💬 MySensors NRF5 Platform
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@d00616 ok, but the encryption for RF24 is also rather useless as it does not use initialization vectors. So the first part of the message (if the message is up to the encryption block size in size) will always yield the same cipher text and thus be predictable. But perhaps this hw handles that. I have not read up on it. I believe the rfm69 radio does since it states that the payload size decreases if encryption is enabled, suggesting that there is room reserved for syncing IV:s.
Nevertheless, encryption is not the key to security imo. Authentication is. Encryption gives obfuscation.
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@d00616, an impressive first post here in the community. Welcome!
Great job on porting the library to a new platform.
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BTW. Have you had any time reading up on frequency hopping and how much stay-away-windows affect battery consumption? How is the time synchronization handled between nodes?
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@d00616
very nice work
I've also some projects with nrf52832, and waiting for pcb i'll release soon. I'm using raytac modules, was very tempted to try to make my antenna too but for the moment i'm sticking with those modules. I've not tried range yet, what do you get?
Can't wait to get some 52840 modules.. (a bit expensive for the moment) because package need special pcb.
Regarding authentication, i have added signing ic (atsha204a i2c) on my boards in case..Thank you very much for your porting to Mysensors, that's awesome
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@Anticimex
The implemented encryption is in the same state like NRF24. I know about the IV(0) problem, but my first goal was the NRF24 compatibility.For an nRF5 only protocol, the hardware AES-CCM encryption can be used. At the moment, I have no plans to start with a new radio protocol. When I should start with, my idea is to use dynamic keys exchanged with micro-ecc. An IV based on a shared part the node id and a value from synchronized RTC.
Nevertheless, encryption is not the key to security imo. Authentication is. Encryption gives obfuscation.
I agree here.
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@hek said in
MySensors NRF5 Platform:BTW. Have you had any time reading up on frequency hopping and how much stay-away-windows affect battery consumption? How is the time synchronization handled between nodes?
The main problem of frequency hopping is finding the right time slot initially. I have no idea about a good way to implement this.
When I see the number of retransmits on my location, frequency hopping has no real benefit. What I interested is to use time slots for battery powered actors. The Gateway or Relay needs to cache packages and transmit it at the correct time. The node needs to listen at a specified time. When no data is transmitted the radio can be disabled after the time the address should send. To implement this Shortcuts and a bit counter is available. To use a low power mode to to this, the 32kHz crystal is required.
I use some of the functionality to disable the radio in the ESB mode when no ACK packet is received or after ACK is received.
To control this, the RTC trigger points needs to synchronized. Maybe with an protocol extension, but this needs access to the signing logic.
If you find out what is possible, there is an calculation tool for ANT+ protocol. https://www.thisisant.com/developer/components/developer
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@scalz said in
MySensors NRF5 Platform:I'm using raytac modules, was very tempted to try to make my antenna too but for the moment i'm sticking with those modules. I've not tried range yet, what do you get?
I haven't measured the range yet.
Can't wait to get some 52840 modules.. (a bit expensive for the moment) because package need special pcb.
I think the final nRF82840 isn't launched yet.
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@d00616 yes I agree that protocol compatibility is priority. I just wanted to point out the current flaws with that encryption but you obviously know what you are doing
Best would be to come up with a solution that was radio agnostic, but for me encryption is not worth spending too much effort on. I'd say it's obscure enough as it is. Combined with signing, I think people will have a hard time breaking into it.
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@d00616
oki. i'll try to do some range tests, and your PR too! when i'll get more time
Would be nice if they would release a better package footprint for the 840..I said this because i've seen Fanstel is selling modules but not so cheap, so i prefer to wait a bit.
And i agree with you the 832 is already very nice, even if 840 has some nice feature.
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@Anticimex said in
MySensors NRF5 Platform:Best would be to come up with a solution that was radio agnostic, but for me encryption is not worth spending too much effort on. I'd say it's obscure enough as it is. Combined with signing, I think people will have a hard time breaking into it.
What do you think about switching signing and encryption to AES-CCM? AES-CCM is part BLE(AES-CCM) and ZigBee(AES-CCM*) specification and available as hardware unit in NRF5 and other MCU. With AES132A a coprocessor is available.
AES-CCM provides encryption and authentication. With AES-CCM the SHA code can be removed. http://infocenter.nordicsemi.com/index.jsp?topic=%2Fcom.nordic.infocenter.nrf52832.ps.v1.1%2Fccm.html&cp=2_2_0_28&anchor=topic
My thesis needs testing; I think AES-CCM on an AVR is faster than AES-CBC with SHA signing in Hardware and requires transmitting less data than the actual signing implementation.
I don't know something about the code size of AVR projects. When 8k are available, it's possible to store a unique AES-128 key per node in 4k. For AES key updates, a second 4k page is required.
The keys can be managed with the VirtualPage class: https://github.com/d00616/MySensors/blob/add_nrf5_platform/drivers/NVM/VirtualPage.h
For key exchange a library like micro-ecc is available. A device can authenticated with an preshared secret.
The IV can be built by the node ID and a counter incremented with every packet and a global distributed timestamp.
