/* * Hamlib Kenwood backend - Elecraft K3 description * Copyright (c) 2002-2009 by Stephane Fillod * Copyright (C) 2010,2011,2012,2013 by Nate Bargmann, n0nb@arrl.net * * 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 * * See the file 'COPYING.LIB' in the main Hamlib distribution directory for * the complete text of the GNU Lesser Public License version 2.1. * */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include "idx_builtin.h" #include "kenwood.h" #include "bandplan.h" #include "elecraft.h" #include "token.h" #include "cal.h" #define K3_MODES (RIG_MODE_CW|RIG_MODE_CWR|RIG_MODE_SSB|\ RIG_MODE_RTTY|RIG_MODE_RTTYR|RIG_MODE_FM|RIG_MODE_AM|RIG_MODE_PKTUSB|\ RIG_MODE_PKTLSB) #define K3_FUNC_ALL (RIG_FUNC_NB|RIG_FUNC_VOX|RIG_FUNC_APF|\ RIG_FUNC_DUAL_WATCH|RIG_FUNC_DIVERSITY|\ RIG_FUNC_LOCK|RIG_FUNC_RIT|RIG_FUNC_XIT) #define K3_LEVEL_ALL (RIG_LEVEL_ATT|RIG_LEVEL_PREAMP|RIG_LEVEL_AGC|RIG_LEVEL_SQL|\ RIG_LEVEL_STRENGTH|RIG_LEVEL_ALC|RIG_LEVEL_RFPOWER|RIG_LEVEL_KEYSPD|\ RIG_LEVEL_AF|RIG_LEVEL_RF|RIG_LEVEL_MICGAIN|RIG_LEVEL_COMP|\ RIG_LEVEL_NR|RIG_LEVEL_MONITOR_GAIN|RIG_LEVEL_RAWSTR|RIG_LEVEL_RFPOWER_METER) #define K3_VFO (RIG_VFO_A|RIG_VFO_B) #define K3_VFO_OP (RIG_OP_UP|RIG_OP_DOWN) #define K3_ANTS (RIG_ANT_1|RIG_ANT_2) #define KX3_FUNC_ALL (RIG_FUNC_NB|RIG_FUNC_VOX|RIG_FUNC_APF|\ RIG_FUNC_DUAL_WATCH|RIG_FUNC_LOCK|RIG_FUNC_RIT|RIG_FUNC_XIT) #define KX3_LEVEL_ALL (RIG_LEVEL_ATT|RIG_LEVEL_PREAMP|RIG_LEVEL_AGC|RIG_LEVEL_SQL|\ RIG_LEVEL_STRENGTH|RIG_LEVEL_RFPOWER|RIG_LEVEL_KEYSPD|\ RIG_LEVEL_AF|RIG_LEVEL_RF|RIG_LEVEL_MICGAIN|RIG_LEVEL_COMP|\ RIG_LEVEL_NR|RIG_LEVEL_MONITOR_GAIN|RIG_LEVEL_RAWSTR|RIG_LEVEL_RFPOWER_METER) /* * Elecraft K3/K3S extra level definitions * * Token definitions for .cfgparams in rig_caps * See enum rig_conf_e and struct confparams in rig.h */ const struct confparams k3_ext_levels[] = { { TOK_IF_FREQ, "ifctr", "IF freq", "IF center frequency", NULL, RIG_CONF_NUMERIC, { .n = { 0, 9990, 10 } } }, { TOK_TX_STAT, "txst", "TX status", "TX status", NULL, RIG_CONF_CHECKBUTTON, { { } }, }, { TOK_RIT_CLR, "ritclr", "RIT clear", "RIT clear", NULL, RIG_CONF_BUTTON, { { } }, }, { TOK_ESSB, "essb", "ESSB", "Extended SSB frequency response", NULL, RIG_CONF_CHECKBUTTON, { { } }, }, { TOK_RX_ANT, "rx_ant", "RX ANT", "RX antenna", NULL, RIG_CONF_CHECKBUTTON, { { } }, }, { TOK_LINK_VFOS, "link_vfos", "Link VFOs", "Link VFOs", NULL, RIG_CONF_CHECKBUTTON, { { } }, }, { TOK_TX_METER, "tx_meter", "TX meter", "Transmit meter mode", NULL, RIG_CONF_COMBO, { .c = { .combostr = { "SWR", "ALC", NULL } } } }, { TOK_IF_NB, "if_nb", "IF NB", "IF noise blanker level", NULL, RIG_CONF_NUMERIC, { .n = { 0, 21, 1 } }, }, { RIG_CONF_END, NULL, } }; /* * Elecraft KX3/KX2 extra level definitions * * Token definitions for .cfgparams in rig_caps * See enum rig_conf_e and struct confparams in rig.h */ const struct confparams kx3_ext_levels[] = { { TOK_TX_STAT, "txst", "TX status", "TX status", NULL, RIG_CONF_CHECKBUTTON, { { } }, }, { TOK_RIT_CLR, "ritclr", "RIT clear", "RIT clear", NULL, RIG_CONF_BUTTON, { { } }, }, { TOK_ESSB, "essb", "ESSB", "Extended SSB frequency response", NULL, RIG_CONF_CHECKBUTTON, { { } }, }, { RIG_CONF_END, NULL, } }; /* kenwood_transaction() will add this to command strings * sent to the rig and remove it from strings returned from * the rig, so no need to append ';' manually to command strings. */ static struct kenwood_priv_caps k3_priv_caps = { .cmdtrm = EOM_KEN, }; /* K3 specific function declarations */ int k3_get_mode(RIG *rig, vfo_t vfo, rmode_t *mode, pbwidth_t *width); int k3_set_mode(RIG *rig, vfo_t vfo, rmode_t mode, pbwidth_t width); int k3_set_vfo(RIG *rig, vfo_t vfo); int k3_set_ext_level(RIG *rig, vfo_t vfo, token_t token, value_t val); int k3_get_ext_level(RIG *rig, vfo_t vfo, token_t token, value_t *val); int k3_set_rit(RIG *rig, vfo_t vfo, shortfreq_t rit); int k3_set_xit(RIG *rig, vfo_t vfo, shortfreq_t rit); int k3_set_split_mode(RIG *rig, vfo_t vfo, rmode_t tx_mode, pbwidth_t tx_width); int k3_get_split_mode(RIG *rig, vfo_t vfo, rmode_t *tx_mode, pbwidth_t *tx_width); int k3_set_level(RIG *rig, vfo_t vfo, setting_t level, value_t val); int k3_get_level(RIG *rig, vfo_t vfo, setting_t level, value_t *val); int kx3_get_level(RIG *rig, vfo_t vfo, setting_t level, value_t *val); int k3_set_func(RIG *rig, vfo_t vfo, setting_t func, int status); int k3_get_func(RIG *rig, vfo_t vfo, setting_t func, int *status); /* Private helper functions */ int set_rit_xit(RIG *rig, shortfreq_t rit); int k3_set_nb_level(RIG *rig, float dsp_nb, float if_nb); int k3_get_nb_level(RIG *rig, float *dsp_nb, float *if_nb); int k3_get_bar_graph_level(RIG *rig, float *smeter, float *pwr, float *alc, int *mode_tx); int kx3_get_bar_graph_level(RIG *rig, float *level); /* * K3 rig capabilities. * This kit can recognize a large subset of TS-570/K2 commands and has many * extensions of its own. Extension backend functions to standard Kenwood * command are defined in elecraft.c (shared with K2) and in this file. * * Part of info comes from http://www.elecraft.com/K2_Manual_Download_Page.htm#K3 * look for K3 Programmer's Reference PDF * */ const struct rig_caps k3_caps = { .rig_model = RIG_MODEL_K3, .model_name = "K3", .mfg_name = "Elecraft", .version = "20200107", .