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mbed-os/features/lorawan/lorastack/phy/LoRaPHYKR920.cpp

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/**
* @file LoRaPHYKR920.cpp
*
* @brief Implements LoRaPHY for Korean 920 MHz band
*
* \code
* ______ _
* / _____) _ | |
* ( (____ _____ ____ _| |_ _____ ____| |__
* \____ \| ___ | (_ _) ___ |/ ___) _ \
* _____) ) ____| | | || |_| ____( (___| | | |
* (______/|_____)_|_|_| \__)_____)\____)_| |_|
* (C)2013 Semtech
* ___ _____ _ ___ _ _____ ___ ___ ___ ___
* / __|_ _/_\ / __| |/ / __/ _ \| _ \/ __| __|
* \__ \ | |/ _ \ (__| ' <| _| (_) | / (__| _|
* |___/ |_/_/ \_\___|_|\_\_| \___/|_|_\\___|___|
* embedded.connectivity.solutions===============
*
* \endcode
*
*
* License: Revised BSD License, see LICENSE.TXT file include in the project
*
* Maintainer: Miguel Luis ( Semtech ), Gregory Cristian ( Semtech ) and Daniel Jaeckle ( STACKFORCE )
*
* Copyright (c) 2017, Arm Limited and affiliates.
* SPDX-License-Identifier: BSD-3-Clause
*
*/
#include "LoRaPHYKR920.h"
#include "lora_phy_ds.h"
/*!
* Number of default channels
*/
#define KR920_NUMB_DEFAULT_CHANNELS 3
/*!
* Number of channels to apply for the CF list
*/
#define KR920_NUMB_CHANNELS_CF_LIST 5
/*!
* Minimal datarate that can be used by the node
*/
#define KR920_TX_MIN_DATARATE DR_0
/*!
* Maximal datarate that can be used by the node
*/
#define KR920_TX_MAX_DATARATE DR_5
/*!
* Minimal datarate that can be used by the node
*/
#define KR920_RX_MIN_DATARATE DR_0
/*!
* Maximal datarate that can be used by the node
*/
#define KR920_RX_MAX_DATARATE DR_5
/*!
* Default datarate used by the node
*/
#define KR920_DEFAULT_DATARATE DR_0
/*!
* Minimal Rx1 receive datarate offset
*/
#define KR920_MIN_RX1_DR_OFFSET 0
/*!
* Maximal Rx1 receive datarate offset
*/
#define KR920_MAX_RX1_DR_OFFSET 5
/*!
* Default Rx1 receive datarate offset
*/
#define KR920_DEFAULT_RX1_DR_OFFSET 0
/*!
* Minimal Tx output power that can be used by the node
*/
#define KR920_MIN_TX_POWER TX_POWER_7
/*!
* Maximal Tx output power that can be used by the node
*/
#define KR920_MAX_TX_POWER TX_POWER_0
/*!
* Default Tx output power used by the node
*/
#define KR920_DEFAULT_TX_POWER TX_POWER_0
/*!
* Default Max EIRP for frequency 920.9 MHz - 921.9 MHz
*/
#define KR920_DEFAULT_MAX_EIRP_LOW 10.0f
/*!
* Default Max EIRP for frequency 922.1 MHz - 923.3 MHz
*/
#define KR920_DEFAULT_MAX_EIRP_HIGH 14.0f
/*!
* Default antenna gain
*/
#define KR920_DEFAULT_ANTENNA_GAIN 2.15f
/*!
* ADR Ack limit
*/
#define KR920_ADR_ACK_LIMIT 64
/*!
* ADR Ack delay
*/
#define KR920_ADR_ACK_DELAY 32
/*!
* Enabled or disabled the duty cycle
*/
#define KR920_DUTY_CYCLE_ENABLED 0
/*!
* Maximum RX window duration
*/
#define KR920_MAX_RX_WINDOW 4000
/*!
* Receive delay 1
*/
#define KR920_RECEIVE_DELAY1 1000
/*!
* Receive delay 2
*/
#define KR920_RECEIVE_DELAY2 2000
/*!
* Join accept delay 1
*/
#define KR920_JOIN_ACCEPT_DELAY1 5000
/*!
* Join accept delay 2
*/
#define KR920_JOIN_ACCEPT_DELAY2 6000
/*!
* Maximum frame counter gap
*/
#define KR920_MAX_FCNT_GAP 16384
/*!
* Ack timeout
*/
#define KR920_ACKTIMEOUT 2000
/*!