The counter can be stored in EEPROM after ~1000 packages and is rounded up to next 1000 after a reboot of a node.
If a node counter reaches the end, a new AES-Key is generated and distributed by the gateway.
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@d00616 I don't see how this relate to the signing solution we use. We use HMAC-SHA256. We already have hw support for this in the atsha204a. There is no plan to replace this.
Encryption is also already existing in certain radios already (like the rfm69). So it will in a sense always be radio specific and needs to be in order to be effective.
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@Anticimex Ok.
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@d00616 I don't however see it as a problem if you implement some underlying security solution specific to nrf5 as long as it don't require protocol "awareness". That's just a bonus so feel free to have a look at that. But things will quite fast become quite messy if we start mixing security schemes in the protocol.
The signing backend does have versioning support so it is possible to extend it with new schemes, but so far the scheme we use is supported across all radio variants and it would be a pity to give up that compatibility unless the new scheme offer some improvement over the current one.
The main drawback with the current one is the message size limitation imposed by the current protocol version which forces us to truncate the signatures but in version 3 of the MySensors protocol, this limitation will be overcome by protocol upgrades.
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@Anticimex At the moment I have other priorities than implementing another security solution or protocol for NRF5. Another protocol can be implemented as a second radio driver including breaking the NRF24 compatibility with larger packet sizes and protocol optimization.
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@d00616 with v3 the protocol backwards compatibility will be broken nevertheless in a way which will support the current generic security protocol fully across all radio transports.
But there are basically two layers. A mysensors layer where signing is handled using HMAC-SHA256 with nonce exchange, timeouts, lock detection and whitelisting. A rf specific layer can implement additional security solutions (typically encryption) that work transparently with the MySensors protocol. For signing, it is probably not needed as we already have that in place, but encryption could be a relevant feature for the lower level layers.
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Hi,
This is a such great addition for this project. For long time I wanted something like this: a RF SOC with pretty good and usable software support and low power also(and a Cortex arch - pff..that's too much :simple_smile: ). I just wanted to congratulate you for your work and bringing this in to MySensors project - it's very neat and useful.
I tested it and it works just great so far. I would give you 100 likes on openhardware.io if it would be possible :simple_smile: . Thanks once again for your effort.
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@mtiutiu Thank you very much. I like to read your words. Have fun with this port.
I have started 2014 to work on Sensors based on the nRF51 chips. At this time the MCU was well documented, but Software was only available under an NDA. Without luck, I tried to build a free Arduino version based on RFduino. There are problems with my linker scripts.
My next attempt was to use RIOT OS as the base for my Sensor project. Later I have found the great MySensors project. I have started to extend the RIOT Arduino layer to let MySensors running. On my research, I found the Arduino port of Sandeep Mistry (thank you!), so it was easier for me add the missing functionality to MySensors and arduino-nrf5 instead to RIOT OS. From this point, I required eight months to a functional MySensors port.
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Congratulations on winning the contest. That convinces me to give it a try.
Even though this has been available for months, I'm not seeing much discussion on:- Improvements on range.
- The best module to purchase for the simplest nodes - like temperature.
- Battery performance.
Anyone have feedback on those yet?
Thanks ahead of time
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@ileneken3
I'm having some fun with @d00616 work And it's working fine so far (thx again).I have not tested battery performance for the moment.. NRF52 is capable of very low power but i think the low power is not enabled yet in the porting, it's explained in the project prez if i remember
Regarding range, sure NRF52 is an improved chip compared to NRF24 for instance, but the most important part is the antenna. That's the case for all mcu though. Take a long range capable mcu and a bad antenna choice, or a bad antenna design (bad gnd plane, bad clearance for antenna etc) and you'll never get the long range (example: miniaturized chip antenna, or some pcb antennas too).
For the simplest devices to buy, no idea as i'm making custom boards.
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@ileneken3 Thank you.
Like @scalz has written, the range depending mostly on the antenna. With the same antenna the nRF52 series are more efficient.
If you need a simple module to start with, a RedBear BLE Nano 2 or Nano is a good module. It's a small module with integrated voltage regulator and 2.54mm pins. This module is available in the second generation with compatible pin layout.
If you need an cheap module, there are some starting at 3-6€ with an nRF51. I don't know how long these modules are sold. If possible, use nRF52 based modules. The nRF52 is faster (https://github.com/mysensors/MySensors/pull/845), more flexible and less current consuming then nRF51. The interrupt vector of the nRF52 can be moved into RAM. This reduces the interrupt latency and allows to implement OTA updates in an simple way.
Most peripherals (e.g. expect ADC) can be assigned to any IO pin. So you can change the role in arduinos board definition.
You can find detailed information about the current consumption in the datasheets. The MySensors sleep function consumes 3µA until you want to wait for an Interrupt (1mA). To fix this cores/nRF5/WInterrupts.c needs an partitial rewrite. I have no time at the moment to fix this issue. The discussion about how to fix is sleeping: https://github.com/sandeepmistry/arduino-nRF5/issues/153
Another point to save some energy is to manage the DCDC converter (not available on all boards) in the radio or sleep code. -> https://devzone.nordicsemi.com/question/685/ldo-vs-dcdc-nrf51822/
More energy savings, requires breaking the compatibility to NRF24 radios and implementing an additional communication protocol. This allows to implement battery powered nodes which can receive packages.
