/* * Hamlib Kenwood backend - TS2000 description * Copyright (c) 2000-2011 by Stephane Fillod * * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include "kenwood.h" #define TS2000_ALL_MODES (RIG_MODE_AM|RIG_MODE_CW|RIG_MODE_SSB|RIG_MODE_FM|RIG_MODE_RTTY) #define TS2000_OTHER_TX_MODES (RIG_MODE_CW|RIG_MODE_SSB|RIG_MODE_FM|RIG_MODE_RTTY) #define TS2000_AM_TX_MODES RIG_MODE_AM #define TS2000_FUNC_ALL (RIG_FUNC_TONE|RIG_FUNC_TSQL|RIG_FUNC_BC|RIG_FUNC_NB|RIG_FUNC_NR|RIG_FUNC_ANF|RIG_FUNC_COMP) #define TS2000_LEVEL_ALL (RIG_LEVEL_PREAMP|RIG_LEVEL_ATT|RIG_LEVEL_VOX|RIG_LEVEL_AF|RIG_LEVEL_RF|RIG_LEVEL_SQL|RIG_LEVEL_CWPITCH|RIG_LEVEL_RFPOWER|RIG_LEVEL_MICGAIN|RIG_LEVEL_KEYSPD|RIG_LEVEL_COMP|RIG_LEVEL_AGC|RIG_LEVEL_BKINDL|RIG_LEVEL_METER|RIG_LEVEL_VOXGAIN|RIG_LEVEL_ANTIVOX|RIG_LEVEL_RAWSTR|RIG_LEVEL_STRENGTH) #define TS2000_MAINVFO (RIG_VFO_A|RIG_VFO_B) #define TS2000_SUBVFO (RIG_VFO_C) #define TS2000_VFO_OP (RIG_OP_UP|RIG_OP_DOWN|RIG_OP_BAND_UP|RIG_OP_BAND_DOWN) #define TS2000_SCAN_OP (RIG_SCAN_VFO) #define TS2000_ANTS (RIG_ANT_1|RIG_ANT_2) #define TS2000_STR_CAL {9, {\ {0x00, -54},\ {0x03, -48},\ {0x06, -36},\ {0x09, -24},\ {0x0C, -12},\ {0x0F, 0},\ {0x14, 20},\ {0x19, 40},\ {0x1E, 60}}\ } /* prototypes */ static int ts2000_get_level(RIG *rig, vfo_t vfo, setting_t level, value_t *val); static int ts2000_get_channel(RIG *rig, channel_t *chan); static int ts2000_set_channel(RIG *rig, const channel_t *chan); /* * 38 CTCSS sub-audible tones + 1750 tone */ const tone_t ts2000_ctcss_list[] = { 670, 719, 744, 770, 797, 825, 854, 885, 915, 948, 974, 1000, 1035, 1072, 1109, 1148, 1188, 1230, 1273, 1318, 1365, 1413, 1462, 1514, 1567, 1622, 1679, 1738, 1799, 1862, 1928, 2035, 2107, 2181, 2257, 2336, 2418, 2503, 17500, 0, }; /* * 103 available DCS codes */ static const tone_t ts2000_dcs_list[] = { 23, 25, 26, 31, 32, 36, 43, 47, 51, 53, 54, 65, 71, 72, 73, 74, 114, 115, 116, 122, 125, 131, 132, 134, 143, 145, 152, 155, 156, 162, 165, 172, 174, 205, 212, 223, 225, 226, 243, 244, 245, 246, 251, 252, 255, 261, 263, 265, 266, 271, 274, 306, 311, 315, 325, 331, 332, 343, 346, 351, 356, 364, 365, 371, 411, 412, 413, 423, 431, 432, 445, 446, 452, 454, 455, 462, 464, 465, 466, 503, 506, 516, 523, 526, 532, 546, 565, 606, 612, 624, 627, 631, 632, 654, 662, 664, 703, 712, 723, 731, 732, 734, 743, 754, 0, }; static struct kenwood_priv_caps ts2000_priv_caps = { .cmdtrm = EOM_KEN, }; /* memory capabilities */ #define TS2000_MEM_CAP { \ .freq = 1, \ .mode = 1, \ .tx_freq=1, \ .tx_mode=1, \ .split=1, \ .rptr_shift=1, \ .rptr_offs=1, \ .funcs=RIG_FUNC_REV|RIG_FUNC_TONE|RIG_FUNC_TSQL,\ .tuning_step=1, \ .ctcss_tone=1, \ .ctcss_sql=1, \ .dcs_code=1, \ .dcs_sql=1, \ .scan_group=1, \ .flags=1, \ .channel_desc=1 \ } /* * ts2000 rig capabilities. * * part of infos comes from http://www.kenwood.net/ */ const struct rig_caps ts2000_caps = { .rig_model = RIG_MODEL_TS2000, .model_name = "TS-2000", .mfg_name = "Kenwood", .version = BACKEND_VER ".4", .copyright = "LGPL", .status = RIG_STATUS_BETA, .rig_type = RIG_TYPE_TRANSCEIVER, .ptt_type = RIG_PTT_RIG, .dcd_type = RIG_DCD_RIG, .port_type = RIG_PORT_SERIAL, .serial_rate_min = 1200, .serial_rate_max = 57600, .serial_data_bits = 8, .serial_stop_bits = 1, .serial_parity = RIG_PARITY_NONE, .serial_handshake = RIG_HANDSHAKE_NONE, .write_delay = 0, .post_write_delay = 50, /* ms */ .timeout = 200, .retry = 3, .has_get_func = TS2000_FUNC_ALL, .has_set_func = TS2000_FUNC_ALL, .has_get_level = TS2000_LEVEL_ALL, .has_set_level = RIG_LEVEL_SET(TS2000_LEVEL_ALL), .has_get_parm = RIG_PARM_NONE, .has_set_parm = RIG_PARM_NONE, /* FIXME: parms */ .level_gran = {}, /* FIXME: granularity */ .parm_gran = {}, .vfo_ops = TS2000_VFO_OP, .scan_ops = TS2000_SCAN_OP, .ctcss_list = ts2000_ctcss_list, .dcs_list = ts2000_dcs_list, .preamp = { 20, RIG_DBLST_END, }, /* FIXME: real preamp? */ .attenuator = { 20, RIG_DBLST_END, }, .max_rit = kHz(20), .max_xit = kHz(20), .max_ifshift = kHz(1), .targetable_vfo = RIG_TARGETABLE_FREQ, .transceive = RIG_TRN_RIG, .bank_qty = 0, .chan_desc_sz = 7, .chan_list = { { 0, 299, RIG_MTYPE_MEM, TS2000_MEM_CAP }, RIG_CHAN_END, }, .rx_range_list1 = { {kHz(300),MHz(60),TS2000_ALL_MODES,-1,-1,TS2000_MAINVFO,TS2000_ANTS}, {MHz(144),MHz(146),TS2000_ALL_MODES,-1,-1,TS2000_MAINVFO}, {MHz(430),MHz(440),TS2000_ALL_MODES,-1,-1,TS2000_MAINVFO}, {MHz(144),MHz(146),TS2000_ALL_MODES,-1,-1,TS2000_SUBVFO}, {MHz(430),MHz(440),TS2000_ALL_MODES,-1,-1,TS2000_SUBVFO}, RIG_FRNG_END, }, /* rx range */ .tx_range_list1 = { {kHz(1830),kHz(1850),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {kHz(1830),kHz(1850),TS2000_AM_TX_MODES,2000,25000,TS2000_MAINVFO,TS2000_ANTS}, {kHz(3500),kHz(3800),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {kHz(3500),kHz(3800),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(7),kHz(7100),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(7),kHz(7100),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(10.1),MHz(10.15),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(10.1),MHz(10.15),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(14),kHz(14350),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(14),kHz(14350),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {kHz(18068),kHz(18168),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {kHz(18068),kHz(18168),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(21),kHz(21450),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(21),kHz(21450),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {kHz(24890),kHz(24990),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {kHz(24890),kHz(24990),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(28),kHz(29700),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(28),kHz(29700),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(50),MHz(50.2),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(50),MHz(50.2),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(144),MHz(146),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO}, {MHz(144),MHz(146),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO}, {MHz(430),MHz(440),TS2000_OTHER_TX_MODES,W(5),W(50),TS2000_MAINVFO}, {MHz(430),MHz(440),TS2000_AM_TX_MODES,W(5),W(12.5),TS2000_MAINVFO}, RIG_FRNG_END, }, /* tx