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 = 4800, .serial_rate_max = 38400, .serial_data_bits = 8, .serial_stop_bits = 1, .serial_parity = RIG_PARITY_NONE, .serial_handshake = RIG_HANDSHAKE_NONE, .write_delay = 0, /* Timing between bytes */ .post_write_delay = 0, /* Timing between command strings */ .timeout = 1000, /* FA and FB make take up to 500 ms on band change */ .retry = 5, .has_get_func = K3_FUNC_ALL, .has_set_func = K3_FUNC_ALL, .has_get_level = K3_LEVEL_ALL, .has_set_level = RIG_LEVEL_SET(K3_LEVEL_ALL), .has_get_parm = RIG_PARM_NONE, .has_set_parm = RIG_PARM_NONE, /* FIXME: parms */ .level_gran = { [LVL_KEYSPD] = { .min = { .i = 8 }, .max = { .i = 50 }, .step = { .i = 1 } }, }, .parm_gran = {}, .extlevels = k3_ext_levels, .extparms = kenwood_cfg_params, .preamp = { 1, RIG_DBLST_END, }, .attenuator = { 10, RIG_DBLST_END, }, .max_rit = Hz(9990), .max_xit = Hz(9990), .max_ifshift = Hz(0), .vfo_ops = K3_VFO_OP, .targetable_vfo = RIG_TARGETABLE_FREQ, .transceive = RIG_TRN_RIG, .bank_qty = 0, .chan_desc_sz = 0, .chan_list = { RIG_CHAN_END }, .rx_range_list1 = { {kHz(500), MHz(30), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, { MHz(48), MHz(54), K3_MODES, -1, - 1, K3_VFO, K3_ANTS}, RIG_FRNG_END, }, /* rx range */ .tx_range_list1 = { FRQ_RNG_HF(1, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), FRQ_RNG_6m(1, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), RIG_FRNG_END, }, /* tx range */ .rx_range_list2 = { {kHz(500), MHz(30), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, { MHz(48), MHz(54), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, RIG_FRNG_END, }, /* rx range */ .tx_range_list2 = { FRQ_RNG_HF(2, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), FRQ_RNG_6m(2, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), RIG_FRNG_END, }, /* tx range */ .tuning_steps = { {K3_MODES, 1}, RIG_TS_END, }, /* mode/filter list, remember: order matters! */ /* Values are arbitrary based on common K3 filter options. */ .filters = { {RIG_MODE_SSB, kHz(2.7)}, {RIG_MODE_SSB, kHz(2.8)}, {RIG_MODE_SSB, kHz(1.8)}, {RIG_MODE_SSB, kHz(2.4)}, {RIG_MODE_SSB, RIG_FLT_ANY}, {RIG_MODE_CW | RIG_MODE_CWR, kHz(1)}, {RIG_MODE_CW | RIG_MODE_CWR, kHz(2.8)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(50)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(500)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(300)}, {RIG_MODE_CW | RIG_MODE_CWR, RIG_FLT_ANY}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, kHz(2)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, kHz(2.7)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, Hz(500)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, Hz(300)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, RIG_FLT_ANY}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, kHz(2.7)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, kHz(2.8)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(50)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(2400)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(500)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(300)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, RIG_FLT_ANY}, {RIG_MODE_AM, kHz(6)}, {RIG_MODE_AM, kHz(13)}, {RIG_MODE_AM, kHz(2.7)}, {RIG_MODE_AM, RIG_FLT_ANY}, {RIG_MODE_FM, kHz(13)}, /* TBC */ RIG_FLT_END, }, .priv = (void *)& k3_priv_caps, .rig_init = kenwood_init, .rig_cleanup = kenwood_cleanup, .rig_open = elecraft_open, .rig_close = kenwood_close, .set_freq = kenwood_set_freq, .get_freq = kenwood_get_freq, .set_mode = k3_set_mode, .get_mode = k3_get_mode, .set_vfo = k3_set_vfo, .get_vfo = kenwood_get_vfo_if, .set_split_mode = k3_set_split_mode, .get_split_mode = k3_get_split_mode, .set_split_vfo = kenwood_set_split_vfo, .get_split_vfo = kenwood_get_split_vfo_if, .set_rit = k3_set_rit, .get_rit = kenwood_get_rit, .set_xit = k3_set_xit, .get_xit = kenwood_get_xit, .get_ptt = kenwood_get_ptt, .set_ptt = kenwood_set_ptt, .get_dcd = kenwood_get_dcd, .set_func = k3_set_func, .get_func = k3_get_func, .set_ext_parm = kenwood_set_ext_parm, .get_ext_parm = kenwood_get_ext_parm, .set_level = k3_set_level, .get_level = k3_get_level, .set_ext_level = k3_set_ext_level, .get_ext_level = k3_get_ext_level, .vfo_op = kenwood_vfo_op, .set_trn = kenwood_set_trn, .get_trn = kenwood_get_trn, .set_powerstat = kenwood_set_powerstat, .get_powerstat = kenwood_get_powerstat, .set_ant = kenwood_set_ant_no_ack, .get_ant = kenwood_get_ant, .send_morse = kenwood_send_morse, }; const struct rig_caps k3s_caps = { .rig_model = RIG_MODEL_K3S, .model_name = "K3S", .mfg_name = "Elecraft", .version = "20190529", .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 = 4800, .serial_rate_max = 38400, .serial_data_bits = 8, .serial_stop_bits = 1, .serial_parity = RIG_PARITY_NONE, .serial_handshake = RIG_HANDSHAKE_NONE, .write_delay = 0, /* Timing between bytes */ .post_write_delay = 0, /* Timing between command strings */ .timeout = 1000, /* FA and FB make take up to 500 ms on band change */ .retry = 5, .has_get_func = K3_FUNC_ALL, .has_set_func = K3_FUNC_ALL, .has_get_level = K3_LEVEL_ALL, .has_set_level = RIG_LEVEL_SET(K3_LEVEL_ALL), .has_get_parm = RIG_PARM_NONE, .has_set_parm = RIG_PARM_NONE, /* FIXME: parms */ .level_gran = { [LVL_KEYSPD] = { .min = { .i = 8 }, .max = { .i = 50 }, .step = { .i = 1 } }, }, .parm_gran = {}, .extlevels = k3_ext_levels, .extparms = kenwood_cfg_params, .preamp = { 1, RIG_DBLST_END, }, .attenuator = { 5, 10, 15, RIG_DBLST_END, }, .max_rit = Hz(9990), .max_xit = Hz(9990), .max_ifshift = Hz(0), .vfo_ops = K3_VFO_OP, .targetable_vfo = RIG_TARGETABLE_FREQ, .transceive = RIG_TRN_RIG, .bank_qty = 0, .chan_desc_sz = 0, .chan_list = { RIG_CHAN_END }, .rx_range_list1 = { {kHz(500), MHz(30), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, { MHz(48), MHz(54), K3_MODES, -1, - 1, K3_VFO, K3_ANTS}, RIG_FRNG_END, }, /* rx range */ .tx_range_list1 = { FRQ_RNG_HF(1, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), FRQ_RNG_6m(1, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), RIG_FRNG_END, }, /* tx range */ .rx_range_list2 = { {kHz(500), MHz(30), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, { MHz(48), MHz(54), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, RIG_FRNG_END, }, /* rx range */ .tx_range_list2 = { FRQ_RNG_HF(2, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), FRQ_RNG_6m(2, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), RIG_FRNG_END, }, /* tx range */ .tuning_steps = { {K3_MODES, 1}, RIG_TS_END, }, /* mode/filter list, remember: order matters! */ /* Values are arbitrary based on common K3 filter options. */ .filters = { {RIG_MODE_SSB, kHz(2.7)}, {RIG_MODE_SSB, kHz(2.8)}, {RIG_MODE_SSB, kHz(1.8)}, {RIG_MODE_SSB, kHz(2.4)}, {RIG_MODE_SSB, RIG_FLT_ANY}, {RIG_MODE_CW | RIG_MODE_CWR, kHz(1)}, {RIG_MODE_CW | RIG_MODE_CWR, kHz(2.8)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(50)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(500)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(300)}, {RIG_MODE_CW | RIG_MODE_CWR, RIG_FLT_ANY}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, kHz(2)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, kHz(2.7)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, Hz(500)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, Hz(300)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, RIG_FLT_ANY}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, kHz(2.7)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, kHz(2.8)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(50)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(2400)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(500)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(300)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, RIG_FLT_ANY}, {RIG_MODE_AM, kHz(6)}, {RIG_MODE_AM, kHz(13)}, {RIG_MODE_AM, kHz(2.7)}, {RIG_MODE_AM, RIG_FLT_ANY}, {RIG_MODE_FM, kHz(13)}, /* TBC */ RIG_FLT_END, }, .priv = (void *)& k3_priv_caps, .rig_init = kenwood_init, .rig_cleanup = kenwood_cleanup, .rig_open = elecraft_open, .rig_close = kenwood_close, .set_freq = kenwood_set_freq, .get_freq = kenwood_get_freq, .set_mode = k3_set_mode, .get_mode = k3_get_mode, .set_vfo = k3_set_vfo, .get_vfo = kenwood_get_vfo_if, .set_split_mode = k3_set_split_mode, .get_split_mode = k3_get_split_mode, .set_split_vfo = kenwood_set_split_vfo, .get_split_vfo = kenwood_get_split_vfo_if, .set_rit = k3_set_rit, .get_rit = kenwood_get_rit, .set_xit = k3_set_xit, .get_xit = kenwood_get_xit, .get_ptt = kenwood_get_ptt, .set_ptt = kenwood_set_ptt, .get_dcd = kenwood_get_dcd, .set_func = k3_set_func, .get_func = k3_get_func, .set_ext_parm = kenwood_set_ext_parm, .get_ext_parm = kenwood_get_ext_parm, .set_level = k3_set_level, .get_level = k3_get_level, .set_ext_level = k3_set_ext_level, .get_ext_level = k3_get_ext_level, .vfo_op = kenwood_vfo_op, .set_trn = kenwood_set_trn, .get_trn = kenwood_get_trn, .set_powerstat = kenwood_set_powerstat, .get_powerstat = kenwood_get_powerstat, .set_ant = kenwood_set_ant_no_ack, .get_ant = kenwood_get_ant, .send_morse = kenwood_send_morse, }; const struct rig_caps kx3_caps = { .rig_model = RIG_MODEL_KX3, .model_name = "KX3", .mfg_name = "Elecraft", .version = "20190529", .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 = 4800, .serial_rate_max = 38400, .serial_data_bits = 8, .serial_stop_bits = 1, .serial_parity = RIG_PARITY_NONE, .serial_handshake = RIG_HANDSHAKE_NONE, .write_delay = 0, /* Timing between bytes */ .post_write_delay = 0, /* Timing between command strings */ .timeout = 1000, /* FA and FB make take up to 500 ms on band change */ .retry = 5, .has_get_func = KX3_FUNC_ALL, .has_set_func = KX3_FUNC_ALL, .has_get_level = KX3_LEVEL_ALL, .has_set_level = RIG_LEVEL_SET(KX3_LEVEL_ALL), .has_get_parm = RIG_PARM_NONE, .has_set_parm = RIG_PARM_NONE, /* FIXME: parms */ .level_gran = { [LVL_KEYSPD] = { .min = { .i = 8 }, .max = { .i = 50 }, .step = { .i = 1 } }, }, .parm_gran = {}, .extlevels = kx3_ext_levels, .extparms = kenwood_cfg_params, .preamp = { 1, RIG_DBLST_END, }, .attenuator = { 10, RIG_DBLST_END, }, .max_rit = Hz(9990), .max_xit = Hz(9990), .max_ifshift = Hz(0), .vfo_ops = K3_VFO_OP, .targetable_vfo = RIG_TARGETABLE_FREQ, .transceive = RIG_TRN_RIG, .bank_qty = 0, .chan_desc_sz = 0, .chan_list = { RIG_CHAN_END }, .rx_range_list1 = { {kHz(500), MHz(30), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, { MHz(48), MHz(54), K3_MODES, -1, - 1, K3_VFO, K3_ANTS}, RIG_FRNG_END, }, /* rx range */ .tx_range_list1 = { FRQ_RNG_HF(1, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), FRQ_RNG_6m(1, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), RIG_FRNG_END, }, /* tx range */ .rx_range_list2 = { {kHz(500), MHz(30), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, { MHz(48), MHz(54), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, RIG_FRNG_END, }, /* rx range */ .tx_range_list2 = { FRQ_RNG_HF(2, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), FRQ_RNG_6m(2, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), RIG_FRNG_END, }, /* tx range */ .tuning_steps = { {K3_MODES, 1}, RIG_TS_END, }, /* mode/filter list, remember: order matters! */ /* Values are arbitrary based on common K3 filter options. */ .filters = { {RIG_MODE_SSB, kHz(2.7)}, {RIG_MODE_SSB, kHz(2.8)}, {RIG_MODE_SSB, kHz(1.8)}, {RIG_MODE_SSB, kHz(2.4)}, {RIG_MODE_SSB, RIG_FLT_ANY}, {RIG_MODE_CW | RIG_MODE_CWR, kHz(1)}, {RIG_MODE_CW | RIG_MODE_CWR, kHz(2.8)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(50)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(500)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(300)}, {RIG_MODE_CW | RIG_MODE_CWR, RIG_FLT_ANY}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, kHz(2)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, kHz(2.7)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, Hz(500)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, Hz(300)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, RIG_FLT_ANY}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, kHz(2.7)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, kHz(2.8)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(50)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(2400)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(500)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(300)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, RIG_FLT_ANY}, {RIG_MODE_AM, kHz(6)}, {RIG_MODE_AM, kHz(13)}, {RIG_MODE_AM, kHz(2.7)}, {RIG_MODE_AM, RIG_FLT_ANY}, {RIG_MODE_FM, kHz(13)}, /* TBC */ RIG_FLT_END, }, .priv = (void *)& k3_priv_caps, .rig_init = kenwood_init, .rig_cleanup = kenwood_cleanup, .rig_open = elecraft_open, .rig_close = kenwood_close, .set_freq = kenwood_set_freq, .get_freq = kenwood_get_freq, .set_mode = k3_set_mode, .get_mode = k3_get_mode, .set_vfo = k3_set_vfo, .get_vfo = kenwood_get_vfo_if, .set_split_mode = k3_set_split_mode, .get_split_mode = k3_get_split_mode, .set_split_vfo = kenwood_set_split_vfo, .get_split_vfo = kenwood_get_split_vfo_if, .set_rit = k3_set_rit, .get_rit = kenwood_get_rit, .set_xit = k3_set_xit, .get_xit = kenwood_get_xit, .get_ptt = kenwood_get_ptt, .set_ptt = kenwood_set_ptt, .get_dcd = kenwood_get_dcd, .set_func = k3_set_func, .get_func = k3_get_func, .set_ext_parm = kenwood_set_ext_parm, .get_ext_parm = kenwood_get_ext_parm, .set_level = k3_set_level, .get_level = kx3_get_level, .set_ext_level = k3_set_ext_level, .get_ext_level = k3_get_ext_level, .vfo_op = kenwood_vfo_op, .set_trn = kenwood_set_trn, .get_trn = kenwood_get_trn, .set_powerstat = kenwood_set_powerstat, .get_powerstat = kenwood_get_powerstat, .set_ant = kenwood_set_ant_no_ack, .get_ant = kenwood_get_ant, .send_morse = kenwood_send_morse, }; const struct rig_caps kx2_caps = { .rig_model = RIG_MODEL_KX2, .model_name = "KX2", .mfg_name = "Elecraft", .version = "20190529", .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 = 4800, .serial_rate_max = 38400, .serial_data_bits = 8, .serial_stop_bits = 1, .serial_parity = RIG_PARITY_NONE, .serial_handshake = RIG_HANDSHAKE_NONE, .write_delay = 0, /* Timing between bytes */ .post_write_delay = 0, /* Timing between command strings */ .timeout = 1000, /* FA and FB make take up to 500 ms on band change */ .retry = 5, .has_get_func = KX3_FUNC_ALL, .has_set_func = KX3_FUNC_ALL, .has_get_level = KX3_LEVEL_ALL, .has_set_level = RIG_LEVEL_SET(KX3_LEVEL_ALL), .has_get_parm = RIG_PARM_NONE, .has_set_parm = RIG_PARM_NONE, /* FIXME: parms */ .level_gran = { [LVL_KEYSPD] = { .min = { .i = 8 }, .max = { .i = 50 }, .step = { .i = 1 } }, }, .parm_gran = {}, .extlevels = kx3_ext_levels, .extparms = kenwood_cfg_params, .preamp = { 1, RIG_DBLST_END, }, .attenuator = { 10, RIG_DBLST_END, }, .max_rit = Hz(9990), .max_xit = Hz(9990), .max_ifshift = Hz(0), .vfo_ops = K3_VFO_OP, .targetable_vfo = RIG_TARGETABLE_FREQ, .transceive = RIG_TRN_RIG, .bank_qty = 0, .chan_desc_sz = 0, .chan_list = { RIG_CHAN_END }, .rx_range_list1 = { {kHz(500), MHz(30), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, { MHz(48), MHz(54), K3_MODES, -1, - 1, K3_VFO, K3_ANTS}, RIG_FRNG_END, }, /* rx range */ .tx_range_list1 = { FRQ_RNG_HF(1, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), FRQ_RNG_6m(1, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), RIG_FRNG_END, }, /* tx range */ .rx_range_list2 = { {kHz(500), MHz(30), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, { MHz(48), MHz(54), K3_MODES, -1, -1, K3_VFO, K3_ANTS}, RIG_FRNG_END, }, /* rx range */ .tx_range_list2 = { FRQ_RNG_HF(2, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), FRQ_RNG_6m(2, K3_MODES, mW(10), W(10), K3_VFO, K3_ANTS), RIG_FRNG_END, }, /* tx range */ .tuning_steps = { {K3_MODES, 1}, RIG_TS_END, }, /* mode/filter list, remember: order matters! */ /* Values are arbitrary based on common K3 filter options. */ .filters = { {RIG_MODE_SSB, kHz(2.7)}, {RIG_MODE_SSB, kHz(2.8)}, {RIG_MODE_SSB, kHz(1.8)}, {RIG_MODE_SSB, kHz(2.4)}, {RIG_MODE_SSB, RIG_FLT_ANY}, {RIG_MODE_CW | RIG_MODE_CWR, kHz(1)}, {RIG_MODE_CW | RIG_MODE_CWR, kHz(2.8)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(50)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(500)}, {RIG_MODE_CW | RIG_MODE_CWR, Hz(300)}, {RIG_MODE_CW | RIG_MODE_CWR, RIG_FLT_ANY}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, kHz(2)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, kHz(2.7)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, Hz(500)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, Hz(300)}, {RIG_MODE_RTTY | RIG_MODE_RTTYR, RIG_FLT_ANY}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, kHz(2.7)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, kHz(2.8)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(50)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(2400)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(500)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, Hz(300)}, {RIG_MODE_PKTUSB | RIG_MODE_PKTLSB, RIG_FLT_ANY}, {RIG_MODE_AM, kHz(6)}, {RIG_MODE_AM, kHz(13)}, {RIG_MODE_AM, kHz(2.7)}, {RIG_MODE_AM, RIG_FLT_ANY}, {RIG_MODE_FM, kHz(13)}, /* TBC */ RIG_FLT_END, }, .priv = (void *)& k3_priv_caps, .rig_init = kenwood_init, .rig_cleanup = kenwood_cleanup, .rig_open = elecraft_open, .rig_close = kenwood_close, .set_freq = kenwood_set_freq, .get_freq = kenwood_get_freq, .set_mode = k3_set_mode, .get_mode = k3_get_mode, .set_vfo = k3_set_vfo, .get_vfo = kenwood_get_vfo_if, .set_split_mode = k3_set_split_mode, .get_split_mode = k3_get_split_mode, .set_split_vfo = kenwood_set_split_vfo, .get_split_vfo = kenwood_get_split_vfo_if, .set_rit = k3_set_rit, .get_rit = kenwood_get_rit, .set_xit = k3_set_xit, .get_xit = kenwood_get_xit, .get_ptt = kenwood_get_ptt, .set_ptt = kenwood_set_ptt, .get_dcd = kenwood_get_dcd, .set_func = k3_set_func, .get_func = k3_get_func, .set_ext_parm = kenwood_set_ext_parm, .get_ext_parm = kenwood_get_ext_parm, .set_level = k3_set_level, .get_level = kx3_get_level, .set_ext_level = k3_set_ext_level, .get_ext_level = k3_get_ext_level, .vfo_op = kenwood_vfo_op, .set_trn = kenwood_set_trn, .get_trn = kenwood_get_trn, .set_powerstat = kenwood_set_powerstat, .get_powerstat = kenwood_get_powerstat, .set_ant = kenwood_set_ant_no_ack, .get_ant = kenwood_get_ant, .send_morse = kenwood_send_morse, }; /* * K3 extension function definitions follow */ /* k3_get_mode() * * The K3 supports