When issue 153 is fixed, I think the nRF5 platform is a good choice to start new developments of sensors without the CPU and memory limitations of ATMEGA or maybe in the future the limitations of NRF24 radio. When its not fixed this is a good platform for main powered components and sensors which are only waking up by time.
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@scalz said in
MySensors NRF5 Platform:I have not tested battery performance for the moment.. NRF52 is capable of very low power but i think the low power is not enabled yet in the porting, it's explained in the project prez if i remember
Low power in implemented at the MySensors side. There is an issue at the Arduino side ->
MySensors NRF5 PlatformEdit: The radio is saving power in some states. There is a little room for improvments like fast rampup for nRF52. With an NRF24 incompatible protocol there is room for improvements.
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@d00616 I found the current issue is a problem only with older nRF51 hardware. I can't measure the current on with newer nRF51 or nRF52 chips. But a fix is documented in http://infocenter.nordicsemi.com/pdf/nRF51822-pan_v3.0.pdf (s. PAN #39)
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@d00616 thx for the info
I'll try to measure power consumption asap
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FWIW, you may want to delete this passage in your overview, as it's not really accurate:
Don't buy an nRF5 development kit to program other nRF5 modules. The programmer is hard wired to the nRF5 chip on most DK boards.In fact, Nordic has this video that I just now came across on how to do it:
https://www.youtube.com/watch?v=n6sNDnRA6BYIMHO, I think the DK is a good way for noobs to get started, because the setup is well supported for the onboard nRF52 and "just works." The fact that it can later be used to program external nRF5 devices is a nice (and very poorly advertised) bonus. The DK has a real Segger J-Link on the DK board.
That being said, the DK is not the cheapest option, so noobs may need to weigh "easy" vs "cheap" in their purchase decision.
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I am having problems compiling the Mockmysensors example on the waveshare board.
If you comment out all sensors and uncomment
#define ID_S_MULTIMETER 28I get the following error:
exit status 1
call of overloaded 'set(int&)' is ambiguous
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@rmtucker said in
MySensors NRF5 Platform:I am having problems compiling the Mockmysensors example on the waveshare board.
If you comment out all sensors and uncomment
#define ID_S_MULTIMETER 28I get the following error:
exit status 1
call of overloaded 'set(int&)' is ambiguousDid you remember to do this?
// Enable and select radio type attached //#define MY_RADIO_NRF24 #define MY_RADIO_NRF5_ESB
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@NeverDie
Yes did that.
Strange though if you run the sketch with just the first 2 sensors uncommented it compiles fine.
It must me something to do with multimeter?
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At least on my system, if I don't uncomment anything (other than the passage I just indicated), it at least compiles. Haven't actually tried to see if it works yet....
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Well, I just tried what you queried about, and it compiles fine on my system:
