/* $NetBSD: mbg_gps166.h,v 1.1.1.1 2000/03/29 12:38:48 simonb Exp $ */ /* * /src/NTP/ntp-4/include/mbg_gps166.h,v 4.1 1998/06/12 15:07:30 kardel RELEASE_19990228_A * * Created: Sun Jul 20 09:20:50 1997 * * Copyright (C) 1997, 1998 by Frank Kardel */ #ifndef MBG_GPS166_H #define MBG_GPS166_H /***************************************************************************/ /* */ /* File: GPSSERIO.H 4.1 */ /* */ /* Project: Common C Library */ /* */ /* Compiler: Borland C++ */ /* */ /* Author: M. Burnicki, Meinberg Funkuhren */ /* */ /* */ /* Description: */ /* This file defines structures and codes to be used to access GPS166 */ /* via its serial interface COM0. COM0 should be set to a high baud */ /* rate, default is 19200. */ /* */ /* Standard GPS166 serial operation is to send a time string that is */ /* compatible with Meinberg UA31 or PZF535 DCF77 radio remote clocks. */ /* That string can be transmitted automatically once per second, once */ /* per minute or on request per ASCII '?'. */ /* */ /* Parameter setup or parameter readout works using blocks of binary */ /* data which have to be isolated from the standard string. A block of */ /* data starts with a SOH code (ASCII Start Of Header, 0x01) followed */ /* by a message header with constant length and a data portion with */ /* variable length. The first field (cmd) of the message header holds */ /* the command code rsp. the type of data to be transmitted. The next */ /* field (len) gives the number of data bytes that are transmitted */ /* after the header. This number ranges from 0 to sizeof( MSG_DATA ). */ /* The third field (data_csum) holds a checksum of all data bytes and */ /* the last field of the header finally holds the checksum of the. */ /* header. */ /* */ /***************************************************************************/ /* the control codes defined below are to be or'ed with a command/type code */ #define GPS_REQACK 0x8000 /* to GPS166: request acknowledge */ #define GPS_ACK 0x4000 /* from GPS166: acknowledge a command */ #define GPS_NACK 0x2000 /* from GPS166: error receiving command */ #define GPS_CTRL_MSK 0xF000 /* masks control code from command */ /* The codes below specify commands/types of data to be supplied to GPS166: */ /* GPS166 auto-message to host */ /* þ host request, GPS166 response */ /* þ þ host download to GPS166 */ /* þ þ þ */ enum { /* þ þ þ */ /* system data */ GPS_AUTO_ON = 0x000, /* þ þ þ X þ enable auto-messages from GPS166 */ GPS_AUTO_OFF, /* þ þ þ X þ disable auto-messages from GPS166 */ GPS_SW_REV, /* þ þ X þ þ request software revision */ GPS_STAT, /* þ þ X þ þ request status of buffered variables */ GPS_TIME, /* þ X þ þ X þ current time or capture or init board time */ GPS_POS_XYZ, /* þ þ X þ X þ current position in ECEF coords */ GPS_POS_LLA, /* þ þ X þ X þ current position in geographic coords */ GPS_TZDL, /* þ þ X þ X þ time zone / daylight saving */ GPS_PORT_PARM, /* þ þ X þ X þ parameters of the serial ports */ GPS_SYNTH, /* þ þ X þ X þ synthesizer's frequency and phase */ GPS_ANT_INFO, /* þ X þ X þ þ time diff after antenna disconnect */ GPS_UCAP, /* þ X þ X þ þ user capture */ /* GPS data */ GPS_CFGH = 0x100, /* þ þ X þ X þ SVs' configuration and health codes */ GPS_ALM, /* þ þ X þ X þ one SV's almanac */ GPS_EPH, /* þ þ X þ X þ one SV's ephemeris */ GPS_UTC, /* þ þ X þ X þ UTC correction parameters */ GPS_IONO, /* þ þ X þ X þ ionospheric correction parameters */ GPS_ASCII_MSG /* þ þ X þ þ the GPS ASCII message */ }; /* * modelled after GPSDEFS.H Revision 1.5 */ /***************************************************************************/ /* */ /* File: GPSDEFS.H 4.1 */ /* */ /* Project: Common C Library */ /* */ /* Compiler: Borland C++ */ /* */ /* Author: M. Burnicki, Meinberg