* Random ack timeout limits
*/
#define KR920_ACK_TIMEOUT_RND 1000
#if ( KR920_DEFAULT_DATARATE > DR_5 )
#error "A default DR higher than DR_5 may lead to connectivity loss."
#endif
/*!
* Second reception window channel frequency definition.
*/
#define KR920_RX_WND_2_FREQ 921900000
/*!
* Second reception window channel datarate definition.
*/
#define KR920_RX_WND_2_DR DR_0
/*!
* Band 0 definition
* { DutyCycle, TxMaxPower, LastJoinTxDoneTime, LastTxDoneTime, TimeOff }
*/
static const band_t KR920_BAND0 = { 1, KR920_MAX_TX_POWER, 0, 0, 0 }; // 100.0 %
/*!
* LoRaMac default channel 1
* Channel = { Frequency [Hz], RX1 Frequency [Hz], { ( ( DrMax << 4 ) | DrMin ) }, Band }
*/
static const channel_params_t KR920_LC1 = { 922100000, 0, { ((DR_5 << 4) | DR_0) }, 0 };
/*!
* LoRaMac default channel 2
* Channel = { Frequency [Hz], RX1 Frequency [Hz], { ( ( DrMax << 4 ) | DrMin ) }, Band }
*/
static const channel_params_t KR920_LC2 = { 922300000, 0, { ((DR_5 << 4) | DR_0) }, 0 };
/*!
* LoRaMac default channel 3
* Channel = { Frequency [Hz], RX1 Frequency [Hz], { ( ( DrMax << 4 ) | DrMin ) }, Band }
*/
static const channel_params_t KR920_LC3 = { 922500000, 0, { ((DR_5 << 4) | DR_0) }, 0 };
/*!
* LoRaMac channels which are allowed for the join procedure
*/
#define KR920_JOIN_CHANNELS ( uint16_t )( LC( 1 ) | LC( 2 ) | LC( 3 ) )
/*!
* RSSI threshold for a free channel [dBm]
*/
#define KR920_RSSI_FREE_TH -65
/*!
* Specifies the time the node performs a carrier sense
*/
#define KR920_CARRIER_SENSE_TIME 6
/*!
* Data rates table definition
*/
static const uint8_t datarates_KR920[] = { 12, 11, 10, 9, 8, 7 };
/*!
* Bandwidths table definition in Hz
*/
static const uint32_t bandwidths_KR920[] = { 125000, 125000, 125000, 125000, 125000, 125000 };
/*!
* Maximum payload with respect to the datarate index. Can operate with and without a repeater.
*/
static const uint8_t max_payloads_KR920[] = { 51, 51, 51, 115, 242, 242 };
/*!
* Maximum payload with respect to the datarate index. Can operate with repeater.
*/
static const uint8_t max_payloads_with_repeater_KR920[] = { 51, 51, 51, 115, 222, 222 };
LoRaPHYKR920::LoRaPHYKR920()
{
bands[0] = KR920_BAND0;
// Channels
channels[0] = KR920_LC1;
channels[0].band = 0;
channels[1] = KR920_LC2;
channels[1].band = 0;
channels[2] = KR920_LC3;
channels[2].band = 0;
// Initialize the channels default mask
default_channel_mask[0] = LC(1) + LC(2) + LC(3);
// Update the channels mask
copy_channel_mask(channel_mask, default_channel_mask, KR920_CHANNEL_MASK_SIZE);
// set default channels
phy_params.channels.channel_list = channels;
phy_params.channels.channel_list_size = KR920_MAX_NB_CHANNELS;
phy_params.channels.mask = channel_mask;
phy_params.channels.default_mask = default_channel_mask;
phy_params.channels.mask_size = KR920_CHANNEL_MASK_SIZE;
// set bands for KR920 spectrum
phy_params.bands.table = (void *) bands;
phy_params.bands.size = KR920_MAX_NB_BANDS;
// set bandwidths available in KR920 spectrum
phy_params.bandwidths.table = (void *) bandwidths_KR920;
phy_params.bandwidths.size = 6;
// set data rates available in KR920 spectrum
phy_params.datarates.table = (void *) datarates_KR920;
phy_params.datarates.size = 6;
// set payload sizes with respect to data rates
phy_params.payloads.table = (void *) max_payloads_KR920;
phy_params.payloads.size = 6;