range */ .rx_range_list2 = { {kHz(300),MHz(60),TS2000_ALL_MODES,-1,-1,TS2000_MAINVFO,TS2000_ANTS}, {MHz(142),MHz(152),TS2000_ALL_MODES,-1,-1,TS2000_MAINVFO}, {MHz(420),MHz(450),TS2000_ALL_MODES,-1,-1,TS2000_MAINVFO}, {MHz(118),MHz(174),TS2000_ALL_MODES,-1,-1,TS2000_SUBVFO}, {MHz(220),MHz(512),TS2000_ALL_MODES,-1,-1,TS2000_SUBVFO}, RIG_FRNG_END, }, /* rx range */ .tx_range_list2 = { {kHz(1800),MHz(2),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {kHz(1800),MHz(2),TS2000_AM_TX_MODES,2000,25000,TS2000_MAINVFO,TS2000_ANTS}, {kHz(3500),MHz(4),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {kHz(3500),MHz(4),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(7),kHz(7300),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(7),kHz(7300),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(10.1),MHz(10.15),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(10.1),MHz(10.15),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(14),kHz(14350),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(14),kHz(14350),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {kHz(18068),kHz(18168),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {kHz(18068),kHz(18168),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(21),kHz(21450),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(21),kHz(21450),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {kHz(24890),kHz(24990),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {kHz(24890),kHz(24990),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(28),kHz(29700),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(28),kHz(29700),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(50),MHz(54),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO,TS2000_ANTS}, {MHz(50),MHz(54),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO,TS2000_ANTS}, {MHz(144),MHz(148),TS2000_OTHER_TX_MODES,W(5),W(100),TS2000_MAINVFO}, {MHz(144),MHz(148),TS2000_AM_TX_MODES,W(5),W(25),TS2000_MAINVFO}, {MHz(430),MHz(450),TS2000_OTHER_TX_MODES,W(5),W(50),TS2000_MAINVFO}, {MHz(430),MHz(450),TS2000_AM_TX_MODES,W(5),W(12.5),TS2000_MAINVFO}, RIG_FRNG_END, }, /* tx range */ .tuning_steps = { {RIG_MODE_SSB|RIG_MODE_CW|RIG_MODE_RTTY,1}, {TS2000_ALL_MODES,10}, {TS2000_ALL_MODES,100}, {TS2000_ALL_MODES,kHz(1)}, {TS2000_ALL_MODES,kHz(2.5)}, {TS2000_ALL_MODES,kHz(5)}, {RIG_MODE_AM|RIG_MODE_FM,kHz(6.25)}, {TS2000_ALL_MODES,kHz(10)}, {RIG_MODE_AM|RIG_MODE_FM,kHz(12.5)}, {RIG_MODE_AM|RIG_MODE_FM,kHz(12.5)}, {RIG_MODE_AM|RIG_MODE_FM,kHz(15)}, {RIG_MODE_AM|RIG_MODE_FM,kHz(20)}, {RIG_MODE_AM|RIG_MODE_FM,kHz(25)}, {RIG_MODE_AM|RIG_MODE_FM,kHz(30)}, {RIG_MODE_AM|RIG_MODE_FM,kHz(50)}, {RIG_MODE_AM|RIG_MODE_FM,kHz(100)}, {TS2000_ALL_MODES,MHz(1)}, {TS2000_ALL_MODES,0}, /* any tuning step */ RIG_TS_END, }, /* mode/filter list, remember: order matters! */ .filters = { {RIG_MODE_SSB, kHz(2.2)}, {RIG_MODE_CW, Hz(600)}, {RIG_MODE_RTTY, Hz(1500)}, {RIG_MODE_AM, kHz(6)}, {RIG_MODE_FM|RIG_MODE_AM, kHz(12)}, RIG_FLT_END, }, .str_cal = TS2000_STR_CAL, .priv = (void *)&ts2000_priv_caps, .rig_init = kenwood_init, .rig_cleanup = kenwood_cleanup, .set_freq = kenwood_set_freq, .get_freq = kenwood_get_freq, .set_rit = kenwood_set_rit, .get_rit = kenwood_get_rit, .set_xit = kenwood_set_xit, .get_xit = kenwood_get_xit, .set_mode = kenwood_set_mode, .get_mode = kenwood_get_mode, .set_vfo = kenwood_set_vfo, .get_vfo = kenwood_get_vfo_if, .set_ctcss_tone = kenwood_set_ctcss_tone_tn, .get_ctcss_tone = kenwood_get_ctcss_tone, .set_ctcss_sql = kenwood_set_ctcss_sql, .get_ctcss_sql = kenwood_get_ctcss_sql, .get_ptt = kenwood_get_ptt, .set_ptt = kenwood_set_ptt, .get_dcd = kenwood_get_dcd, .set_func = kenwood_set_func, .get_func = kenwood_get_func, .set_level = kenwood_set_level, .get_level = ts2000_get_level, .set_ant = kenwood_set_ant, .get_ant = kenwood_get_ant, .send_morse = kenwood_send_morse, .vfo_op = kenwood_vfo_op, .scan = kenwood_scan, .set_mem = kenwood_set_mem, .get_mem = kenwood_get_mem, .get_channel = ts2000_get_channel, .set_channel = ts2000_set_channel, .set_trn = kenwood_set_trn, .get_trn = kenwood_get_trn, .set_powerstat = kenwood_set_powerstat, .get_powerstat = kenwood_get_powerstat, .get_info = kenwood_get_info, .reset = kenwood_reset, }; /* * Function definitions below */ /* * ts2000_get_channel * Read command format: M|R|P1|P2|P3|P3|;| * P1: 0 - RX frequency, 1 - TX frequency Memory channel 290 ~ 299: P1=0 (start frequency), P1=1 (end frequency) P2 - bank number allowed values: , 0, 1 or 2 P3 - channel number 00-99 Returned value: M | R |P1 |P2 |P3 |P3 |P4 |P4 |P4 |P4 | P4 |P4 |P4 |P4 |P4 |P4 |P4 |P5 |P6 |P7 | P8 |P8 |P9 |P9 |P10|P10|P10|P11|P12|P13| P13|P13|P13|P13|P13|P13|P13|P13|P14|P14| P15|P16|P16|P16|P16|P16|P16|P16|P16| ; | P1 - P3 described above P4: Frequency in Hz (11-digit). P5: Mode. 1: LSB, 2: USB, 3: CW, 4: FM, 5: AM, 6: FSK, 7: CR-R, 8: Reserved, 9: FSK-R P6: Lockout status. 0: Lockout OFF, 1: Lockout ON. P7: 0: OFF, 1: TONE, 2: CTCSS, 3: DCS. P8: Tone Number. Allowed values 01 (67Hz) - 38 (250.3Hz) P9: CTCSS tone number. Allowed values 01 (67Hz) - 38 (250.3Hz) P10: DCS code. Allowed values 000 (023 DCS code) to 103 (754 DCS code). P11: REVERSE status. P12: SHIFT status. 0: Simplex, 1: +, 2: –, 3: = (All E-types) P13: Offset frequency in Hz (9-digit). Allowed values 000000000 - 059950000 in steps of 50000. Unused digits must be 0. P14: Step size. Allowed values: for SSB, CW, FSK mode: 00 - 03 00: 1 kHz, 01: 2.5 kHz, 02: 5 kHz, 03: 10 kHz for AM, FM mode: 00 - 09 00: 5 kHz, 01: 6.25 kHz, 02: 10 kHz, 03: 12.5 kHz, 04: 15 kHz, 05: 20 kHz, 06: 25 kHz, 07: 30 kHz, 08: 50 kHz, 09: 100 kHz P15: Memory Group number (0 ~ 9). P16: Memory name. A maximum of 8 characters. */ int ts2000_get_channel(RIG *rig, channel_t *chan) { rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!rig || !chan || chan->vfo != RIG_VFO_MEM) return -RIG_EINVAL; int err; char buf[52]; size_t buf_size = 52; char cmd[8]; struct kenwood_priv_caps *caps = kenwood_caps(rig); /* put channel num in the command string */ sprintf(cmd, "MR0%03d;", chan->channel_num); err = kenwood_transaction(rig, cmd, strlen(cmd), buf, &buf_size ); if (err != RIG_OK) return err; memset(chan, 0x00, sizeof(channel_t)); chan->vfo = RIG_VFO_MEM; /* parse