batteries for powering said array of solid state memory devices and said second microprocessor means when said memory means is removed from said solid state event recorder and further comprising inductive interface means between said solid state recorder and said memory means for transferring power to said memory means from said solid state event recorder and for transferring data between said memory means and said solid state event recorder..]..[.5. The solid state event recorder as recited in claim 4 wherein said inductive interface means comprises: first, second and third ferrite core pairs, each core pair having a primary winding and a secondary winding wound on a respective one of said cores, said cores of each pair being positioned for alignment with one another when said removable memory means is inserted in said solid state recorder; oscillator means connected to the primary winding of said first core pair for inductively coupling alternating current power to the secondary winding of said first core pair; rectifier means connected to the secondary winding of said second core pair for producing a rectified direct current voltage; first phase splitter and driver means connected to the primary winding of said second core pair for coupling data signals from said second microprocessor means to the secondary winding of said second core pair; and second phase splitter and river means connected to the primary winding of said third core pair for coupling data signals from said memory means to
the secondary winding of said third core pair..]..[.6. The solid state event recorder as recited in claim 1 further comprising inductive interface means between said solid state recorder and said memory means for transferring power to said memory means for said solid state event recorder and for transferring data between said memory means and said solid state event recorder..]..[.7. The solid state event recorder as recited in claim 6 wherein said inductive interface means comprises: first, second and third ferrite core pairs, each core pair having a primary winding and a secondary winding wound on a respective one of said cores, said cores of each pair being positioned for alignment with one another when said removable memory means is inserted in said solid state recorder; oscillator means connected to the primary winding of said first core pair for inductively coupling alternating current power to the secondary winding of said first core pair; rectifier means connected to the secondary winding of said second core pair for producing a rectified direct current voltage; first phase splitter and driver means connected to the primary winding of said second core pair for coupling data signals from said second microprocessor means to the second winding of said second core pair; and second phase splitter and driver means connected to the primary winding of said third core pair for coupling data signals from said memory means to the secondary winding of said third core pair..]..[.8. The solid state event recorder as recited in claim 1 wherein said recorder is installed on a locomotive of a railroad train and connected to monitor and record events on said locomotive, said recorder being configured as a primary recorder, said plurality of event inputs including brake pipe air pressure, traction motor current, and an axle drive signal proportional to locomotive speed..]..[.9. The solid state event recorder as recited in claim 8 further including engineman monitoring means connected to said recorder..]..[.10. The solid state event recorder as recited in claim 8 wherein said event inputs further include a receiver for receiving transmission from an end of train telemetry transmitter, said receiver providing data signals proportional to brake pipe pressure at the end of the train..]..[.11. The solid state event recorder as recited in claim 10 wherein said receiver further provides data signals marking a beginning and an end of a measured distance, said first microprocessor means being programmed to compute and store wheel calibration data based on said data signals and said axle drive signal, said solid state recorder further comprising speed indicator output means for providing a calibrated signal output as a function of said wheel calibration data..]..[.12. The solid state event recorder recited in claim 8 further comprising a second solid state event recorder connected as a slave to said primary recorder and time synchronized therewith, said second recorder being used to record data for maintenance and troubleshooting said locomotive and having a plurality of event inputs including oil and water temperature, main generator current and voltage, and air filter flow..]..[.13. The solid state event recorder recited in claim 1 wherein said memory means includes a time of day clock, the data recorded in said memory means including time
of day..].14. A solid state event recorder .Iadd.and reproduction system, .Iaddend.comprising: a plurality of event inputs for receiving analog and digital data to be recorded; .Iadd.an .Iaddend.interface .[.means.]. connected to said event inputs for buffering digital inputs and converting analog inputs to digital values; .Iadd.a .Iaddend.microprocessor .[.means.]. connected to said interface .[.means.]. for formatting data provided by said interface .[.means.].; .Iadd.a .Iaddend.memory .[.means.]. coupled to said microprocessor .[.means.]. for receiving and recording formatted data.[., said memory means including.]. .Iadd.; .Iaddend. a time of day clock.Iadd., operatively coupled to said memory, for measuring a time of said event inputs and for time indexing said formatted data.Iaddend.; playback means.Iadd., operatively coupled to said memory, for .Iaddend.interfacing with said memory .[.means.]. and playing back data recorded in said memory .[.means, said playback means including.]..Iadd.; and .Iaddend. a real time clock .[.and.]. .Iadd.operatively coupled to said playback means, said playback means .Iaddend.computing a time error as a difference between said time of day clock and said real time clock, said