/* * MockMySensors * * This skecth is intended to crate fake sensors which register and respond to the controller * *** * Barduino 2015, GizMoCuz 2015 */ // Enable debug prints to serial monitor #define MY_DEBUG // Enable and select radio type attached //#define MY_RADIO_NRF24 #define MY_RADIO_NRF5_ESB //#define MY_RADIO_RFM69 //#define MY_RADIO_RFM95 #define MY_NODE_ID 254 #include <MySensors.h> #define RADIO_ERROR_LED_PIN 4 // Error led pin #define RADIO_RX_LED_PIN 6 // Receive led pin #define RADIO_TX_LED_PIN 5 // the PCB, on board LED // Wait times #define LONG_WAIT 500 #define SHORT_WAIT 50 #define SKETCH_NAME "MockMySensors " #define SKETCH_VERSION "v0.5" // Define Sensors ids /* S_DOOR, S_MOTION, S_SMOKE, S_LIGHT, S_DIMMER, S_COVER, S_TEMP, S_HUM, S_BARO, S_WIND, S_RAIN, S_UV, S_WEIGHT, S_POWER, S_HEATER, S_DISTANCE, S_LIGHT_LEVEL, S_ARDUINO_NODE, S_ARDUINO_REPEATER_NODE, S_LOCK, S_IR, S_WATER, S_AIR_QUALITY, S_CUSTOM, S_DUST, S_SCENE_CONTROLLER */ ////#define ID_S_ARDUINO_NODE //auto defined in initialization ////#define ID_S_ARDUINO_REPEATER_NODE //auto defined in initialization // Some of these ID's have not been updated for v1.5. Uncommenting too many of them // will make the sketch too large for a pro mini's memory so it's probably best to try // one at a time. //#define ID_S_ARMED 0 // dummy to controll armed stated for several sensors //#define ID_S_DOOR 1 //#define ID_S_MOTION 2 //#define ID_S_SMOKE 3 //#define ID_S_LIGHT 4 //#define ID_S_DIMMER 5 //#define ID_S_COVER 6 //#define ID_S_TEMP 7 //#define ID_S_HUM 8 //#define ID_S_BARO 9 //#define ID_S_WIND 10 //#define ID_S_RAIN 11 //#define ID_S_UV 12 //#define ID_S_WEIGHT 13 //#define ID_S_POWER 14 //#define ID_S_HEATER 15 //#define ID_S_DISTANCE 16 //#define ID_S_LIGHT_LEVEL 17 //#define ID_S_LOCK 18 //#define ID_S_IR 19 //#define ID_S_WATER 20 //#define ID_S_AIR_QUALITY 21 //#define ID_S_DUST 22 //#define ID_S_SCENE_CONTROLLER 23 //// Lib 1.5 sensors //#define ID_S_RGB_LIGHT 24 //#define ID_S_RGBW_LIGHT 25 //#define ID_S_COLOR_SENSOR 26 //#define ID_S_HVAC 27 //#define ID_S_MULTIMETER 28 #define ID_S_SPRINKLER 29 //#define ID_S_WATER_LEAK 30 //#define ID_S_SOUND 31 //#define ID_S_VIBRATION 32 //#define ID_S_MOISTURE 33 // //#define ID_S_CUSTOM 99 // Global Vars unsigned long SLEEP_TIME = 900000; // Sleep time between reads (in milliseconds) bool metric = true; long randNumber; //Instanciate Messages objects #ifdef ID_S_ARMED bool isArmed; #endif #ifdef ID_S_DOOR // V_TRIPPED, V_ARMED MyMessage msg_S_DOOR_T(ID_S_DOOR,V_TRIPPED); MyMessage msg_S_DOOR_A(ID_S_DOOR,V_ARMED); #endif #ifdef ID_S_MOTION // V_TRIPPED, V_ARMED MyMessage msg_S_MOTION_A(ID_S_MOTION,V_ARMED); MyMessage msg_S_MOTION_T(ID_S_MOTION,V_TRIPPED); #endif #ifdef ID_S_SMOKE // V_TRIPPED, V_ARMED MyMessage msg_S_SMOKE_T(ID_S_SMOKE,V_TRIPPED); MyMessage msg_S_SMOKE_A(ID_S_SMOKE,V_ARMED); #endif #ifdef ID_S_LIGHT MyMessage msg_S_LIGHT(ID_S_LIGHT,V_LIGHT); bool isLightOn=0; #endif #ifdef ID_S_DIMMER MyMessage msg_S_DIMMER(ID_S_DIMMER,V_DIMMER); int dimmerVal=100; #endif #ifdef ID_S_COVER MyMessage msg_S_COVER_U(ID_S_COVER,V_UP); MyMessage msg_S_COVER_D(ID_S_COVER,V_DOWN); MyMessage msg_S_COVER_S(ID_S_COVER,V_STOP); MyMessage msg_S_COVER_V(ID_S_COVER,V_VAR1); int coverState=0; //0=Stop; 1=up; -1=down #endif #ifdef ID_S_TEMP MyMessage msg_S_TEMP(ID_S_TEMP,V_TEMP); #endif #ifdef ID_S_HUM MyMessage msg_S_HUM(ID_S_HUM,V_HUM); #endif #ifdef ID_S_BARO MyMessage msg_S_BARO_P(ID_S_BARO,V_PRESSURE); MyMessage msg_S_BARO_F(ID_S_BARO,V_FORECAST); #endif #ifdef ID_S_WIND MyMessage msg_S_WIND_S(ID_S_WIND,V_WIND); MyMessage msg_S_WIND_G(ID_S_WIND,V_GUST); MyMessage msg_S_WIND_D(ID_S_WIND,V_DIRECTION); #endif #ifdef ID_S_RAIN MyMessage msg_S_RAIN_A(ID_S_RAIN,V_RAIN); MyMessage