Funkuhren */ /* */ /* */ /* Description: */ /* General definitions to be used with GPS166 */ /* GPS166 Rev. 1.23 or above */ /* */ /* Modifications: see file GPSLIB.TXT */ /* */ /***************************************************************************/ #define _GPSDEFS_H /* the type of various checksums */ #ifndef _CSUM_DEFINED typedef unsigned short CSUM; # define _CSUM_DEFINED #endif /* the message header */ typedef struct { unsigned short gps_cmd; unsigned short gps_len; unsigned short gps_data_csum; unsigned short gps_hdr_csum; } GPS_MSG_HDR; /* a struct used to hold the software revision information */ typedef struct { unsigned short code; /* e.g. 0x0120 means rev. 1.20 */ unsigned char name[17]; /* used to identify customized versions */ } SW_REV; /* GPS ASCII message */ typedef struct { CSUM csum; /* checksum of the remaining bytes */ short valid; /* flag data are valid */ char s[23]; /* 22 chars GPS ASCII message plus trailing zero */ } ASCII_MSG; #define MIN_SVNO 1 /* min. SV number */ #define MAX_SVNO 32 /* max. SV number */ #define N_SVNO ( MAX_SVNO - MIN_SVNO + 1) /* number of possibly active SVs */ typedef short SVNO; /* the number of a SV */ typedef unsigned short HEALTH; /* a SV's health code */ typedef unsigned short CFG; /* a SV's configuration code */ typedef unsigned short IOD; /* Issue-Of-Data code */ /* Date and time referred to the linear time scale defined by GPS. */ /* GPS time is defined by the number of weeks since midnight from */ /* January 5, 1980 to January 6, 1980 plus the number of seconds of */ /* the current week plus fractions of a second. GPS time differs from */ /* UTC because UTC is corrected with leap seconds while GPS time scale */ /* is continuous. */ typedef struct { unsigned short wn; /* the week number since GPS has been installed */ unsigned long sec; /* the second of that week */ unsigned long tick; /* fractions of a second; scale: 1E-7 */ } T_GPS; /* Local date and time computed from GPS time. The current number */ /* of leap seconds have to be added to get UTC from GPS time. */ /* Additional corrections could have been made according to the */ /* time zone/daylight saving parameters (TZDL, see below) defined */ /* by the user. The status field can be checked to see which corrections */ /* have been applied. */ #ifndef _TM_DEFINED typedef struct { short year; /* 0..9999 */ char month; /* 1..12 */ char mday; /* 1..31 */ short yday; /* 1..366 */ char wday; /* 0..6 == Sun..Sat */ char hour; /* 0..23 */ char minute; /* 0..59 */ char second; /* 0..59 */ long frac; /* fractions of a second, scale 1E-7 */ long offs_from_utc; /* local time's offset from UTC */ unsigned short status; /* flags */ } TM; /* status flags used with conversion from GPS time to local time */ # define TM_UTC 0x01 /* UTC correction has been made */ # define TM_LOCAL 0x02 /* UTC has been converted to local time */ # define TM_DL_ANN 0x04 /* state of daylight saving is going to change */ # define TM_DL_ENB 0x08 /* daylight saving is enabled */ # define TM_LS_ANN 0x10 /* leap second will be inserted */ # define TM_LS_ENB 0x20 /* current second is leap second */ # define _TM_DEFINED #endif /* the status flags below are defined starting with rev. 1.32 */ #define TM_ANT_DISCONN 0x1000 /* antenna currently disconnected */ #define TM_SYN_FLAG 0x2000 /* TIME_SYN output is low */ #define TM_NO_SYNC 0x4000 /* not sync'ed after reset */ #define TM_NO_POS 0x8000 /* position not computed after reset, */ /* LOCK LED off */ /* a struct used to transmit information on date and time */ typedef struct { short channel; /* -1: the current time; 0, 1: capture 0, 1 */ T_GPS t; /* time in GPS format */ TM tm; /* that time converted to local time */ } TTM; /* Two types of variables used