a new command, DT, to query the data submode so * RIG_MODE_PKTUSB and RIG_MODE_PKTLSB can be supported. */ int k3_get_mode(RIG *rig, vfo_t vfo, rmode_t *mode, pbwidth_t *width) { char buf[KENWOOD_MAX_BUF_LEN]; int err; rmode_t temp_m; pbwidth_t temp_w; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!mode || !width) { return -RIG_EINVAL; } err = kenwood_get_mode(rig, vfo, &temp_m, &temp_w); if (err != RIG_OK) { return err; } if (temp_m == RIG_MODE_RTTY) { err = kenwood_safe_transaction(rig, "DT", buf, KENWOOD_MAX_BUF_LEN, 3); if (err != RIG_OK) { rig_debug(RIG_DEBUG_VERBOSE, "%s: Cannot read K3 DT value\n", __func__); return err; } switch (atoi(&buf[2])) { case K3_MODE_DATA_A: case K3_MODE_PSK_D: *mode = RIG_MODE_PKTUSB; break; case K3_MODE_AFSK_A: *mode = RIG_MODE_PKTLSB; break; default: *mode = temp_m; break; } } else if (temp_m == RIG_MODE_RTTYR) { err = kenwood_safe_transaction(rig, "DT", buf, KENWOOD_MAX_BUF_LEN, 3); if (err != RIG_OK) { rig_debug(RIG_DEBUG_VERBOSE, "%s: Cannot read K3 DT value\n", __func__); return err; } switch (atoi(&buf[2])) { case K3_MODE_DATA_A: case K3_MODE_PSK_D: *mode = RIG_MODE_PKTLSB; break; case K3_MODE_AFSK_A: *mode = RIG_MODE_PKTUSB; break; case K3_MODE_FSK_D: default: *mode = temp_m; break; } } else { *mode = temp_m; } /* The K3 is not limited to specific filter widths so we can query * the actual bandwidth using the BW command */ err = kenwood_safe_transaction(rig, "BW", buf, KENWOOD_MAX_BUF_LEN, 6); if (err != RIG_OK) { rig_debug(RIG_DEBUG_VERBOSE, "%s: Cannot read K3 BW value\n", __func__); return err; } *width = atoi(&buf[2]) * 10; return RIG_OK; } /* k3_set_mode() * * As with k3_get_mode(), the K3 can also set the data sub-modes which * allows use of RIG_MODE_PKTUSB and RIG_MODE_PKTLSB. * * The K3 supports AFSK & FSK sub-modes and for the D versions it also * has an internal RTTY and PSK31 decoder. The decoder sub-modes are * reported as FSK (RTTY) and the AFSK sub-modes are reported as * PKT(USB & LSB). LSB modes are assumed to be RTTY and USB modes are * assumed to be PKT(PSK, WS modes etc.). * * For mode set the data sub-modes are set as follows: * * RTTY -> FSK D normal (LSB) VFO shows MARK QRG * RTTYR -> FSK D reversed (USB) VFO shows MARK QRG * PKTUSB -> DATA A normal (USB) VFO shows suppressed carrier QRG * PKTLSB -> AFSK A normal (LSB) optimised for RTTY VFO shows MARK QRG * Not all data sub-mode combinations are possible but the above * mapping seems most likely to cover the user requirements. */ int k3_set_mode(RIG *rig, vfo_t vfo, rmode_t mode, pbwidth_t width) { int err; char cmd_m[4]; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); switch (mode) { case RIG_MODE_PKTLSB: mode = RIG_MODE_RTTY; snprintf(cmd_m, sizeof(cmd_m), "DT1"); /* AFSK A mode - AFSK on LSB optimised for RTTY, VFO dial is MARK */ break; case RIG_MODE_PKTUSB: mode = RIG_MODE_RTTY; snprintf(cmd_m, sizeof(cmd_m), "DT0"); /* DATA A mode - AFSK on USB general, VFO dial is suppressed carrier QRG */ break; case RIG_MODE_RTTY: case RIG_MODE_RTTYR: snprintf(cmd_m, sizeof(cmd_m), "DT2"); /* FSK D mode - direct FSK keying, LSB is "normal", VFO dial is MARK */ break; default: break; } /* kenwood_set_mode() ignores width value for K2/K3/TS-570 */ err = kenwood_set_mode(rig, vfo, mode, width); if (err != RIG_OK) { return err; } if (width != RIG_PASSBAND_NOCHANGE) { char cmd_s[64]; /* and set the requested bandwidth. On my K3, the bandwidth is rounded * down to the nearest 50 Hz, i.e. sending BW0239; will cause the bandwidth * to be set to 2.350 kHz. As the width must be divided by 10, 10 Hz values * between 0 and 4 round down to the nearest 100 Hz and values between 5 * and 9 round down to the nearest 50 Hz. * * width string value must be padded with leading '0' to equal four * characters. */ /* passband widths vary by mode so gather lower and upper limits */ pbwidth_t pb_nar = rig_passband_narrow(rig, mode); pbwidth_t pb_wid = rig_passband_wide(rig, mode); if (width < 0) { width = labs(width); } if (width == RIG_PASSBAND_NORMAL) { width = rig_passband_normal(rig, mode); } else if (width < pb_nar) { width = pb_nar; } else if (width > pb_wid) { width = pb_wid; } snprintf(cmd_s, sizeof(cmd_s), "BW%04ld", width / 10); err = kenwood_transaction(rig, cmd_s, NULL, 0); if (err != RIG_OK) { return err; } } /* Now set data sub-mode. K3 needs to be in a DATA mode before setting * the sub-mode. */ if (mode == RIG_MODE_PKTLSB || mode == RIG_MODE_PKTUSB || mode == RIG_MODE_RTTY || mode == RIG_MODE_RTTYR) { err = kenwood_transaction(rig, cmd_m, NULL, 0); if (err != RIG_OK) { return err; } } return RIG_OK; } /* The K3 changes "VFOs" by swapping the contents of * the upper display with the lower display. This function * accomplishes this by sending the emulation command, SWT11; * to the K3 to emulate a tap of the A/B button. */ int k3_set_vfo(RIG *rig, vfo_t vfo) { int err; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); switch (vfo) { case RIG_VFO_B: err = kenwood_transaction(rig, "SWT11", NULL, 0); if (err != RIG_OK) { return err; } break; default: break; } return RIG_OK; } /* Support the RC command for clearing RIT/XIT, * * token Defined in elecraft.h or this file * val Type depends on token type from confparams structure: * NUMERIC: val.f * COMBO: val.i, starting from 0 Index to a string table. * STRING: val.cs for set, val.s for get * CHECKBUTTON: val.i 0/1 * * See Private Elecraft extra levels definitions in elecraft.c and * private token #define in elecraft.h */ int k3_set_ext_level(RIG *rig, vfo_t vfo, token_t token, value_t val) { char buf[10]; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); switch (token) { case TOK_RIT_CLR: return kenwood_transaction(rig, "RC", NULL, 0); case TOK_ESSB: snprintf(buf, sizeof(buf), "ES%c", (val.i == 0) ? '0' : '1'); return kenwood_transaction(rig, buf, NULL, 0); case TOK_RX_ANT: snprintf(buf, sizeof(buf), "AR%c", (val.i == 0) ? '0' : '1'); return