phy_params.payloads_with_repeater.table = (void *) max_payloads_with_repeater_KR920;
phy_params.payloads_with_repeater.size = 6;
// dwell time setting
phy_params.ul_dwell_time_setting = 0;
phy_params.dl_dwell_time_setting = 0;
// set initial and default parameters
phy_params.duty_cycle_enabled = KR920_DUTY_CYCLE_ENABLED;
phy_params.accept_tx_param_setup_req = false;
phy_params.fsk_supported = false;
phy_params.cflist_supported = true;
phy_params.dl_channel_req_supported = true;
phy_params.custom_channelplans_supported = true;
phy_params.default_channel_cnt = KR920_NUMB_DEFAULT_CHANNELS;
phy_params.max_channel_cnt = KR920_MAX_NB_CHANNELS;
phy_params.cflist_channel_cnt = KR920_NUMB_CHANNELS_CF_LIST;
phy_params.min_tx_datarate = KR920_TX_MIN_DATARATE;
phy_params.max_tx_datarate = KR920_TX_MAX_DATARATE;
phy_params.min_rx_datarate = KR920_RX_MIN_DATARATE;
phy_params.max_rx_datarate = KR920_RX_MAX_DATARATE;
phy_params.default_datarate = KR920_DEFAULT_DATARATE;
phy_params.default_max_datarate = KR920_TX_MAX_DATARATE;
phy_params.min_rx1_dr_offset = KR920_MIN_RX1_DR_OFFSET;
phy_params.max_rx1_dr_offset = KR920_MAX_RX1_DR_OFFSET;
phy_params.default_rx1_dr_offset = KR920_DEFAULT_RX1_DR_OFFSET;
phy_params.min_tx_power = KR920_MIN_TX_POWER;
phy_params.max_tx_power = KR920_MAX_TX_POWER;
phy_params.default_tx_power = KR920_DEFAULT_TX_POWER;
phy_params.default_max_eirp = KR920_DEFAULT_MAX_EIRP_HIGH;
phy_params.default_antenna_gain = KR920_DEFAULT_ANTENNA_GAIN;
phy_params.adr_ack_limit = KR920_ADR_ACK_LIMIT;
phy_params.adr_ack_delay = KR920_ADR_ACK_DELAY;
phy_params.max_rx_window = KR920_MAX_RX_WINDOW;
phy_params.recv_delay1 = KR920_RECEIVE_DELAY1;
phy_params.recv_delay2 = KR920_RECEIVE_DELAY2;
phy_params.join_channel_mask = KR920_JOIN_CHANNELS;
phy_params.join_accept_delay1 = KR920_JOIN_ACCEPT_DELAY1;
phy_params.join_accept_delay2 = KR920_JOIN_ACCEPT_DELAY2;
phy_params.max_fcnt_gap = KR920_MAX_FCNT_GAP;
phy_params.ack_timeout = KR920_ACKTIMEOUT;
phy_params.ack_timeout_rnd = KR920_ACK_TIMEOUT_RND;
phy_params.rx_window2_datarate = KR920_RX_WND_2_DR;
phy_params.rx_window2_frequency = KR920_RX_WND_2_FREQ;
}
LoRaPHYKR920::~LoRaPHYKR920()
{
}
int8_t LoRaPHYKR920::get_max_eirp(uint32_t freq)
{
if (freq >= 922100000) {// Limit to 14dBm
return KR920_DEFAULT_MAX_EIRP_HIGH;
}
// Limit to 10dBm
return KR920_DEFAULT_MAX_EIRP_LOW;
}
bool LoRaPHYKR920::verify_frequency_for_band(uint32_t freq, uint8_t band) const
{
uint32_t tmp_freq = freq;
_radio->lock();
if (_radio->check_rf_frequency(tmp_freq) == false) {
_radio->unlock();
return false;
}
_radio->unlock();
// Verify if the frequency is valid. The frequency must be in a specified
// range and can be set to specific values.
if ((tmp_freq >= 920900000) && (tmp_freq <= 923300000)) {
// Range ok, check for specific value
tmp_freq -= 920900000;
if ((tmp_freq % 200000) == 0) {
return true;
}
}
return false;
}
bool LoRaPHYKR920::tx_config(tx_config_params_t *config, int8_t *tx_power,
lorawan_time_t *tx_toa)
{
int8_t phy_dr = datarates_KR920[config->datarate];
if (config->tx_power > bands[channels[config->channel].band].max_tx_pwr) {
config->tx_power = bands[channels[config->channel].band].max_tx_pwr;
}
uint32_t bandwidth = get_bandwidth(config->datarate);
float max_eirp = get_max_eirp(channels[config->channel].frequency);
int8_t phy_tx_power = 0;
// Take the minimum between the max_eirp and txConfig->MaxEirp.