to store a position. Type XYZ is */ /* used with a position in earth centered, earth fixed (ECEF) */ /* coordinates whereas type LLA holds such a position converted */ /* to geographic coordinates as defined by WGS84 (World Geodetic */ /* System from 1984). */ #ifndef _XYZ_DEFINED /* sequence and number of components of a cartesian position */ enum { XP, YP, ZP, N_XYZ }; /* a type of array holding a cartesian position */ typedef l_fp XYZ[N_XYZ]; /* values are in [m] */ # define _XYZ_DEFINED #endif #ifndef _LLA_DEFINED /* sequence and number of components of a geographic position */ enum { LAT, LON, ALT, N_LLA }; /* latitude, longitude, altitude */ /* a type of array holding a geographic position */ typedef l_fp LLA[N_LLA]; /* lon, lat in [rad], alt in [m] */ # define _LLA_DEFINED #endif /* Synthesizer parameters. Synthesizer frequency is expressed as a */ /* four digit decimal number (freq) to be multiplied by 0.1 Hz and an */ /* base 10 exponent (range). If the effective frequency is less than */ /* 10 kHz its phase is synchronized corresponding to the variable phase. */ /* Phase may be in a range from -360° to +360° with a resolution of 0.1°, */ /* so the resulting numbers to be stored are in a range of -3600 to +3600. */ /* Example: */ /* Assume the value of freq is 2345 (decimal) and the value of phase is 900. */ /* If range == 0 the effective frequency is 234.5 Hz with a phase of +90°. */ /* If range == 1 the synthesizer will generate a 2345 Hz output frequency */ /* and so on. */ /* Limitations: */ /* If freq == 0 the synthesizer is disabled. If range == 0 the least */ /* significant digit of freq is limited to 0, 3, 5 or 6. The resulting */ /* frequency is shown in the examples below: */ /* freq == 1230 --> 123.0 Hz */ /* freq == 1233 --> 123 1/3 Hz (real 1/3 Hz, NOT 123.3 Hz) */ /* freq == 1235 --> 123.5 Hz */ /* freq == 1236 --> 123 2/3 Hz (real 2/3 Hz, NOT 123.6 Hz) */ /* If range == MAX_RANGE the value of freq must not exceed 1200, so the */ /* output frequency is limited to 12 MHz. */ /* Phase will be ignored if the resulting frequency is greater or equal */ /* to 10 kHz. */ #define MAX_SYNTH_FREQ 1200 /* if range == MAX_SYNTH_RANGE */ #define MIN_SYNTH_RANGE 0 #define MAX_SYNTH_RANGE 5 #define MAX_SYNTH_PHASE 3600 typedef struct { short freq; /* four digits used; scale: 0.1; e.g. 1234 -> 123.4 Hz */ short range; /* scale factor for freq; 0..MAX_SYNTH_RANGE */ short phase; /* -MAX_SYNTH_PHASE..+MAX_SYNTH_PHASE; >0 -> pulses later */ } SYNTH; /* Time zone/daylight saving parameters. */ /* the name of a time zone, 5 characters plus trailing zero */ typedef char TZ_NAME[6]; typedef struct { long offs; /* offset from UTC to local time [sec] */ long offs_dl; /* additional offset if daylight saving enabled [sec] */ TM tm_on; /* date/time when daylight saving starts */ TM tm_off; /* date/time when daylight saving ends */ TZ_NAME name[2]; /* names without and with daylight saving enabled */ } TZDL; /* The constant below is defined beginning with software rev. 1.29. */ /* If the year in tzdl.tmon and tzdl.tm_off is or'ed with that constant, */ /* the receiver automatically generates daylight saving year by year. */ /* See GPSLIB.TXT for more information. */ #define DL_AUTO_FLAG 0x8000 /* Example: */ /* for automatic daylight saving enable/disable in Central Europe, */ /* the variables are to be set as shown below: */ /* offs = 3600L one hour from UTC */ /* offs_dl = 3600L one additional hour if daylight saving enabled */ /* tm_on = first Sunday from March 25, 02:00:00h ( year |= DL_AUTO_FLAG ) */ /* tm_off = first Sunday from Sept 24, 03:00:00h ( year |= DL_AUTO_FLAG ) */ /* name[0] == "MEZ " name if daylight saving not enabled */ /* name[1] == "MESZ " name if daylight saving is