msg_S_RAIN_R(ID_S_RAIN,V_RAINRATE); #endif #ifdef ID_S_UV MyMessage msg_S_UV(ID_S_UV,V_UV); #endif #ifdef ID_S_WEIGHT MyMessage msg_S_WEIGHT(ID_S_WEIGHT,V_WEIGHT); #endif #ifdef ID_S_POWER MyMessage msg_S_POWER_W(ID_S_POWER,V_WATT); MyMessage msg_S_POWER_K(ID_S_POWER,V_KWH); #endif #ifdef ID_S_HEATER //////// REVIEW IMPLEMENTATION //////////// MyMessage msg_S_HEATER_SET_POINT(ID_S_HEATER, V_HVAC_SETPOINT_HEAT); // HVAC/Heater setpoint (Integer between 0-100). S_HEATER, S_HVAC MyMessage msg_S_HEATER_FLOW_STATE(ID_S_HEATER, V_HVAC_FLOW_STATE); // Mode of header. One of "Off", "HeatOn", "CoolOn", or "AutoChangeOver" // S_HVAC, S_HEATER //MyMessage msg_S_HEATER_STATUS(ID_S_HEATER,V_STATUS); //MyMessage msg_S_HEATER_TEMP(ID_S_HEATER,V_TEMP); float heater_setpoint=21.5; String heater_flow_state="Off"; // float heater_temp=23.5; // bool heater_status=false; // V_TEMP // Temperature // V_STATUS // Binary status. 0=off 1=on // V_HVAC_FLOW_STATE // Mode of header. One of "Off", "HeatOn", "CoolOn", or "AutoChangeOver" // V_HVAC_SPEED // HVAC/Heater fan speed ("Min", "Normal", "Max", "Auto") // V_HVAC_SETPOINT_HEAT // HVAC/Heater setpoint #endif #ifdef ID_S_DISTANCE MyMessage msg_S_DISTANCE(ID_S_DISTANCE,V_DISTANCE); #endif #ifdef ID_S_LIGHT_LEVEL MyMessage msg_S_LIGHT_LEVEL(ID_S_LIGHT_LEVEL,V_LIGHT_LEVEL); #endif #ifdef ID_S_LOCK MyMessage msg_S_LOCK(ID_S_LOCK,V_LOCK_STATUS); bool isLocked = 0; #endif #ifdef ID_S_IR MyMessage msg_S_IR_S(ID_S_IR,V_IR_SEND); MyMessage msg_S_IR_R(ID_S_IR,V_IR_RECEIVE); long irVal = 0; #endif #ifdef ID_S_WATER MyMessage msg_S_WATER_F(ID_S_WATER,V_FLOW); MyMessage msg_S_WATER_V(ID_S_WATER,V_VOLUME); #endif #ifdef ID_S_AIR_QUALITY MyMessage msg_S_AIR_QUALITY(ID_S_AIR_QUALITY,V_LEVEL); #endif #ifdef ID_S_DUST MyMessage msg_S_DUST(ID_S_DUST,V_LEVEL); #endif #ifdef ID_S_SCENE_CONTROLLER MyMessage msg_S_SCENE_CONTROLLER_ON(ID_S_SCENE_CONTROLLER,V_SCENE_ON); MyMessage msg_S_SCENE_CONTROLLER_OF(ID_S_SCENE_CONTROLLER,V_SCENE_OFF); // not sure if scene controller sends int or chars // betting on ints as Touch Display Scen by Hek // compiler warnings char *scenes[] = { (char *)"Good Morning", (char *)"Clean Up!", (char *)"All Lights Off", (char *)"Music On/Off" }; int sceneVal=0; int sceneValPrevious=0; #endif #ifdef ID_S_RGB_LIGHT MyMessage msg_S_RGB_LIGHT_V_RGB(ID_S_RGB_LIGHT,V_RGB); MyMessage msg_S_RGB_LIGHT_V_WATT(ID_S_RGB_LIGHT,V_WATT); String rgbState="000000"; //RGB light V_RGB, V_WATT //RGB value transmitted as ASCII hex string (I.e "ff0000" for red) #endif #ifdef ID_S_RGBW_LIGHT MyMessage msg_S_RGBW_LIGHT_V_RGBW(ID_S_RGBW_LIGHT,V_RGBW); MyMessage msg_S_RGBW_LIGHT_V_WATT(ID_S_RGBW_LIGHT,V_WATT); String rgbwState="00000000"; //RGBW light (with separate white component) V_RGBW, V_WATT //RGBW value transmitted as ASCII hex string (I.e "ff0000ff" for red + full white) S_RGBW_LIGHT #endif #ifdef ID_S_COLOR_SENSOR MyMessage msg_S_COLOR_SENSOR_V_RGB(ID_S_COLOR_SENSOR,V_RGB); //Color sensor V_RGB //RGB value transmitted as ASCII hex string (I.e "ff0000" for red) S_RGB_LIGHT, S_COLOR_SENSOR #endif #ifdef ID_S_HVAC MyMessage msg_S_HVAC_V_HVAC_SETPOINT_HEAT(ID_S_HVAC,V_HVAC_SETPOINT_HEAT); MyMessage msg_S_HVAC_V_HVAC_SETPOINT_COOL(ID_S_HVAC,V_HVAC_SETPOINT_COOL); MyMessage msg_S_HVAC_V_HVAC_FLOW_STATET(ID_S_HVAC,V_HVAC_FLOW_STATE); MyMessage msg_S_HVAC_V_HVAC_FLOW_MODE(ID_S_HVAC,V_HVAC_FLOW_MODE); MyMessage msg_S_HVAC_V_HVAC_SPEED(ID_S_HVAC,V_HVAC_SPEED); float hvac_SetPointHeat = 16.5; float hvac_SetPointCool = 25.5; String hvac_FlowState = "AutoChangeOver"; String hvac_FlowMode = "Auto"; String hvac_Speed = "Normal"; //Thermostat/HVAC device //V_HVAC_SETPOINT_HEAT, // HVAC/Heater setpoint //V_HVAC_SETPOINT_COOL, // HVAC cold setpoint //V_HVAC_FLOW_STATE, // Mode of header. One of "Off", "HeatOn", "CoolOn", or "AutoChangeOver" //V_HVAC_FLOW_MODE, // Flow mode for HVAC ("Auto", "ContinuousOn", "PeriodicOn") //V_HVAC_SPEED // HVAC/Heater fan speed ("Min", "Normal", "Max", "Auto") // NOT IMPLEMENTED YET //V_TEMP // Temperature //V_STATUS // Binary status. 