.Iadd.formatted .Iaddend.data being indexed by said time error. 15. A solid state recorder .Iadd.and reproduction system, .Iaddend.comprising: a plurality of event inputs for receiving analog and digital data to be recorded; .Iadd.an .Iaddend.interface .[.means.]. connected to said event inputs for buffering digital inputs and converting analog inputs to digital values; .Iadd.a .Iaddend.microprocessor .[.means.]. connected to said interface .[.means.]. for formatting data provided by said interface .[.means.].; .Iadd.a .Iaddend.memory .[.means.]. coupled to said microprocessor .[.means.]. for receiving and recording formatted data.[., said memory means including.]..Iadd.; .Iaddend. a time of day clock.Iadd., operatively coupled to said memory, for measuring a time of said event inputs and for time indexing said formatted data.Iaddend.; downloading means.Iadd., operatively coupled to said memory, .Iaddend.for interfacing with said memory .[.means.]. and downloading data recorded in said memory .[.means, said downloading means including.]..Iadd.; and .Iaddend. a real time clock .Iadd.operatively coupled to said downloading means, said downloading means .Iaddend..[.and.]. computing a time error as a difference between said time of day clock and said real time clock, said
.Iadd.formatted .Iaddend.data being indexed by said time error. 16. A solid state event recorder .Iadd.and reproduction system, .Iaddend.for .[.mounting in and.]. monitoring events in a vehicle comprising: a plurality of event inputs for receiving analog and digital data representing events in said vehicle to be recorded; .Iadd.an .Iaddend.interface .[.means.]. connected to said event inputs for buffering digital inputs and converting analog inputs to digital values; .Iadd.a .Iaddend.microprocessor .[.means.]. connected to said interface .[.means.]. for formatting data provided by said interface .[.means.].; .Iadd.a .Iaddend.solid state memory .[.means.]. coupled to said microprocessor .[.means.]. for receiving and recording formatted data; .[.and.]. downloading means.Iadd., operatively coupled to said solid state memory, .Iaddend.for downloading data from said solid state memory .[.means, wherein said solid state memory includes.]..Iadd.; .Iaddend. a time of day clock .Iadd.operatively coupled to said downloading means and to said solid state memory.Iaddend., the data recorded in said solid state memory including the time of day.[., and said downloading means includes.]..Iadd.; and .Iaddend. a real time clock .[.and computes.]. .Iadd.operatively coupled to said downloading means, said downloading means computing .Iaddend.a time error as a difference between said time of day clock and said real time clock,
indexed by said time error. 20. In a solid state event recorder for .[.mounting in and.]. monitoring events in a vehicle, said solid state event recorder comprising a plurality of event inputs for receiving analog and digital data to be recorded, .Iadd.an .Iaddend.interface .[.means.]. connected to said event inputs for buffering digital inputs and converting analog inputs to digital values, .Iadd.a .Iaddend.first microprocessor .[.means.]. connected to said interface .[.means.]. for formatting data provided by said interface .[.means.]., and .Iadd.a .Iaddend.removable solid state memory .[.means.]. coupled to said first microprocessor .[.means.]. for receiving and recording formatted data, said solid state memory .[.means.]. being physically removable for playback of recorded data separate from said solid state .Iadd.event .Iaddend.recorder, the improvement comprising: an array of solid state memory devices and a second microprocessor .[.means.]. in said removable .Iadd.solid state memory .[.means.]., said second microprocessor .[.means.]. receiving data from said first microprocessor .[.means.]. and recording said data in said array of solid state memory devices, said data being directly transmitted between said first and second .[.microprocessor means.]. .Iadd.microprocessors .Iaddend.as digital signals; and .Iadd.an .Iaddend.inductive interface .[.means.]. between said removable solid state memory .[.means.]. and said first microprocessor .[.means.]. for transferring data at baseband between said first microprocessor .[.means.]. and said second microprocessor .[.means.]. and for coupling power from said solid state event recorder to said removable solid state
said opening. 23. The improvement in the solid state event recorder recited in claim 21 further comprising: .Iadd.an .Iaddend.oscillator .[.means.]. connected to the primary winding of said first core pair for inductively coupling alternating current power to the secondary winding of said first core pair; .Iadd.a .Iaddend.rectifier .[.means.]. connected to the secondary winding of said second core pair for producing a rectified direct current voltage; .Iadd.a .Iaddend.first phase splitter and driver .[.means.]. .Iadd.circuit .Iaddend.connected to the primary winding of said second core pair for coupling data signals from said first microprocessor .[.means.]. to the secondary winding of said second core pair; and .Iadd.a .Iaddend.second phase splitter and driver .[.means.]. .Iadd.circuit .Iaddend.connected to the primary winding of said third core pair for coupling data signals from said removable .Iadd.solid state .Iaddend.memory .[.means.]. to the secondary winding of said third core