// The value of txConfig->MaxEirp could have changed during runtime, e.g. due to a MAC command.
max_eirp = MIN(config->max_eirp, max_eirp);
// Calculate physical TX power
phy_tx_power = compute_tx_power(config->tx_power, max_eirp, config->antenna_gain);
// Setup the radio frequency
_radio->lock();
_radio->set_channel(channels[config->channel].frequency);
_radio->set_tx_config(MODEM_LORA, phy_tx_power, 0, bandwidth, phy_dr, 1, 8,
false, true, 0, 0, false, 3000);
// Setup maximum payload lenght of the radio driver
_radio->set_max_payload_length(MODEM_LORA, config->pkt_len);
// Get the time-on-air of the next tx frame
*tx_toa = _radio->time_on_air(MODEM_LORA, config->pkt_len);
_radio->unlock();
*tx_power = config->tx_power;
return true;
}
lorawan_status_t LoRaPHYKR920::set_next_channel(channel_selection_params_t *params,
uint8_t *channel, lorawan_time_t *time,
lorawan_time_t *aggregate_timeoff)
{
uint8_t next_channel_idx = 0;
uint8_t nb_enabled_channels = 0;
uint8_t delay_tx = 0;
uint8_t enabled_channels[KR920_MAX_NB_CHANNELS] = {0};
lorawan_time_t nextTxDelay = 0;
if (num_active_channels(channel_mask, 0, 1) == 0) {
// Reactivate default channels
channel_mask[0] |= LC(1) + LC(2) + LC(3);
}
if (params->aggregate_timeoff <= _lora_time->get_elapsed_time(params->last_aggregate_tx_time)) {
// Reset Aggregated time off
*aggregate_timeoff = 0;
// Update bands Time OFF
nextTxDelay = update_band_timeoff(params->joined, params->dc_enabled,
bands, KR920_MAX_NB_BANDS);
// Search how many channels are enabled
nb_enabled_channels = enabled_channel_count(params->current_datarate,
channel_mask,
enabled_channels, &delay_tx);
} else {
delay_tx++;
nextTxDelay = params->aggregate_timeoff - _lora_time->get_elapsed_time(params->last_aggregate_tx_time);
}
if (nb_enabled_channels > 0) {
for (uint8_t i = 0, j = get_random(0, nb_enabled_channels - 1);
i < KR920_MAX_NB_CHANNELS; i++) {
next_channel_idx = enabled_channels[j];
j = (j + 1) % nb_enabled_channels;
// Perform carrier sense for KR920_CARRIER_SENSE_TIME
// If the channel is free, we can stop the LBT mechanism
_radio->lock();
if (_radio->perform_carrier_sense(MODEM_LORA,
channels[next_channel_idx].frequency,
KR920_RSSI_FREE_TH,
KR920_CARRIER_SENSE_TIME) == true) {
// Free channel found
*channel = next_channel_idx;
*time = 0;
_radio->unlock();
return LORAWAN_STATUS_OK;
}
_radio->unlock();
}
return LORAWAN_STATUS_NO_FREE_CHANNEL_FOUND;
} else {
if (delay_tx > 0) {
// Delay transmission due to AggregatedTimeOff or to a band time off
*time = nextTxDelay;
return LORAWAN_STATUS_DUTYCYCLE_RESTRICTED;
}
// Datarate not supported by any channel, restore defaults
channel_mask[0] |= LC(1) + LC(2) + LC(3);
*time = 0;
return LORAWAN_STATUS_NO_CHANNEL_FOUND;
}
}
void LoRaPHYKR920::set_tx_cont_mode(cw_mode_params_t *params, uint32_t given_frequency)
{
(void)given_frequency;
if (params->tx_power > bands[channels[params->channel].band].max_tx_pwr) {
params->tx_power = bands[channels[params->channel].band].max_tx_pwr;
}
float max_eirp = get_max_eirp(channels[params->channel].frequency);
int8_t phy_tx_power = 0;
uint32_t frequency = channels[params->channel].frequency;
// Take the minimum between the max_eirp and params->max_eirp.
// The value of params->max_eirp could have changed during runtime,
// e.g. due to a MAC command.
max_eirp = MIN(params->max_eirp, max_eirp);
// Calculate physical TX power
phy_tx_power = compute_tx_power(params->tx_power, max_eirp, params->antenna_gain);
_radio->lock();
_radio->set_tx_continuous_wave(frequency, phy_tx_power, params->timeout);
_radio->unlock();
}
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