0=off 1=on #endif #ifdef ID_S_MULTIMETER MyMessage msg_S_MULTIMETER_V_IMPEDANCE(ID_S_MULTIMETER,V_IMPEDANCE); MyMessage msg_S_MULTIMETER_V_VOLTAGE(ID_S_MULTIMETER,V_VOLTAGE); MyMessage msg_S_MULTIMETER_V_CURRENT(ID_S_MULTIMETER,V_CURRENT); // Multimeter device V_VOLTAGE, V_CURRENT, V_IMPEDANCE // V_IMPEDANCE 14 Impedance value // V_VOLTAGE 38 Voltage level // V_CURRENT 39 Current level #endif #ifdef ID_S_SPRINKLER // S_SPRINKLER 31 Sprinkler device V_STATUS (turn on/off), V_TRIPPED (if fire detecting device) // V_STATUS 2 Binary status. 0=off 1=on // V_ARMED 15 Armed status of a security sensor. 1=Armed, 0=Bypassed // V_TRIPPED 16 Tripped status of a security sensor. 1=Tripped, 0=Untripped #endif #ifdef ID_S_WATER_LEAK #endif #ifdef ID_S_SOUND #endif #ifdef ID_S_VIBRATION #endif #ifdef ID_S_MOISTURE #endif #ifdef ID_S_MOISTURE MyMessage msg_S_MOISTURE(ID_S_MOISTURE,V_LEVEL); #endif #ifdef ID_S_CUSTOM MyMessage msg_S_CUSTOM_1(ID_S_CUSTOM,V_VAR1); MyMessage msg_S_CUSTOM_2(ID_S_CUSTOM,V_VAR2); MyMessage msg_S_CUSTOM_3(ID_S_CUSTOM,V_VAR3); MyMessage msg_S_CUSTOM_4(ID_S_CUSTOM,V_VAR4); MyMessage msg_S_CUSTOM_5(ID_S_CUSTOM,V_VAR5); #endif void setup() { // Random SEED randomSeed(analogRead(0)); wait(LONG_WAIT); Serial.println("GW Started"); } void presentation() { // Send the Sketch Version Information to the Gateway Serial.print("Send Sketch Info: "); sendSketchInfo(SKETCH_NAME, SKETCH_VERSION); Serial.print(SKETCH_NAME); Serial.println(SKETCH_VERSION); wait(LONG_WAIT); // Get controller configuration Serial.print("Get Config: "); metric = getControllerConfig().isMetric; Serial.println(metric ? "Metric":"Imperial"); wait(LONG_WAIT); // Init Armed #ifdef ID_S_ARMED isArmed = true; #endif // Register all sensors to gw (they will be created as child devices) Serial.println("Presenting Nodes"); Serial.println("________________"); #ifdef ID_S_DOOR Serial.println(" S_DOOR"); present(ID_S_DOOR,S_DOOR,"Outside Door"); wait(SHORT_WAIT); #endif #ifdef ID_S_MOTION Serial.println(" S_MOTION"); present(ID_S_MOTION,S_MOTION,"Outside Motion"); wait(SHORT_WAIT); #endif #ifdef ID_S_SMOKE Serial.println(" S_SMOKE"); present(ID_S_SMOKE,S_SMOKE,"Kitchen Smoke"); wait(SHORT_WAIT); #endif #ifdef ID_S_LIGHT Serial.println(" S_LIGHT"); present(ID_S_LIGHT,S_LIGHT,"Hall Light"); wait(SHORT_WAIT); #endif #ifdef ID_S_DIMMER Serial.println(" S_DIMMER"); present(ID_S_DIMMER,S_DIMMER,"Living room dimmer"); wait(SHORT_WAIT); #endif #ifdef ID_S_COVER Serial.println(" S_COVER"); present(ID_S_COVER,S_COVER,"Window cover"); wait(SHORT_WAIT); #endif #ifdef ID_S_TEMP Serial.println(" S_TEMP"); present(ID_S_TEMP,S_TEMP,"House Temperarue"); wait(SHORT_WAIT); #endif #ifdef ID_S_HUM Serial.println(" S_HUM"); present(ID_S_HUM,S_HUM,"Current Humidity"); wait(SHORT_WAIT); #endif #ifdef ID_S_BARO Serial.println(" S_BARO"); present(ID_S_BARO,S_BARO," Air pressure"); wait(SHORT_WAIT); #endif #ifdef ID_S_WIND Serial.println(" S_WIND"); present(ID_S_WIND,S_WIND,"Wind Station"); wait(SHORT_WAIT); #endif #ifdef ID_S_RAIN Serial.println(" S_RAIN"); present(ID_S_RAIN,S_RAIN,"Rain Station"); wait(SHORT_WAIT); #endif #ifdef ID_S_UV Serial.println(" S_UV"); present(ID_S_UV,S_UV,"Ultra Violet"); wait(SHORT_WAIT); #endif #ifdef ID_S_WEIGHT Serial.println(" S_WEIGHT"); present(ID_S_WEIGHT,S_WEIGHT,"Outdoor Scale"); wait(SHORT_WAIT); #endif #ifdef ID_S_POWER Serial.println(" S_POWER"); present(ID_S_POWER,S_POWER,"Power Metric"); wait(SHORT_WAIT); #endif #ifdef ID_S_HEATER Serial.println(" S_HEATER"); present(ID_S_HEATER,S_HEATER,"Garage Heater"); wait(SHORT_WAIT); #endif #ifdef ID_S_DISTANCE Serial.println(" S_DISTANCE"); present(ID_S_DISTANCE,S_DISTANCE,"Distance Measure"); wait(SHORT_WAIT); #endif #ifdef ID_S_LIGHT_LEVEL Serial.println(" S_LIGHT_LEVEL"); present(ID_S_LIGHT_LEVEL,S_LIGHT_LEVEL,"Outside Light Level"); wait(SHORT_WAIT); #endif #ifdef ID_S_LOCK Serial.println(" S_LOCK"); present(ID_S_LOCK,S_LOCK,"Front Door Lock"); wait(SHORT_WAIT); #endif #ifdef ID_S_IR Serial.println(" S_IR"); present(ID_S_IR,S_IR,"Univeral Command"); wait(SHORT_WAIT); #endif #ifdef ID_S_WATER Serial.println(" S_WATER"); present(ID_S_WATER,S_WATER,"Water Level"); wait(SHORT_WAIT); #endif #ifdef ID_S_AIR_QUALITY Serial.println(" S_AIR_QUALITY"); present(ID_S_AIR_QUALITY,S_AIR_QUALITY,"Air Station"); wait(SHORT_WAIT); #endif #ifdef ID_S_DUST Serial.println(" S_DUST"); present(ID_S_DUST,S_DUST,"Dust Level"); wait(SHORT_WAIT); #endif #ifdef ID_S_SCENE_CONTROLLER Serial.println(" S_SCENE_CONTROLLER"); present(ID_S_SCENE_CONTROLLER,S_SCENE_CONTROLLER,"Scene Controller"); wait(SHORT_WAIT); #endif #ifdef ID_S_RGB_LIGHT Serial.println(" RGB_LIGHT"); present(ID_S_RGB_LIGHT,S_RGB_LIGHT,"Mood Light"); wait(SHORT_WAIT); #endif #ifdef ID_S_RGBW_LIGHT Serial.println(" RGBW_LIGHT"); present(ID_S_RGBW_LIGHT,S_RGBW_LIGHT,"Mood Light 2"); wait(SHORT_WAIT); #endif #ifdef ID_S_COLOR_SENSOR Serial.println(" COLOR_SENSOR"); present(ID_S_COLOR_SENSOR,S_COLOR_SENSOR,"Hall Painting"); wait(SHORT_WAIT); #endif #ifdef ID_S_HVAC Serial.println(" HVAC"); present(ID_S_HVAC,S_HVAC,"HVAC"); wait(SHORT_WAIT); #endif #ifdef ID_S_MULTIMETER Serial.println(" MULTIMETER"); present(ID_S_MULTIMETER,S_MULTIMETER,"Electric Staion"); wait(SHORT_WAIT); #endif #ifdef ID_S_SPRINKLER #endif #ifdef ID_S_WATER_LEAK #endif #ifdef ID_S_SOUND #endif #ifdef ID_S_VIBRATION #endif #ifdef ID_S_MOISTURE #endif #ifdef ID_S_MOISTURE Serial.println(" S_MOISTURE"); present(ID_S_MOISTURE,S_MOISTURE,"Basement Sensor"); wait(SHORT_WAIT); #endif #ifdef ID_S_CUSTOM Serial.println(" S_CUSTOM"); present(ID_S_CUSTOM,S_CUSTOM,"Other Stuff"); wait(SHORT_WAIT); #endif Serial.println("________________"); } void loop() { Serial.println(""); Serial.println(""); Serial.println(""); Serial.println("#########################"); randNumber=random(0,101); Serial.print("RandomNumber:"); Serial.println(randNumber); // Send fake battery level Serial.println("Send Battery Level"); sendBatteryLevel(randNumber); wait(LONG_WAIT); // Request time Serial.println("Request Time"); requestTime(); wait(LONG_WAIT); //Read Sensors #ifdef ID_S_DOOR door(); #endif #ifdef ID_S_MOTION motion(); #endif #ifdef ID_S_SMOKE smoke(); #endif #ifdef ID_S_LIGHT light(); #endif #ifdef ID_S_DIMMER dimmer(); #endif #ifdef ID_S_COVER cover(); #endif #ifdef ID_S_TEMP temp(); #endif #ifdef ID_S_HUM hum(); #endif #ifdef ID_S_BARO baro(); #endif #ifdef ID_S_WIND wind(); #endif #ifdef ID_S_RAIN rain(); #endif #ifdef ID_S_UV uv(); #endif #ifdef ID_S_WEIGHT weight(); #endif #ifdef ID_S_POWER power(); #endif #ifdef ID_S_HEATER heater(); #endif #ifdef ID_S_DISTANCE distance(); #endif #ifdef ID_S_LIGHT_LEVEL light_level(); #endif #ifdef ID_S_LOCK lock(); #endif #ifdef ID_S_IR ir(); #endif #ifdef ID_S_WATER water(); #endif #ifdef ID_S_AIR_QUALITY air(); #endif #ifdef ID_S_DUST dust(); #endif #ifdef