pair. 24. In a solid state event recorder .[.of the type mounted in and.]. .Iadd.for .Iaddend.monitoring events in a vehicle, said solid state event recorder comprising a plurality of event inputs for receiving analog and digital data to be recorded, .Iadd.an .Iaddend.interface .[.means.]. connected to said event inputs for buffering digital inputs and converting analog inputs to digital values, .Iadd.a .Iaddend.first microprocessor .[.means.]. connected to said interface .[.means.]. for formatting data provided by said interface .[.means.]., .[.said.]. .Iadd.a .Iaddend.solid state memory .[.means.]. coupled to said first microprocessor .[.means.]. for receiving and recording formatted data, said solid state memory .[.means.]. being electrically isolated from said solid state .Iadd.event .Iaddend.recorder, the improvement comprising: an array of solid state memory devices and a second microprocessor .[.means.]. in said .Iadd.solid state .Iaddend.memory .[.means.]., said second microprocessor .[.means.]. receiving data from said first microprocessor .[.means.]. and recording said data in said array of solid state memory devices, said data being directly transmitted between said first and second .[.microprocessor means.]. .Iadd.microprocessors .Iaddend.as digital signals; and .Iadd.an .Iaddend.inductive interface .[.means.]. between said .Iadd.solid state .Iaddend.memory .[.means.]. and said first microprocessor .[.means.]. for transferring data between said first microprocessor .[.means.]. and said second microprocessor .[.means.]. and for coupling power from said solid state event recorder to said .Iadd.solid state
one another. 26. The improvement in the solid state event recorder recited in claim 25 further comprising: .Iadd.an .Iaddend.oscillator .[.means.]. connected to the primary winding of said first core pair for inductively coupling alternating current power to the secondary winding of said first core pair; .Iadd.a .Iaddend.rectifier .[.means.]. connected to the secondary winding of said second core pair for producing a rectified direct current voltage; .Iadd.a .Iaddend.first phase splitter and driver .[.means.]. .Iadd.circuit .Iaddend.connected to the primary winding of said second core pair for coupling data signals from said first microprocessor .[.means.]. to the secondary winding of said second core pair; and .Iadd.a .Iaddend.second phase splitter and driver .[.means.]. .Iadd.circuit .Iaddend.connected to the primary winding of said third core pair for coupling data signals from said .Iadd.solid state .Iaddend.memory
receiver. .Iaddend..Iadd.28. A solid state event recorder and reproduction system for monitoring events in a vehicle comprising: a plurality of event inputs for receiving analog and digital data representing events in said vehicle to be recorded; an interface connected to said event inputs for buffering digital inputs and converting analog inputs to digital values; a microprocessor connected to said interface for formatting data provided by said interface; a solid state memory coupled to said microprocessor for receiving and recording formatted data; timekeeping means, operatively coupled to said solid state memory, for establishing an elapsed time of said events in said vehicle corresponding to said formatted data, said solid state memory additionally storing elapsed time data of said events in said vehicle corresponding to said formatted data; downloading means for downloading data from said solid state memory, said downloading means including at least one receiver along a route of said vehicle for receiving said formatted data from said solid state memory; and means, operatively coupled to said solid state memory and to said downloading means, for correlating said elapsed time of said events in said vehicle corresponding to said formatted data, to a real time of day, said correlating means including means for providing said real time of day, wherein said correlating means includes a realtime clock and means for computing said real time of day as a difference between said elapsed time and said realtime clock, said formatted data being indexed by said real
said route of said vehicle. .Iaddend..Iadd.30. A solid state event recorder and reproduction system for monitoring events in a vehicle comprising: a plurality of event inputs for receiving analog and digital data representing events in said vehicle to be recorded; an interface connected to said event inputs for buffering digital inputs and converting analog inputs to digital values; a microprocessor connected to said interface for formatting data provided by said interface; a solid state memory coupled to said microprocessor for receiving and recording formatted data; timekeeping means, operatively coupled to said solid state memory, for establishing an elapsed time of said events in said vehicle corresponding to said formatted data, said solid state memory additionally storing elapsed time data of said events in said vehicle corresponding to said formatted data; downloading means for downloading data from said solid state memory, said downloading means including at least one receiver along a route of said vehicle for receiving said formatted data from said solid state memory; and means, operatively coupled to said solid state memory and to said downloading means, for correlating said elapsed time of said events in said vehicle corresponding to said formatted data, to a real time of day, said correlating means including means for providing said real time of day, wherein said timekeeping means is operatively coupled to said microprocessor for establishing said elapsed time of said events over a real time of day, wherein said timekeeping means includes a time of day clock for generating a time of day, wherein said downloading means includes means for computing the real time of the day as a difference between said elapsed time and said time of day.
