lorawan_status_t LoRaPHYCN470::set_next_channel(channel_selection_params_t *params,
uint8_t *channel, lorawan_time_t *time,
lorawan_time_t *aggregate_timeoff)
{
uint8_t channel_count = 0;
uint8_t delay_tx = 0;
uint8_t enabled_channels[CN470_MAX_NB_CHANNELS] = {0};
lorawan_time_t next_tx_delay = 0;
band_t *band_table = (band_t *) phy_params.bands.table;
if (num_active_channels(phy_params.channels.mask, 0,
phy_params.channels.mask_size) == 0) {
// Reactivate default channels
copy_channel_mask(phy_params.channels.mask,
phy_params.channels.default_mask,
phy_params.channels.mask_size);
}
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
next_tx_delay = update_band_timeoff(params->joined,
params->dc_enabled,
band_table, phy_params.bands.size);
// Search how many channels are enabled
channel_count = enabled_channel_count(params->current_datarate,
phy_params.channels.mask,
enabled_channels, &delay_tx);
} else {
delay_tx++;
next_tx_delay = params->aggregate_timeoff -
_lora_time->get_elapsed_time(params->last_aggregate_tx_time);
}
if (channel_count > 0) {
// We found a valid channel
*channel = enabled_channels[get_random(0, channel_count - 1)];
*time = 0;
return LORAWAN_STATUS_OK;
}
if (delay_tx > 0) {
// Delay transmission due to AggregatedTimeOff or to a band time off
*time = next_tx_delay;
return LORAWAN_STATUS_DUTYCYCLE_RESTRICTED;
}
*time = 0;
return LORAWAN_STATUS_NO_CHANNEL_FOUND;
}
int8_t LoRaPHYUS915::limit_tx_power(int8_t tx_power, int8_t max_band_tx_power,
int8_t datarate)
{
int8_t tx_power_out = tx_power;
// Limit tx power to the band max
tx_power_out = MAX (tx_power, max_band_tx_power);
if (datarate == DR_4) {
// Limit tx power to max 26dBm
tx_power_out = MAX (tx_power, TX_POWER_2);
} else {
if (num_active_channels(channel_mask, 0, 4) < 50) {
// Limit tx power to max 21dBm
tx_power_out = MAX (tx_power, TX_POWER_5);
}
}
return tx_power_out;
}
bool LoRaPHYUS915::set_next_channel(channel_selection_params_t* params,
uint8_t* channel, lorawan_time_t* time,
lorawan_time_t* aggregate_timeOff)
{
uint8_t nb_enabled_channels = 0;
uint8_t delay_tx = 0;
uint8_t enabled_channels[US915_MAX_NB_CHANNELS] = {0};
lorawan_time_t next_tx_delay = 0;
// Count 125kHz channels
if (num_active_channels(current_channel_mask, 0, 4) == 0) {
// If none of the 125 kHz Upstream channel found,
// Reactivate default channels
copy_channel_mask(current_channel_mask, channel_mask, 4);
}
// Check other channels
if (params->current_datarate >= DR_4) {
if ((current_channel_mask[4] & 0x00FF ) == 0) {
current_channel_mask[4] = channel_mask[4];
}
}
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
next_tx_delay = update_band_timeoff(params->joined, params->dc_enabled, bands, US915_MAX_NB_BANDS);
// Search how many channels are enabled
nb_enabled_channels = enabled_channel_count(params->joined,
params->current_datarate,
current_channel_mask,
enabled_channels, &delay_tx);
} else {
delay_tx++;
next_tx_delay = params->aggregate_timeoff - _lora_time.get_elapsed_time(params->last_aggregate_tx_time);
}
if (nb_enabled_channels > 0) {
// We found a valid channel
*channel = enabled_channels[get_random( 0, nb_enabled_channels - 1 )];
// Disable the channel in the mask
disable_channel(current_channel_mask, *channel, US915_MAX_NB_CHANNELS - 8);
*time = 0;
return true;
} else {
if (delay_tx > 0) {
// Delay transmission due to AggregatedTimeOff or to a band time off
*time = next_tx_delay;
return true;
}
// Datarate not supported by any channel
*time = 0;
return false;
}
}
uint8_t LoRaPHYUS915::link_ADR_request(adr_req_params_t* params,
int8_t* dr_out, int8_t* tx_power_out,
uint8_t* nb_rep_out, uint8_t* nb_bytes_parsed)
{
uint8_t status = 0x07;
link_adr_params_t adr_settings;
uint8_t next_idx = 0;
uint8_t bytes_processed = 0;
uint16_t temp_channel_masks[US915_CHANNEL_MASK_SIZE] = {0, 0, 0, 0, 0};
verify_adr_params_t verify_params;
// Initialize local copy of channels mask
copy_channel_mask(temp_channel_masks, channel_mask, US915_CHANNEL_MASK_SIZE);
while (bytes_processed < params->payload_size) {
next_idx = parse_link_ADR_req(&(params->payload[bytes_processed]),
&adr_settings);
if (next_idx == 0) {
break; // break loop, since no more request has been found
}