enabled */ /* the structure below was defined in rev. 1.31. It reflects the status */ /* of the antenna, the times of last disconnect/reconnect and the boards */ /* clock offset after the phase of disconnection. */ typedef struct { short status; /* current status of antenna */ TM tm_disconn; /* time of antenna disconnect */ TM tm_reconn; /* time of antenna reconnect */ long delta_t; /* clock offset at reconnect time, units: TICKS_PER_SEC */ } ANT_INFO; /* the status field may be set to one of the values below: */ enum { ANT_INVALID, /* struct not set yet because ant. has not been disconn. */ ANT_DISCONN, /* ant. now disconn., tm_reconn and delta_t not set */ ANT_RECONN /* ant. has been disconn. and reconn., all fields valid */ }; /* Summary of configuration and health data of all SVs. */ typedef struct { CSUM csum; /* checksum of the remaining bytes */ short valid; /* flag data are valid */ T_GPS tot_51; /* time of transmission, page 51 */ T_GPS tot_63; /* time of transmission, page 63 */ T_GPS t0a; /* complete reference time almanac */ CFG cfg[N_SVNO]; /* SV configuration from page 63 */ HEALTH health[N_SVNO]; /* SV health from pages 51, 63 */ } CFGH; /* UTC correction parameters */ typedef struct { CSUM csum; /* checksum of the remaining bytes */ short valid; /* flag data are valid */ T_GPS t0t; /* Reference Time UTC Parameters [sec] */ l_fp A0; /* ± Clock Correction Coefficient 0 [sec] */ l_fp A1; /* ± Clock Correction Coefficient 1 [sec/sec] */ ushort WNlsf; /* week number of nearest leap second */ short DNt; /* the day number at the end of which LS is inserted */ char delta_tls; /* */ char delta_tlsf; /* */ } UTC; /* a struct used to hold the settings of a serial port */ #ifndef _COM_PARM_DEFINED typedef long BAUD_RATE; /* indices used to identify a parameter in the framing string */ enum { F_DBITS, F_PRTY, F_STBITS }; /* types of handshake */ enum { HS_NONE, HS_XONXOFF, HS_RTSCTS }; typedef struct { BAUD_RATE baud_rate; /* e.g. 19200L */ char framing[4]; /* e.g. "8N1" */ short handshake; /* a numeric value, only HS_NONE supported yet */ } COM_PARM; #define _COM_PARM_DEFINED #endif /* the codes below define what has to comes out of the serial ports */ enum { STR_ON_REQ, STR_PER_SEC, STR_PER_MIN, N_STR_MODE_0, /* COM0 and COM1 */ STR_UCAP = N_STR_MODE_0, STR_UCAP_REQ, N_STR_MODE_1 /* COM1 only */ }; #define N_COM 2 /* the number of serial ports */ /* the structure used to store the modes of both serial ports */ typedef struct { COM_PARM com[N_COM]; /* COM0 and COM1 settings */ u_char mode[N_COM]; /* COM0 and COM1 output mode */ } PORT_PARM; /* Ephemeris parameters of one specific SV. Needed to compute the position */ /* of a satellite at a given time with high precision. Valid for an */ /* interval of 4 to 6 hours from start of transmission. */ typedef struct { CSUM csum; /* checksum of the remaining bytes */ short valid; /* flag data are valid */ HEALTH health; /* health indication of transmitting SV [---] */ IOD IODC; /* Issue Of Data, Clock */ IOD IODE2; /* Issue of Data, Ephemeris (Subframe 2) */ IOD IODE3; /* Issue of Data, Ephemeris (Subframe 3) */ T_GPS tt; /* time of transmission */ T_GPS t0c; /* Reference Time Clock [---] */ T_GPS t0e; /* Reference Time Ephemeris [---] */ l_fp sqrt_A; /* Square Root of semi-major Axis [sqrt(m)] */ l_fp e; /* Eccentricity [---] */ l_fp M0; /* ± Mean Anomaly at Ref. Time [rad] */ l_fp omega; /* ± Argument of Perigee [rad] */ l_fp OMEGA0; /* ± Longit. of Asc. Node of orbit plane [rad] */ l_fp OMEGADOT; /* ± Rate of Right Ascension [rad/sec] */ l_fp deltan; /* ± Mean Motion Diff. from computed value [rad/sec] */ l_fp i0; /* ± Inclination Angle [rad] */ l_fp idot; /* ± Rate of Inclination Angle [rad/sec] */ l_fp crc; /* ± Cosine Corr. Term to