______________________________________     int init.sub.-- events( void );       return         OK.FAILED______________________________________
______________________________________unsigned char get.sub.-- fast.sub.-- event( unsigned    char ev.sub.-- num );    ev.sub.-- num        EV1 . . . EV23    return       HIGH (&amp;gt;0) . LOW (0)______________________________________
______________________________________Unsigned char get.sub.-- normal.sub.-- event( unsigned char  ev.sub.-- num ):  ev.sub.-- num     EV1 . . . EV23  return    88 HIGH (&amp;gt;0).LOW (0)______________________________________
______________________________________    int event.sub.-- change( void );      return        YES.NO______________________________________
______________________________________  int enable.sub.-- fast.sub.-- event( unsigned char    ev.sub.-- num );    event.sub.-- num      EV1 EV2 EV3 EV5 EV8 EV12 etc.    return      OK.FAILED______________________________________
______________________________________int enable.sub.-- normal.sub.-- event( unsigned char   ev.sub.-- num ):   event.sub.-- num     EV1 EV2 EV3 EV5 EV8 EV12 etc.   return     OK.FAILED______________________________________
______________________________________int disable.sub.-- event( unsigned char   ev.sub.-- num );   list     EV1 EV2 EV3 EV5 EV8 EV12 etc.   return     OK.FAILED______________________________________
______________________________________  void output.sub.-- signal( int out.sub.-- num . int    state );    ev.sub.-- num       GP.sub.-- OUT    state      ACTIVE.INACTIVE______________________________________
______________________________________   int event.sub.-- recorder.sub.-- type( void );     return       PIN.sub.-- FOR.sub.-- PIN       SLAVE       MASTER______________________________________
______________________________________   int init.sub.-- fm.sub.-- analog.sub.-- inputs( int     recorder.sub.-- type );     recorder.sub.-- type       PIN.sub.-- FOR.sub.-- PIN       SLAVE       MASTER     return       OK.FAILED______________________________________
______________________________________    int get.sub.-- pwm.sub.-- cycles( void );      return        0-352 Hz______________________________________
______________________________________   void current.sub.-- int.sub.-- input( void ):______________________________________
______________________________________  int get.sub.-- cycles( int ev.sub.-- num );     ev.sub.-- num        CEV11,CEV12,CEV19,CEV20,CEV21,        CEV23     return        0-366 Hz______________________________________
______________________________________   int get.sub.-- atd.sub.-- value( int av.sub.-- num );       av.sub.-- num          AV1       return          0-255 full range______________________________________
______________________________________int.totalize.sub.-- cycles( int ev.sub.-- num );  ev.sub.-- num    CEV11,CEV12,CEV19,CEV20,CEV21,    CEV23  return    OK.FAILED______________________________________
______________________________________long get.sub.-- totalized.sub.-- cycles( int ev.sub.-- num );    ev.sub.-- num      CEV11,CEV12,CEV19,CEV20,CEV21,      CEV23    return      0-2 32 cycles______________________________________
______________________________________void init.sub.-- counter( unsigned int address,unsigned char mode );    address      address of counter    mode      MODE0 . . . MODE5______________________________________
______________________________________void latch.sub.-- counters( unsigned incontrol.sub.-- address, unsigned charcounter.sub.-- mask );control.sub.-- address   address of control registercounter.sub.-- mask   COUNTER0.sub.-- MASK . . . COUNTER2.sub.-- MASK______________________________________
______________________________________  in get.sub.-- counts( unsigned in address );     address       address of counter     return       counter value 0-65535______________________________________
______________________________________  void put.sub.-- counts( unsigned int address ,  unsigned in value );     address       address of counter     value       0-65535______________________________________
______________________________________  unsigned char get.sub.-- counter.sub.-- status(  unsigned int address );     address       address of counter     return       status byte          OUT.sub.-- PIN          NULL.sub.-- COUNT          etc.______________________________________
______________________________________     int .sub.-- init.sub.-- duart1( void );        return           OK.FAILED______________________________________
______________________________________     int.sub.-- init.sub.-- duart2( void );        return           OK,FAILED______________________________________
______________________________________     void init.sub.