Basic xdot code to check how many memory is available for user APP after initializing libxdot lorawan stack
Diff: examples/src/peer_to_peer_example.cpp
- Revision:
- 21:09d05faf0e13
- Parent:
- 17:d4f82e16de5f
- Child:
- 22:d9bc10bbc433
diff -r 9ea0f3385ab3 -r 09d05faf0e13 examples/src/peer_to_peer_example.cpp --- a/examples/src/peer_to_peer_example.cpp Tue May 16 10:47:10 2017 -0500 +++ b/examples/src/peer_to_peer_example.cpp Fri Jun 09 08:31:21 2017 -0500 @@ -24,6 +24,7 @@ static uint8_t data_session_key[] = { 0x01, 0x02, 0x03, 0x04, 0x01, 0x02, 0x03, 0x04, 0x01, 0x02, 0x03, 0x04, 0x01, 0x02, 0x03, 0x04 }; mDot* dot = NULL; +lora::ChannelPlan* plan = NULL; Serial pc(USBTX, USBRX); @@ -46,7 +47,23 @@ mts::MTSLog::setLogLevel(mts::MTSLog::TRACE_LEVEL); - dot = mDot::getInstance(); +#if CHANNEL_PLAN == CP_US915 + plan = new lora::ChannelPlan_US915(); +#elif CHANNEL_PLAN == CP_AU915 + plan = new lora::ChannelPlan_AU915(); +#elif CHANNEL_PLAN == CP_EU868 + plan = new lora::ChannelPlan_EU868(); +#elif CHANNEL_PLAN == CP_KR920 + plan = new lora::ChannelPlan_KR920(); +#elif CHANNEL_PLAN == CP_AS923 + plan = new lora::ChannelPlan_AS923(); +#elif CHANNEL_PLAN == CP_AS923_JAPAN + plan = new lora::ChannelPlan_AS923_Japan(); +#endif + assert(plan); + + dot = mDot::getInstance(plan); + assert(dot); logInfo("mbed-os library version: %d", MBED_LIBRARY_VERSION); @@ -69,31 +86,58 @@ } frequency_band = dot->getFrequencyBand(); switch (frequency_band) { - case mDot::FB_EU868: + case lora::ChannelPlan::EU868_OLD: + case lora::ChannelPlan::EU868: // 250kHz channels achieve higher throughput - // DR6 : SF7 @ 250kHz - // DR0 - DR5 (125kHz channels) available but much slower + // DR_6 : SF7 @ 250kHz + // DR_0 - DR_5 (125kHz channels) available but much slower tx_frequency = 869850000; - tx_datarate = mDot::DR6; + tx_datarate = lora::DR_6; // the 869850000 frequency is 100% duty cycle if the total power is under 7 dBm - tx power 4 + antenna gain 3 = 7 tx_power = 4; break; - case mDot::FB_US915: - case mDot::FB_AU915: - default: + + case lora::ChannelPlan::US915_OLD: + case lora::ChannelPlan::US915: + case lora::ChannelPlan::AU915_OLD: + case lora::ChannelPlan::AU915: // 500kHz channels achieve highest throughput - // DR8 : SF12 @ 500kHz - // DR9 : SF11 @ 500kHz - // DR10 : SF10 @ 500kHz - // DR11 : SF9 @ 500kHz - // DR12 : SF8 @ 500kHz - // DR13 : SF7 @ 500kHz - // DR0 - DR3 (125kHz channels) available but much slower + // DR_8 : SF12 @ 500kHz + // DR_9 : SF11 @ 500kHz + // DR_10 : SF10 @ 500kHz + // DR_11 : SF9 @ 500kHz + // DR_12 : SF8 @ 500kHz + // DR_13 : SF7 @ 500kHz + // DR_0 - DR_3 (125kHz channels) available but much slower tx_frequency = 915500000; - tx_datarate = mDot::DR13; + tx_datarate = lora::DR_13; // 915 bands have no duty cycle restrictions, set tx power to max tx_power = 20; break; + + case lora::ChannelPlan::AS923: + case lora::ChannelPlan::AS923_JAPAN: + // 250kHz channels achieve higher throughput + // DR_6 : SF7 @ 250kHz + // DR_0 - DR_5 (125kHz channels) available but much slower + tx_frequency = 924800000; + tx_datarate = lora::DR_6; + tx_power = 16; + break; + + case lora::ChannelPlan::KR920: + // DR_5 : SF7 @ 125kHz + tx_frequency = 922700000; + tx_datarate = lora::DR_5; + tx_power = 14; + break; + + default: + while (true) { + logFatal("no known channel plan in use - extra configuration is needed!"); + wait(5); + } + break; } // in PEER_TO_PEER mode there is no join request/response transaction // as long as both Dots are configured correctly, they should be able to communicate