Orbit Radius [m] */ l_fp crs; /* ± Sine Corr. Term to Orbit Radius [m] */ l_fp cuc; /* ± Cosine Corr. Term to Arg. of Latitude [rad] */ l_fp cus; /* ± Sine Corr. Term to Arg. of Latitude [rad] */ l_fp cic; /* ± Cosine Corr. Term to Inclination Angle [rad] */ l_fp cis; /* ± Sine Corr. Term to Inclination Angle [rad] */ l_fp af0; /* ± Clock Correction Coefficient 0 [sec] */ l_fp af1; /* ± Clock Correction Coefficient 1 [sec/sec] */ l_fp af2; /* ± Clock Correction Coefficient 2 [sec/sec²] */ l_fp tgd; /* ± estimated group delay differential [sec] */ u_short URA; /* predicted User Range Accuracy */ u_char L2code; /* code on L2 channel [---] */ u_char L2flag; /* L2 P data flag [---] */ } EPH; /* Almanac parameters of one specific SV. A reduced precision set of */ /* parameters used to check if a satellite is in view at a given time. */ /* Valid for an interval of more than 7 days from start of transmission. */ typedef struct { CSUM csum; /* checksum of the remaining bytes */ short valid; /* flag data are valid */ HEALTH health; /* [---] */ T_GPS t0a; /* Reference Time Almanac [sec] */ l_fp sqrt_A; /* Square Root of semi-major Axis [sqrt(m)] */ l_fp e; /* Eccentricity [---] */ l_fp M0; /* ± Mean Anomaly at Ref. Time [rad] */ l_fp omega; /* ± Argument of Perigee [rad] */ l_fp OMEGA0; /* ± Longit. of Asc. Node of orbit plane [rad] */ l_fp OMEGADOT; /* ± Rate of Right Ascension [rad/sec] */ l_fp deltai; /* ± [rad] */ l_fp af0; /* ± Clock Correction Coefficient 0 [sec] */ l_fp af1; /* ± Clock Correction Coefficient 1 [sec/sec] */ } ALM; /* ionospheric correction parameters */ typedef struct { CSUM csum; /* checksum of the remaining bytes */ short valid; /* flag data are valid */ l_fp alpha_0; /* Ionosph. Corr. Coeff. Alpha 0 [sec] */ l_fp alpha_1; /* Ionosph. Corr. Coeff. Alpha 1 [sec/deg] */ l_fp alpha_2; /* Ionosph. Corr. Coeff. Alpha 2 [sec/deg^2] */ l_fp alpha_3; /* Ionosph. Corr. Coeff. Alpha 3 [sec/deg^3] */ l_fp beta_0; /* Ionosph. Corr. Coeff. Beta 0 [sec] */ l_fp beta_1; /* Ionosph. Corr. Coeff. Beta 1 [sec/deg] */ l_fp beta_2; /* Ionosph. Corr. Coeff. Beta 2 [sec/deg^2] */ l_fp beta_3; /* Ionosph. Corr. Coeff. Beta 3 [sec/deg^3] */ } IONO; void mbg_tm_str P((unsigned char **, TM *)); void mbg_tgps_str P((unsigned char **, T_GPS *)); void get_mbg_header P((unsigned char **, GPS_MSG_HDR *)); void put_mbg_header P((unsigned char **, GPS_MSG_HDR *)); void get_mbg_sw_rev P((unsigned char **, SW_REV *)); void get_mbg_ascii_msg P((unsigned char **, ASCII_MSG *)); void get_mbg_svno P((unsigned char **, SVNO *)); void get_mbg_health P((unsigned char **, HEALTH *)); void get_mbg_cfg P((unsigned char **, CFG *)); void get_mbg_tgps P((unsigned char **, T_GPS *)); void get_mbg_tm P((unsigned char **, TM *)); void get_mbg_ttm P((unsigned char **, TTM *)); void get_mbg_synth P((unsigned char **, SYNTH *)); void get_mbg_tzdl P((unsigned char **, TZDL *)); void get_mbg_antinfo P((unsigned char **, ANT_INFO *)); void get_mbg_cfgh P((unsigned char **, CFGH *)); void get_mbg_utc P((unsigned char **, UTC *)); void get_mbg_lla P((unsigned char **, LLA)); void get_mbg_xyz P((unsigned char **, XYZ)); void get_mbg_portparam P((unsigned char **, PORT_PARM *)); void get_mbg_eph P((unsigned char **, EPH *)); void get_mbg_alm P((unsigned char **, ALM *)); void get_mbg_iono P((unsigned char **, IONO *)); unsigned long mbg_csum P((unsigned char *, unsigned int)); #endif /* * mbg_gps166.h,v * Revision 4.1 1998/06/12 15:07:30 kardel * fixed prototyping * * Revision 4.0 1998/04/10 19:50:42 kardel * Start 4.0 release version numbering * * Revision 1.1 1998/04/10 19:27:34 kardel * initial NTP VERSION 4 integration of PARSE with GPS166 binary support * * Revision 1.1 1997/10/06 20:55:38 kardel * new parse structure * */