-- fifos( void );______________________________________
______________________________________     int getc( int port.sub.-- num );        port.sub.-- num          INTERNAL          DUART1.sub.-- A          DUART1.sub.-- B          DUART2.sub.-- A        return          character (0-255)          NO.sub.-- CHAR.sub.-- AVAIL______________________________________
______________________________________     int putc( int port.sub.-- num, int c );        port.sub.-- num          INTERNAL          DUART1.sub.-- A          DUART1.sub.-- B          DUART2.sub.-- A        c          character to send (0-255)        return          OK,FAILED______________________________________
______________________________________     int getch( int port.sub.-- num, int time );        port.sub.-- num          INTERNAL          DUART1.sub.-- A          DUART1.sub.-- B          DUART2.sub.-- A        time          time in 50 ms increments        return          character.FAILED______________________________________
______________________________________  int setup( int port.sub.-- num , int baud , int  parbits );     port.sub.-- num        INTERNAL        DUART1.sub.-- A        DUART1.sub.-- B        DUART2.sub.--1     baud        B300,B600,B1200,B2400,B4800,        B9600,B19200     parbits        PBN8 (No parity, 8 bits)        PBE8 (Even parity, 8 bits)        PB08 (Odd parity, 8 bits)        HDLC (HDLC mode)     return        OK,FAILED______________________________________
______________________________________   void comm.sub.-- int.sub.-- handler( void );______________________________________
______________________________________  void int.sub.-- comm.sub.-- int.sub.-- handler( void______________________________________  );
______________________________________     void init.sub.-- nonvol( void );______________________________________
______________________________________  int nonvol.sub.-- write( int address, int data);    address      0x00 - 0x3F    data      0x0000 - 0xFFFF    returns      OK.FAILED  int novol.sub.-- read( int address );    address      0x00 - 0x3F    returns      0x0000 - 0xFFFF______________________________________
______________________________________void init.sub.-- encoder( void );void encode( int recorder.sub.-- type );recorder.sub.-- type   PIN.sub.-- FOR.sub.-- PIN   SLAVE   MASTERvoid init.sub.-- record( void );void add.sub.-- to.sub.-- record( int num.sub.-- bits, intdata );num.sub.-- bits   number of bits for this datadata   data wordvoid crc.sub.-- record( void );int record.sub.-- size( void );return   size of record in bytesvoid write.sub.-- record( int num.sub.-- bytes );num.sub.-- bytes   size of record in bytesThe laptop manager 282 performs the following function.void init-laptop.sub.-- trans.sub.-- mgr( void );void laptop.sub.-- manager( int port.sub.-- num );port.sub.-- num   1,2,3,4______________________________________
______________________________________  void xmodem.sub.-- dump( int port.sub.-- num );    port.sub.-- num      1,2,3,4______________________________________
______________________________________void param.sub.-- update.sub.-- mgr( int port.sub.-- num );   port.sub.-- num     1,2,3,4______________________________________
______________________________________struct frameunsigned char command;unsigned char count;unsigned char buff[255];}int rmm.sub.-- write(RMM.sub.-- FRAME.sub.-- TYPE *buffer );*buffer   pointer to buffer to writereturn   error statusint rmm.sub.-- dump.sub.-- data( void );return   RMM error code______________________________________
______________________________________  void init.sub.-- speed.sub.-- output.sub.-- mgr( void );  void speed.sub.-- out( int speed.sub.-- cycles );    speed.sub.-- cycles      0 - 352 cycles per second______________________________________
______________________________________  int check.sub.-- stacks( int function.sub.-- code );    function.sub.-- code      entry address of function    return      OK,fault.sub.-- code  int check.sub.-- pc( int function.sub.-- code );    function.sub.-- code      entry address of function    return      OK,fault.sub.-- code  void safe.sub.-- dptr( void );  int check.sub.-- flags( void );    return      OK,fault.sub.-- code  void.sub.-- fault.sub.-- handler( int fault.sub.-- code );  void diagnostic.sub.-- mgr( void );  void .sub.-- watchdog.sub.-- cycle( void );  void .sub.-- fault.sub.-- lamp.sub.-- cycle( void______________________________________  );
______________________________________   void init.sub.-- slave.sub.-- trans.sub.-- mgr( void );   void slave.sub.-- trans.sub.-- mgr( void );______________________________________
______________________________________void init.sub.-- mgr( void ):______________________________________
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