// Update bytes processed
bytes_processed += next_idx;
// Revert status, as we only check the last ADR request for the channel mask KO
status = 0x07;
if (adr_settings.ch_mask_ctrl == 6) {
// Enable all 125 kHz channels
temp_channel_masks[0] = 0xFFFF;
temp_channel_masks[1] = 0xFFFF;
temp_channel_masks[2] = 0xFFFF;
temp_channel_masks[3] = 0xFFFF;
// Apply chMask to channels 64 to 71
temp_channel_masks[4] = adr_settings.channel_mask;
} else if (adr_settings.ch_mask_ctrl == 7) {
// Disable all 125 kHz channels
temp_channel_masks[0] = 0x0000;
temp_channel_masks[1] = 0x0000;
temp_channel_masks[2] = 0x0000;
temp_channel_masks[3] = 0x0000;
// Apply chMask to channels 64 to 71
temp_channel_masks[4] = adr_settings.channel_mask;
} else if (adr_settings.ch_mask_ctrl == 5) {
// RFU
status &= 0xFE; // Channel mask KO
} else {
temp_channel_masks[adr_settings.ch_mask_ctrl] = adr_settings.channel_mask;
}
}
// FCC 15.247 paragraph F mandates to hop on at least 2 125 kHz channels
if ((adr_settings.datarate < DR_4) &&
(num_active_channels(temp_channel_masks, 0, 4) < 2)) {
status &= 0xFE; // Channel mask KO
}
verify_params.status = status;
verify_params.adr_enabled = params->adr_enabled;
verify_params.datarate = adr_settings.datarate;
verify_params.tx_power = adr_settings.tx_power;
verify_params.nb_rep = adr_settings.nb_rep;
verify_params.current_datarate = params->current_datarate;
verify_params.current_tx_power = params->current_tx_power;
verify_params.current_nb_rep = params->current_nb_rep;
verify_params.channel_mask = temp_channel_masks;
// Verify the parameters and update, if necessary
status = verify_link_ADR_req(&verify_params, &adr_settings.datarate,
&adr_settings.tx_power, &adr_settings.nb_rep);
// Update channelsMask if everything is correct
if (status == 0x07) {
// Copy Mask
copy_channel_mask(channel_mask, temp_channel_masks, US915_CHANNEL_MASK_SIZE);
current_channel_mask[0] &= channel_mask[0];
current_channel_mask[1] &= channel_mask[1];
current_channel_mask[2] &= channel_mask[2];
current_channel_mask[3] &= channel_mask[3];
current_channel_mask[4] = channel_mask[4];
}
// Update status variables
*dr_out = adr_settings.datarate;
*tx_power_out = adr_settings.tx_power;
*nb_rep_out = adr_settings.nb_rep;
*nb_bytes_parsed = bytes_processed;
return status;
}
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;
}
}
bool LoRaPHYAS923::set_next_channel(channel_selection_params_t* next_channel_prams,
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[AS923_MAX_NB_CHANNELS] = { 0 };
lorawan_time_t next_tx_delay = 0;
if (num_active_channels(channel_mask, 0, 1) == 0) {
// Reactivate default channels
channel_mask[0] |= LC(1) + LC(2);
}
if (next_channel_prams->aggregate_timeoff <= _lora_time.get_elapsed_time(next_channel_prams->last_aggregate_tx_time)) {
// Reset Aggregated time off
*aggregate_timeoff = 0;
// Update bands Time OFF
next_tx_delay = update_band_timeoff(next_channel_prams->joined,
next_channel_prams->dc_enabled,
bands, AS923_MAX_NB_BANDS);
// Search how many channels are enabled
nb_enabled_channels = enabled_channel_count(next_channel_prams->joined,
next_channel_prams->current_datarate,
channel_mask,
enabled_channels, &delay_tx);
} else {
delay_tx++;
next_tx_delay = next_channel_prams->aggregate_timeoff - _lora_time.get_elapsed_time(next_channel_prams->last_aggregate_tx_time);
}
if (nb_enabled_channels > 0) {
_radio->lock();
for (uint8_t i = 0, j = get_random(0, nb_enabled_channels - 1); i < AS923_MAX_NB_CHANNELS; i++) {
next_channel_idx = enabled_channels[j];
j = ( j + 1 ) % nb_enabled_channels;
// Perform carrier sense for AS923_CARRIER_SENSE_TIME
// If the channel is free, we can stop the LBT mechanism
if (_radio->perform_carrier_sense(MODEM_LORA,
channels[next_channel_idx].frequency,
AS923_RSSI_FREE_TH,
AS923_CARRIER_SENSE_TIME) == true) {
// Free channel found
_radio->unlock();
*channel = next_channel_idx;
*time = 0;
return true;
}
}
_radio->unlock();
return false;
} else {
if (delay_tx > 0) {
// Delay transmission due to AggregatedTimeOff or to a band time off
*time = next_tx_delay;
return true;
}
// Datarate not supported by any channel, restore defaults
channel_mask[0] |= LC( 1 ) + LC( 2 );
*time = 0;
return false;
}
}