from right to left */ /* XXX based on the available documentation, there is no command * to read out the filters of a given memory channel. The rig, however, * stores this information. */ /* Replace ';' with '\0' */ buf[ buf_size-1 ] = '\0'; /* First check if a name is assigned. Name is returned at positions 41-48 (counting from 0) */ if( buf_size > 41 ){ // rig_debug(RIG_DEBUG_VERBOSE, "Copying channel description: %s\n", &buf[ 41 ] ); strcpy( chan->channel_desc, &buf[ 41 ] ); } /* Memory group no */ chan->scan_group = buf[ 40 ] - '0'; /* Fileds 38-39 contain tuning step as a number 00 - 09. Tuning step depends on this number and the mode, just save it for now */ buf[ 40 ] = '\0'; int tmp; tmp = atoi( &buf[ 38] ); /* Offset frequency */ buf[ 38 ] = '\0'; chan->rptr_offs = atoi( &buf[ 29 ] ); /* Shift type WARNING: '=' shift type not programmed */ if( buf[ 28 ] == '1' ){ chan->rptr_shift = RIG_RPT_SHIFT_PLUS; }else{ if( buf[ 28 ] == '2' ){ chan->rptr_shift = RIG_RPT_SHIFT_MINUS; }else{ chan->rptr_shift = RIG_RPT_SHIFT_NONE; } } /* Reverse status */ if( buf[27] == '1' ){ chan->funcs |= RIG_FUNC_REV; } /* Check for tone, CTCSS and DCS */ /* DCS code first */ if( buf[ 19 ] == '3' ){ if( rig->caps->dcs_list ){ buf[ 27 ] = '\0'; chan->dcs_code = rig->caps->dcs_list[ atoi( &buf[ 24 ] ) ]; chan->dcs_sql = chan->dcs_code; chan->ctcss_tone = 0; chan->ctcss_sql = 0; } }else{ chan->dcs_code = 0; chan->dcs_sql = 0; /* CTCSS code Caution, CTCSS codes, unlike DCS codes, are numbered from 1! */ buf[ 24 ] = '\0'; if( buf[ 19 ] == '2' ){ chan->funcs |= RIG_FUNC_TSQL; if (rig->caps->ctcss_list){ chan->ctcss_sql = rig->caps->ctcss_list[ atoi( &buf[22] )-1 ]; chan->ctcss_tone = 0; } }else{ chan->ctcss_sql = 0; /* CTCSS tone */ if( buf[ 19 ] == '1' ){ chan->funcs |= RIG_FUNC_TONE; buf[ 22 ] = '\0'; if (rig->caps->ctcss_list) chan->ctcss_tone = rig->caps->ctcss_list[ atoi( &buf[20] )-1 ]; }else{ chan->ctcss_tone = 0; } } } /* memory lockout */ if (buf[18] == '1') chan->flags |= RIG_CHFLAG_SKIP; /* mode */ chan->mode = kenwood2rmode(buf[17] - '0', caps->mode_table); /* Now we have the mode, let's finish the tuning step */ if( (chan->mode == RIG_MODE_AM) || (chan->mode == RIG_MODE_FM) ){ switch (tmp){ case 0: chan->tuning_step = kHz(5); break; case 1: chan->tuning_step = kHz(6.25); break; case 2: chan->tuning_step = kHz(10); break; case 3: chan->tuning_step = kHz(12.5); break; case 4: chan->tuning_step = kHz(15); break; case 5: chan->tuning_step = kHz(20); break; case 6: chan->tuning_step = kHz(25); break; case 7: chan->tuning_step = kHz(30); break; case 8: chan->tuning_step = kHz(50); break; case 9: chan->tuning_step = kHz(100); break; default: chan->tuning_step = 0; } }else{ switch (tmp){ case 0: chan->tuning_step = kHz(1); break; case 1: chan->tuning_step = kHz(2.5); break; case 2: chan->tuning_step = kHz(5); break; case 3: chan->tuning_step = kHz(10); break; default: chan->tuning_step = 0; } } /* Frequency */ buf[17] = '\0'; chan->freq = atoi(&buf[6]); if (chan->freq == RIG_FREQ_NONE) return -RIG_ENAVAIL; buf[6] = '\0'; chan->channel_num = atoi(&buf[3]); /* Check split freq */ cmd[2] = '1'; buf_size = 52; err = kenwood_transaction(rig, cmd, strlen(cmd), buf, &buf_size ); if (err != RIG_OK) return err; chan->tx_mode = kenwood2rmode(buf[17] - '0', caps->mode_table); buf[17] = '\0'; chan->tx_freq = atoi(&buf[6]); if (chan->freq == chan->tx_freq) { chan->tx_freq = RIG_FREQ_NONE; chan->tx_mode = RIG_MODE_NONE; chan->split = RIG_SPLIT_OFF; } else chan->split = RIG_SPLIT_ON; return RIG_OK; } int ts2000_set_channel(RIG *rig, const channel_t *chan) { rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!rig || !chan) return -RIG_EINVAL; char buf[55]; char mode, tx_mode = 0; int err; int tone = 0; struct kenwood_priv_caps *caps = kenwood_caps(rig); mode = rmode2kenwood(chan->mode, caps->mode_table); if (mode < 0 ) { rig_debug(RIG_DEBUG_ERR, "%s: unsupported mode '%s'\n", __func__, rig_strrmode(chan->mode)); return -RIG_EINVAL; } if (chan->split == RIG_SPLIT_ON) { tx_mode = rmode2kenwood(chan->tx_mode, caps->mode_table); if (tx_mode < 0 ) { rig_debug(RIG_DEBUG_ERR, "%s: unsupported mode '%s'\n", __func__, rig_strrmode(chan->tx_mode)); return -RIG_EINVAL; } } /* find tone */ char sqltype = '0'; if (chan->ctcss_tone) { for (; rig->caps->ctcss_list[tone] != 0; tone++) { if (chan->ctcss_tone == rig->caps->ctcss_list[tone]) break; } if (chan->ctcss_tone != rig->caps->ctcss_list[tone]) tone = -1; else sqltype = '1'; }else{ tone = -1; /* -1 because we will add 1 when outputing; this is necessary as CTCSS codes are numbered from 1 */ } /* find CTCSS code */ short code = 0; if (chan->ctcss_sql) { for (; rig->caps->ctcss_list[code] != 0; code++) { if (chan->ctcss_sql == rig->caps->ctcss_list[code]) break; } if (chan->ctcss_sql != rig->caps->ctcss_list[code]) code = -1; else sqltype = '2'; }else{ code = -1; } /* find DCS code */ short dcscode = 0; if (chan->dcs_code) { for (; rig->caps->dcs_list[dcscode] != 0; dcscode++) { if (chan->dcs_code == rig->caps->dcs_list[dcscode]) break; } if (chan->dcs_code != rig->caps->dcs_list[dcscode]) dcscode = 0; else sqltype = '3'; }else{ dcscode = 0; } char shift = '0'; if( chan->rptr_shift == RIG_RPT_SHIFT_PLUS ){ shift = '1'; } if( chan->rptr_shift == RIG_RPT_SHIFT_MINUS ){ shift = '2'; } int tstep = 0; if( (chan->mode == RIG_MODE_AM) || (chan->mode == RIG_MODE_FM) ){ switch( chan->tuning_step ){ case s_kHz(6.25): tstep = 1; break; case s_kHz(10): tstep = 2; break; case s_kHz(12.5): tstep = 3; break; case s_kHz(15): tstep = 4; break; case s_kHz(20): tstep = 5; break; case s_kHz(25): tstep = 6; break; case s_kHz(30): tstep = 7; break; case s_kHz(50): tstep = 8; break; case s_kHz(100): tstep = 9; break; default: tstep = 0; } }else{ switch( chan->tuning_step ){ case s_kHz(2.5): tstep = 1; break; case s_kHz(5): tstep = 2; break; case s_kHz(10): tstep = 3; break; default: tstep = 0; } } /* P-number 2-3 4 5 6 7 8 9 101112 13 141516 */ sprintf(buf, "MW0%03d%011u%c%c%c%02d%02d%03d%c%c%09d0%c%c%s;", chan->channel_num, (unsigned) chan->freq, /* 4 - frequency */ '0' + mode, /* 5 - mode */ (chan->flags & RIG_CHFLAG_SKIP) ? '1' : '0', /* 6 - lockout status */ sqltype, /* 7 - squelch and tone type */ tone+1, /* 8 - tone code */ code+1, /* 