kenwood_transaction(rig, buf, NULL, 0); case TOK_LINK_VFOS: snprintf(buf, sizeof(buf), "LN%c", (val.i == 0) ? '0' : '1'); return kenwood_transaction(rig, buf, NULL, 0); case TOK_TX_METER: snprintf(buf, sizeof(buf), "TM%c", val.i + '0'); return kenwood_transaction(rig, buf, NULL, 0); case TOK_IF_NB: return k3_set_nb_level(rig, -1, val.f / 21.0f); default: rig_debug(RIG_DEBUG_WARN, "%s: Unsupported set_ext_level %s\n", __func__, rig_strlevel(token)); return -RIG_EINVAL; } } /* Support the FI command for reading the IF center frequency, * useful for panadapters and such that need to know the IF center. * TQ command is a quick transmit status query--K2/K3 only. * * token Defined in elecraft.h or this file * val Type depends on token type from confparams structure: * NUMERIC: val.f * COMBO: val.i, starting from 0 Index to a string table. * STRING: val.cs for set, val.s for get * CHECKBUTTON: val.i 0/1 */ int k3_get_ext_level(RIG *rig, vfo_t vfo, token_t token, value_t *val) { char buf[KENWOOD_MAX_BUF_LEN]; int err; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!val) { return -RIG_EINVAL; } switch (token) { case TOK_IF_FREQ: err = kenwood_safe_transaction(rig, "FI", buf, KENWOOD_MAX_BUF_LEN, 6); if (err != RIG_OK) { return err; } val->f = 8210000.0 + (float) atoi(&buf[2]); break; case TOK_TX_STAT: return get_kenwood_func(rig, "TQ", &val->i); case TOK_ESSB: return get_kenwood_func(rig, "ES", &val->i); case TOK_RX_ANT: return get_kenwood_func(rig, "AR", &val->i); case TOK_LINK_VFOS: return get_kenwood_func(rig, "LN", &val->i); case TOK_TX_METER: return get_kenwood_func(rig, "TM", &val->i); case TOK_IF_NB: { float if_nb; err = k3_get_nb_level(rig, NULL, &if_nb); if (err != RIG_OK) { return err; } val->f = (float)((int)(if_nb * 21.0f)); break; } default: rig_debug(RIG_DEBUG_WARN, "%s: Unsupported get_ext_level %s\n", __func__, rig_strlevel(token)); return -RIG_EINVAL; } return RIG_OK; } /* * k3_set_rit() -- Differs from from generic Kenwood function as K3 can set * RIT to an arbitrary offset. When rit == 0, the RIT offset is cleared. */ int k3_set_rit(RIG *rig, vfo_t vfo, shortfreq_t rit) { int err; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); err = set_rit_xit(rig, rit); if (err != RIG_OK) { return err; } return RIG_OK; } /* * k3_set_xit() -- Differs from from generic Kenwood function as K3 can set * XIT to an arbitrary offset. When rit == 0, the XIT offset is cleared. */ int k3_set_xit(RIG *rig, vfo_t vfo, shortfreq_t rit) { int err; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); err = set_rit_xit(rig, rit); if (err != RIG_OK) { return err; } return RIG_OK; } /* * The K3 *always* uses VFOB for TX. */ int k3_set_split_mode(RIG *rig, vfo_t vfo, rmode_t tx_mode, pbwidth_t tx_width) { struct kenwood_priv_caps *caps = kenwood_caps(rig); char buf[32]; char kmode; int err; char cmd_m[4]; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); switch (tx_mode) { case RIG_MODE_PKTLSB: tx_mode = RIG_MODE_RTTY; snprintf(cmd_m, sizeof(cmd_m), "DT1"); /* AFSK A mode - AFSK on LSB optimised for RTTY, VFO dial is MARK */ break; case RIG_MODE_PKTUSB: tx_mode = RIG_MODE_RTTY; snprintf(cmd_m, sizeof(cmd_m), "DT0"); /* DATA A mode - AFSK on USB general, VFO dial is suppressed carrier QRG */ break; case RIG_MODE_RTTY: case RIG_MODE_RTTYR: snprintf(cmd_m, sizeof(cmd_m), "DT2"); /* FSK D mode - direct FSK keying, LSB is "normal", VFO dial is MARK */ break; default: break; } #if 0 /* Set data sub-mode. K3 needs to be in a DATA mode before setting * the sub-mode or switching to VFOB so we do this before the MD$ command. */ if (tx_mode == RIG_MODE_PKTLSB || tx_mode == RIG_MODE_PKTUSB || tx_mode == RIG_MODE_RTTY || tx_mode == RIG_MODE_RTTYR) { err = kenwood_transaction(rig, cmd_m, NULL, 0); if (err != RIG_OK) { return err; } } #endif kmode = rmode2kenwood(tx_mode, caps->mode_table); if (kmode < 0) { rig_debug(RIG_DEBUG_WARN, "%s: unsupported mode '%s'\n", __func__, rig_strrmode(tx_mode)); return -RIG_EINVAL; } sprintf(buf, "MD$%c", '0' + kmode); err = kenwood_transaction(rig, buf, NULL, 0); if (err != RIG_OK) { return err; } if (tx_width != RIG_PASSBAND_NOCHANGE) { char cmd_s[32]; /* and set the requested bandwidth. On my K3, the bandwidth is rounded * down to the nearest 50 Hz, i.e. sending BW0239; will cause the bandwidth * to be set to 2.350 kHz. As the width must be divided by 10, 10 Hz values * between 0 and 4 round down to the nearest 100 Hz and values between 5 * and 9 round down to the nearest 50 Hz. * * tx_width string value must be padded with leading '0' to equal four * characters. */ /* passband widths vary by mode so gather lower and upper limits */ pbwidth_t pb_nar = rig_passband_narrow(rig, tx_mode); pbwidth_t pb_wid = rig_passband_wide(rig, tx_mode); if (tx_width < 0) { tx_width = labs(tx_width); } if (tx_width == RIG_PASSBAND_NORMAL) { tx_width = rig_passband_normal(rig, tx_mode); } else if (tx_width < pb_nar) { tx_width = pb_nar; } else if (tx_width > pb_wid) { tx_width = pb_wid; } snprintf(cmd_s, sizeof(cmd_s), "BW$%04ld", tx_width / 10); err = kenwood_transaction(rig, cmd_s, NULL, 0); if (err != RIG_OK) { return err; } } return RIG_OK; } /* The K3 *always* uses VFOB for TX. */ int k3_get_split_mode(RIG *rig, vfo_t vfo, rmode_t *tx_mode, pbwidth_t *tx_width) { char buf[KENWOOD_MAX_BUF_LEN]; int err; rmode_t temp_m; struct kenwood_priv_caps *caps = kenwood_caps(rig); rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!tx_mode || !tx_width) { return -RIG_EINVAL; } err = kenwood_safe_transaction(rig, "MD$", buf, KENWOOD_MAX_BUF_LEN, 4); if (err != RIG_OK) { return err; } temp_m = kenwood2rmode(buf[3] - '0', caps->mode_table); if (temp_m == RIG_MODE_RTTY) { err = kenwood_safe_transaction(rig, "DT", buf, KENWOOD_MAX_BUF_LEN, 3); if (err != RIG_OK) { rig_debug(RIG_DEBUG_VERBOSE, "%s: Cannot read K3 DT value\n", __func__); return err; } switch (atoi(&buf[2])) { case K3_MODE_DATA_A: case K3_MODE_PSK_D: *tx_mode = RIG_MODE_PKTUSB; break; case K3_MODE_AFSK_A: *tx_mode = RIG_MODE_PKTLSB; break; default: *tx_mode = temp_m; break; } } else if (temp_m == RIG_MODE_RTTYR) { err = kenwood_safe_transaction(rig, "DT", buf, KENWOOD_MAX_BUF_LEN, 3); if (err != RIG_OK) { rig_debug(RIG_DEBUG_VERBOSE, "%s: Cannot read K3 DT value\n", __func__); return err; } switch (atoi(&buf[2])) { case K3_MODE_DATA_A: case K3_MODE_PSK_D: *tx_mode = RIG_MODE_PKTLSB; break; case K3_MODE_AFSK_A: *tx_mode = RIG_MODE_PKTUSB; break; case K3_MODE_FSK_D: break; default: *tx_mode = temp_m; break; } } else { *tx_mode = temp_m; } /* The K3 is not limited to specific filter widths so we can query * the actual bandwidth using the BW$ command */ err = kenwood_safe_transaction(rig, "BW$", buf, KENWOOD_MAX_BUF_LEN, 7); if (err != RIG_OK) { rig_debug(RIG_DEBUG_VERBOSE, "%s: Cannot read K3 BW$ value\n", __func__); return err; } *tx_width = atoi(&buf[3]) * 10; return RIG_OK; } int k3_set_level(RIG *rig, vfo_t vfo, setting_t level, value_t val) { char levelbuf[16]; int kenwood_val; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (RIG_LEVEL_IS_FLOAT(level)) { kenwood_val = val.f * 255; } else { kenwood_val = val.i; } switch (level) { case RIG_LEVEL_AGC: switch (val.i) { case RIG_AGC_OFF: kenwood_val = 0; break; case RIG_AGC_SUPERFAST: case RIG_AGC_FAST: kenwood_val = 2; break; case RIG_AGC_MEDIUM: case RIG_AGC_SLOW: kenwood_val = 4; break; case RIG_AGC_USER: case RIG_AGC_AUTO: return -RIG_EINVAL; } snprintf(levelbuf, sizeof(levelbuf), "GT%03d", kenwood_val); break; case RIG_LEVEL_ATT: if (val.i == 0) { snprintf(levelbuf, sizeof(levelbuf), "RA00"); } else if (val.i == 10) { snprintf(levelbuf, sizeof(levelbuf), "RA01"); } else { int i; for (i = 0; i < MAXDBLSTSIZ && rig->state.attenuator[i]; i++) { if (val.i == rig->state.attenuator[i]) { snprintf(levelbuf, sizeof(levelbuf), "RA%02d", i + 1); break; } } if (val.i != rig->state.attenuator[i]) { return -RIG_EINVAL; } } break; case RIG_LEVEL_MICGAIN: snprintf(levelbuf, sizeof(levelbuf), "MG%03d", (int)(val.f * 60.0f)); break; case RIG_LEVEL_COMP: snprintf(levelbuf, sizeof(levelbuf), "CP%03d", (int)(val.f * 40.0f)); break; case RIG_LEVEL_SQL: snprintf(levelbuf, sizeof(levelbuf), "SQ%03d", (int)(val.f * 29.0f)); break; case RIG_LEVEL_RF: snprintf(levelbuf, sizeof(levelbuf), "RG%03d", (int)(val.f * 250.0f)); break; case RIG_LEVEL_NR: return k3_set_nb_level(rig, val.f, -1); case RIG_LEVEL_MONITOR_GAIN: snprintf(levelbuf, sizeof(levelbuf), "ML%03d", (int)(val.f * 60.0f)); break; default: return kenwood_set_level(rig, vfo, level, val); } return kenwood_transaction(rig, levelbuf, NULL, 0); } /* * Handle S-meter (SM, SMH) level locally and pass rest to kenwood_get_level() */ int k3_get_level(RIG *rig, vfo_t vfo, setting_t level, value_t *val) { char lvlbuf[50]; int retval; int lvl; struct kenwood_priv_data *priv = rig->state.priv; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!val) { return -RIG_EINVAL; } switch (level) { float firmware_have; float firmware_need; case RIG_LEVEL_STRENGTH: /* As of FW rev 4.37 the K3 supports an 'SMH' command that * offers a higher resolution, 0-100 (mine went to 106), * rawstr value for more precise S-meter reporting. */ firmware_have = 0; if (priv->fw_rev != NULL) { sscanf(priv->fw_rev, "%f", &firmware_have); } sscanf("4.37", "%f", &firmware_need); if (firmware_have < firmware_need) { cal_table_t str_cal = K3_SM_CAL; retval = kenwood_safe_transaction(rig, "SM", lvlbuf, sizeof(lvlbuf), 6); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%d", &val->i); /* rawstr */ val->i = (int) rig_raw2val(val->i, &str_cal); } else { cal_table_t str_cal = K3_SMH_CAL; retval = kenwood_safe_transaction(rig, "SMH", lvlbuf, sizeof(lvlbuf), 6); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 3, "%d", &val->i); /* rawstr */ val->i = (int) rig_raw2val(val->i, &str_cal); } break; case RIG_LEVEL_ALC: { int tx_mode; float alc; retval = k3_get_bar_graph_level(rig, NULL, NULL, &alc, &tx_mode); if (retval != RIG_OK) { return retval; } if (!tx_mode) { val->f = 0.0f; return RIG_OK; } if (alc < 0) { return -RIG_EINVAL; } val->f = alc; break; } case RIG_LEVEL_RFPOWER_METER: { int tx_mode; float pwr; retval = k3_get_bar_graph_level(rig, NULL, &pwr, NULL, &tx_mode); if (retval != RIG_OK) { return retval; } if (!tx_mode) { val->f = 0.0f; return RIG_OK; } if (pwr < 0) { return -RIG_EINVAL; } val->f = pwr; break; } case RIG_LEVEL_AGC: retval = kenwood_safe_transaction(rig, "GT", lvlbuf, sizeof(lvlbuf), 5); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%d", &lvl); if (lvl == 0) { val->i = RIG_AGC_OFF; } else if (lvl == 2) { val->i = RIG_AGC_FAST; } else if (lvl == 4) { val->i = RIG_AGC_SLOW; } else { return -RIG_EPROTO; } break; case RIG_LEVEL_ATT: retval = kenwood_safe_transaction(rig, "RA", lvlbuf, sizeof(lvlbuf), 4); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%d", &lvl); if (lvl == 0) { val->i = 0; } else if (lvl == 1) { val->i = 10; } else { int i; for (i = 0; i < lvl && i < MAXDBLSTSIZ; i++) { if (rig->state.attenuator[i] == 0) { rig_debug(RIG_DEBUG_ERR, "%s: unexpected att level %d\n", __func__, lvl); return -RIG_EPROTO; } } if (i != lvl) { return -RIG_EINTERNAL; } val->i = rig->state.attenuator[i - 1]; } break; case RIG_LEVEL_MICGAIN: retval = kenwood_safe_transaction(rig, "MG", lvlbuf, sizeof(lvlbuf), 5); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%d", &lvl); val->f = (float) lvl / 60.0f; break; case RIG_LEVEL_COMP: retval = kenwood_safe_transaction(rig, "CP", lvlbuf, sizeof(lvlbuf), 5); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%d", &lvl); val->f = (float) lvl / 40.0f; break; case RIG_LEVEL_SQL: retval = kenwood_safe_transaction(rig, "SQ", lvlbuf, sizeof(lvlbuf), 5); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%d", &lvl); val->f = (float) lvl / 29.0f; break; case RIG_LEVEL_RF: retval = kenwood_safe_transaction(rig, "RG", lvlbuf, sizeof(lvlbuf), 5); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%d", &lvl); val->f = (float) lvl / 250.0f; break; case RIG_LEVEL_NR: return k3_get_nb_level(rig, &val->f, NULL); case RIG_LEVEL_MONITOR_GAIN: retval = kenwood_safe_transaction(rig, "ML", lvlbuf, sizeof(lvlbuf), 5); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%d", &lvl); val->f = (float) lvl / 60.0f; break; default: return kenwood_get_level(rig, vfo, level, val); } return RIG_OK; } int kx3_get_level(RIG *rig, vfo_t vfo, setting_t level, value_t *val) { switch (level) { case RIG_LEVEL_RFPOWER_METER: { int tx_status = 0; float pwr; // Return zero RF power when not in TX mode int retval = get_kenwood_func(rig, "TQ", &tx_status); if (retval != RIG_OK) { return retval; } if (!tx_status) { val->f = 0.0f; return RIG_OK; } retval = kx3_get_bar_graph_level(rig, &pwr); if (retval != RIG_OK) { return retval; } val->f = pwr; break; } default: return k3_get_level(rig, vfo, level, val); } return RIG_OK; } int k3_set_func(RIG *rig, vfo_t vfo, setting_t func, int status) { char buf[10]; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); switch (func) { case RIG_FUNC_APF: snprintf(buf, sizeof(buf), "AP%c", (status == 0) ? '0' : '1'); break; case RIG_FUNC_DUAL_WATCH: snprintf(buf, sizeof(buf), "SB%c", (status == 0) ? '0' : '1'); break; case RIG_FUNC_DIVERSITY: snprintf(buf, sizeof(buf), "DV%c", (status == 0) ? '0' : '1'); break; default: return kenwood_set_func(rig, vfo, func, status); } return kenwood_transaction(rig, buf, NULL, 0); } /* * Some functions, notably RIT and XIT On/Off status, can be queried * on the K3. Those functions are handled here and others are passed * through to kenwood_get_func(). */ int k3_get_func(RIG *rig, vfo_t vfo, setting_t func, int *status) { rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!status) { return -RIG_EINVAL; } switch (func) { case RIG_FUNC_RIT: return get_kenwood_func(rig, "RT", status); case RIG_FUNC_XIT: return get_kenwood_func(rig, "XT", status); case RIG_FUNC_APF: return get_kenwood_func(rig, "AP", status); case RIG_FUNC_DUAL_WATCH: return get_kenwood_func(rig, "SB", status); case RIG_FUNC_DIVERSITY: return get_kenwood_func(rig, "DV", status); default: return kenwood_get_func(rig, vfo, func, status); } } /* Private K3 helper functions */ /* * set_rit_xit() -- Differs from from generic Kenwood function as K3 can set * RIT/XIT to an arbitrary offset. When rit == 0, the RIT/XIT offset is * cleared. */ int set_rit_xit(RIG *rig, shortfreq_t rit) { int err; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (rit == 0) { /* Clear offset and return */ err = kenwood_transaction(rig, "RC", NULL, 0); if (err != RIG_OK) { return err; } return RIG_OK; } /* Set offset */ if (rit <= 9999 && rit >= -9999) { char cmd[16]; char offs; offs = (rit < 0) ? '-' : '+'; snprintf(cmd, 8, "RO%c%04d", offs, abs((int)rit)); err = kenwood_transaction(rig, cmd, NULL, 0); if (err != RIG_OK) { return err; } } else { return -RIG_EINVAL; } return RIG_OK; } int k3_set_nb_level(RIG *rig, float dsp_nb, float if_nb) { char lvlbuf[16]; int dsp_nb_raw = 0; int if_nb_raw = 0; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (dsp_nb >= 0) { dsp_nb_raw = (int)(dsp_nb * 21.0f); } if (if_nb >= 0) { if_nb_raw = (int)(if_nb * 21.0f); } if (dsp_nb < 0 || if_nb < 0) { int current_dsp_nb_raw; int current_if_nb_raw; int retval = kenwood_safe_transaction(rig, "NL", lvlbuf, sizeof(lvlbuf), 6); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%02d%02d", ¤t_dsp_nb_raw, ¤t_if_nb_raw); if (dsp_nb < 0) { dsp_nb_raw = current_dsp_nb_raw; } if (if_nb < 0) { if_nb_raw = current_if_nb_raw; } } snprintf(lvlbuf, sizeof(lvlbuf), "NL%02d%02d", dsp_nb_raw, if_nb_raw); return kenwood_transaction(rig, lvlbuf, NULL, 0); } int k3_get_nb_level(RIG *rig, float *dsp_nb, float *if_nb) { char lvlbuf[16]; int retval; int dsp_nb_raw; int if_nb_raw; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); retval = kenwood_safe_transaction(rig, "NL", lvlbuf, sizeof(lvlbuf), 6); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%02d%02d", &dsp_nb_raw, &if_nb_raw); if (dsp_nb != NULL) { *dsp_nb = (float) dsp_nb_raw / 21.0f; } if (if_nb != NULL) { *if_nb = (float) if_nb_raw / 21.0f; } return RIG_OK; } int k3_get_bar_graph_level(RIG *rig, float *smeter, float *pwr, float *alc, int *mode_tx) { char lvlbuf[16]; int retval; int tm_raw; int bg_raw; char mode; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); // Determine transmit metering mode: 0 = RF POWER, 1 = ALC retval = get_kenwood_func(rig, "TM", &tm_raw); if (retval != RIG_OK) { return retval; } retval = kenwood_safe_transaction(rig, "BG", lvlbuf, sizeof(lvlbuf), 5); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%02d%c", &bg_raw, &mode); if (mode == 'R') { // S-meter: nn is 00 - 21 (CWT off) or 00 - 09 (CWT on) if (smeter != NULL) { *smeter = (float) bg_raw / 21.0f; } if (pwr != NULL) { *pwr = -1; } if (alc != NULL) { *alc = -1; } } else if (mode == 'T') { if (tm_raw) { // ALC: nn is 00 - 07 if (alc != NULL) { *alc = (float) bg_raw / 7.0f; } if (pwr != NULL) { *pwr = -1; } if (smeter != NULL) { *smeter = -1; } } else { // PWR: nn is 00 - 12 if (pwr != NULL) { *pwr = (float) bg_raw / 12.0f; } if (alc != NULL) { *alc = -1; } if (smeter != NULL) { *smeter = -1; } } } else { return -RIG_EPROTO; } if (mode_tx != NULL) { *mode_tx = (mode == 'T'); } return RIG_OK; } int kx3_get_bar_graph_level(RIG *rig, float *level) { char lvlbuf[16]; int retval; int bg_raw; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); retval = kenwood_safe_transaction(rig, "BG", lvlbuf, sizeof(lvlbuf), 4); if (retval != RIG_OK) { return retval; } sscanf(lvlbuf + 2, "%02d", &bg_raw); if (bg_raw >= 0 && bg_raw <= 10) { if (level != NULL) { *level = (float) bg_raw / 10.0f; } } else if (bg_raw >= 12 && bg_raw <= 22) { if (level != NULL) { *level = (float)(bg_raw - 12) / 10.0f; } } else { return -RIG_EPROTO; } return RIG_OK; }