9 - CTCSS code */ dcscode, /* 10 - DCS code */ (chan->funcs & RIG_FUNC_REV ) ? '1' : '0',/* 11 - Reverse status */ shift, /* 12 - shift type */ (int) chan->rptr_offs, /* 13 - offset frequency */ tstep + '0', /* 14 - Step size */ chan->scan_group + '0', /* 15 - Memory group no */ chan->channel_desc /* 16 - description */ ); rig_debug( RIG_DEBUG_VERBOSE, "The command will be: %s\n", buf ); size_t tmp=0; err = kenwood_transaction(rig, buf, strlen(buf), NULL, &tmp ); if (err != RIG_OK) return err; if( chan->split == RIG_SPLIT_ON ){ sprintf(buf, "MW1%03d%011u%c%c%c%02d%02d%03d%c%c%09d0%c%c%s;\n", chan->channel_num, (unsigned) chan->tx_freq, /* 4 - frequency */ '0' + tx_mode, /* 5 - mode */ (chan->flags & RIG_CHFLAG_SKIP) ? '1' : '0', /* 6 - lockout status */ sqltype, /* 7 - squelch and tone type */ tone+1, /* 8 - tone code */ code+1, /* 9 - CTCSS code */ dcscode+1, /* 10 - DCS code */ (chan->funcs & RIG_FUNC_REV ) ? '1' : '0',/* 11 - Reverse status */ shift, /* 12 - shift type */ (int) chan->rptr_offs, /* 13 - offset frequency */ tstep + '0', /* 14 - Step size */ chan->scan_group + '0', /* Memory group no */ chan->channel_desc /* 16 - description */ ); rig_debug( RIG_DEBUG_VERBOSE, "Split, the command will be: %s\n", buf ); tmp = 0; err = kenwood_transaction(rig, buf, strlen(buf), NULL, &tmp ); } return err; } /* * ts2000_get_level * Assumes rig!=NULL, val!=NULL */ int ts2000_get_level(RIG *rig, vfo_t vfo, setting_t level, value_t *val) { char lvlbuf[50]; size_t lvl_len; int lvl, retval, ret, agclevel; lvl_len = 50; switch (level) { case RIG_LEVEL_PREAMP: retval = kenwood_transaction (rig, "PA", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if ((lvl_len != 5)){ /*TS-2000 returns 5 chars for PA; */ rig_debug(RIG_DEBUG_ERR,"%s: unexpected answer len=%d\n", __func__, lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); if (lvl < 10) /* just checking for main receiver preamp setting */ val->i = 0; if (lvl > 9) val->i = rig->state.preamp[0]; break; case RIG_LEVEL_ATT: retval = kenwood_transaction (rig, "RA", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if ((lvl_len != 7)){ /* TS-2000 returns 7 chars for RA; */ rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); if (lvl < 100) /* just checking main band attenuator */ val->i = 0; if (lvl > 99) val->i = rig->state.attenuator[0]; /* Since the TS-2000 only has one step on the attenuator */ break; case RIG_LEVEL_VOX: retval = kenwood_transaction (rig, "VD", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 7) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); val->i = lvl / 100; break; case RIG_LEVEL_AF: retval = kenwood_transaction (rig, "AG0", 3, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 7) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); val->f = lvl / 255.0; break; case RIG_LEVEL_RF: retval = kenwood_transaction (rig, "RG", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 6) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); val->f = lvl / 255.0; break; case RIG_LEVEL_SQL: retval = kenwood_transaction (rig, "SQ0", 3, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 7) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+3, "%d", &lvl); val->f = lvl / 255.0; break; case RIG_LEVEL_CWPITCH: retval = kenwood_transaction (rig, "EX0310000", 9, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 12) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d answer=%s\n", lvl_len, lvlbuf); return -RIG_ERJCTED; } sscanf(lvlbuf+8, "%d", &lvl); val->i = 400 + (50 * lvl); break; case RIG_LEVEL_RFPOWER: retval = kenwood_transaction (rig, "PC", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 6) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+3, "%d", &lvl); val->f = lvl / 100.0; /* FIXME: for 1.2GHZ need to divide by 10 */ break; case RIG_LEVEL_MICGAIN: retval = kenwood_transaction (rig, "MG", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 6) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); val->f = lvl / 100.0; break; case RIG_LEVEL_KEYSPD: retval = kenwood_transaction (rig, "KS", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 6) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); val->i = lvl; break; case RIG_LEVEL_NOTCHF: return -RIG_ENIMPL; break; case RIG_LEVEL_COMP: retval = kenwood_transaction (rig, "PL", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 9) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); lvl = lvl / 1000; val->f = lvl / 100.0; break; case RIG_LEVEL_AGC: /* FIX ME: ts2000 returns 0 -20 for AGC */ ret = get_kenwood_level(rig, "GT", 2, &val->f); agclevel = 255.0 * val->f; if (agclevel == 0) val->i = 0; else if (agclevel < 85) val->i = 1; else if (agclevel < 170) val->i = 2; else if (agclevel <= 255) val->i = 3; return ret; break; case RIG_LEVEL_BKINDL: retval = kenwood_transaction (rig, "SD", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 7) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); val->i = lvl / 100; break; case RIG_LEVEL_BALANCE: return -RIG_ENIMPL; break; case RIG_LEVEL_METER: retval = kenwood_transaction (rig, "RM", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 8) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); val->i = lvl / 10000; break; case RIG_LEVEL_VOXGAIN: retval = kenwood_transaction (rig, "VG", 2, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (lvl_len != 6) { rig_debug(RIG_DEBUG_ERR,"ts2000_get_level: " "unexpected answer len=%d\n", lvl_len); return -RIG_ERJCTED; } sscanf(lvlbuf+2, "%d", &lvl); val->f = lvl / 9.0; break; case RIG_LEVEL_ANTIVOX: return -RIG_ENIMPL; break; case RIG_LEVEL_RAWSTR: case RIG_LEVEL_STRENGTH: retval = kenwood_transaction (rig, "SM0", 3, lvlbuf, &lvl_len); if (retval != RIG_OK) return retval; if (( (lvl_len !=8)) || lvlbuf[1] != 'M') { /* TS-2000 returns 8 bytes for S meter level */ rig_debug(RIG_DEBUG_ERR,"%s: wrong answer len=%d\n", __func__, lvl_len); return -RIG_ERJCTED; } /* Frontend expects: -54 = S0, 0 = S9 */ sscanf(lvlbuf+3, "%d", &val->i); /* TS-2000 main receiver returns values from 0 - 30 */ /* so scale the value */ if (level == RIG_LEVEL_STRENGTH) val->i = (val->i * 3.6) - 54; break; default: rig_debug(RIG_DEBUG_ERR,"Unsupported get_level %d", level); return -RIG_EINVAL; } return RIG_OK; }