ID_S_SCENE_CONTROLLER scene(); #endif #ifdef ID_S_RGB_LIGHT rgbLight(); #endif #ifdef ID_S_RGBW_LIGHT rgbwLight(); #endif #ifdef ID_S_COLOR_SENSOR color(); #endif #ifdef ID_S_HVAC hvac(); #endif #ifdef ID_S_MULTIMETER multimeter(); #endif #ifdef ID_S_SPRINKLER #endif #ifdef ID_S_WATER_LEAK #endif #ifdef ID_S_SOUND #endif #ifdef ID_S_VIBRATION #endif #ifdef ID_S_MOISTURE #endif #ifdef ID_S_MOISTURE moisture(); #endif #ifdef ID_S_CUSTOM custom(); #endif sendBatteryLevel(randNumber); wait(SHORT_WAIT); Serial.println("#########################"); wait(SLEEP_TIME); //sleep a bit } // This is called when a new time value was received void receiveTime(unsigned long controllerTime) { Serial.print("Time value received: "); Serial.println(controllerTime); } //void door(){} #ifdef ID_S_DOOR void door() { Serial.print("Door is: " ); if (randNumber <= 50) { Serial.println("Open"); send(msg_S_DOOR_T.set((int16_t)1)); } else { Serial.println("Closed"); send(msg_S_DOOR_T.set((int16_t)0)); } #ifdef ID_S_ARMED Serial.print("System is: " ); Serial.println((isArmed ? "Armed":"Disarmed")); send(msg_S_DOOR_A.set(isArmed)); #endif } #endif #ifdef ID_S_MOTION void motion() { Serial.print("Motion is: " ); if (randNumber <= 50) { Serial.println("Active"); send(msg_S_MOTION_T.set(1)); } else { Serial.println("Quiet"); send(msg_S_MOTION_T.set(0)); } #ifdef ID_S_ARMED Serial.print("System is: " ); Serial.println((isArmed ? "Armed":"Disarmed")); send(msg_S_MOTION_A.set(isArmed)); #endif } #endif #ifdef ID_S_SMOKE void smoke() { Serial.print("Smoke is: " ); if (randNumber <= 50) { Serial.println("Active"); send(msg_S_SMOKE_T.set(1)); } else { Serial.println("Quiet"); send(msg_S_SMOKE_T.set(0)); } #ifdef ID_S_ARMED Serial.print("System is: " ); Serial.println((isArmed ? "Armed":"Disarmed")); send(msg_S_SMOKE_A.set(isArmed)); #endif } #endif #ifdef ID_S_LIGHT void light() { Serial.print("Light is: " ); Serial.println((isLightOn ? "On":"Off")); send(msg_S_LIGHT.set(isLightOn)); } #endif #ifdef ID_S_DIMMER void dimmer() { Serial.print("Dimmer is set to: " ); Serial.println(dimmerVal); send(msg_S_DIMMER.set(dimmerVal)); } #endif #ifdef ID_S_COVER void cover() { Serial.print("Cover is : " ); if (coverState == 1) { Serial.println("Opening"); send(msg_S_COVER_U.set(1)); } else if (coverState == -1) { Serial.println("Closing"); send(msg_S_COVER_D.set(0)); } else { Serial.println("Idle"); send(msg_S_COVER_S.set(-1)); } send(msg_S_COVER_V.set(coverState)); } #endif #ifdef ID_S_TEMP void temp() { Serial.print("Temperature is: " ); Serial.println(map(randNumber,1,100,0,45)); send(msg_S_TEMP.set(map(randNumber,1,100,0,45))); } #endif #ifdef ID_S_HUM void hum() { Serial.print("Humitidty is: " ); Serial.println(randNumber); send(msg_S_HUM.set(randNumber)); } #endif #ifdef ID_S_BARO void baro() { const char *weather[] = {"stable","sunny","cloudy","unstable","thunderstorm","unknown"}; long pressure = map(randNumber,1,100,870,1086);// hPa? int forecast = map(randNumber,1,100,0,5); Serial.print("Atmosferic Pressure is: " ); Serial.println(pressure); send(msg_S_BARO_P.set(pressure)); Serial.print("Weather forecast: " ); Serial.println(weather[forecast]); send(msg_S_BARO_F.set(weather[forecast])); } #endif #ifdef ID_S_WIND void wind() { Serial.print("Wind Speed is: " ); Serial.println(randNumber); send(msg_S_WIND_S.set(randNumber)); Serial.print("Wind Gust is: " ); Serial.println(randNumber+10); send(msg_S_WIND_G.set(randNumber+10)); Serial.print("Wind Direction is: " ); Serial.println(map(randNumber,1,100,0,360)); send(msg_S_WIND_D.set(map(randNumber,1,100,0,360))); } #endif #ifdef ID_S_RAIN void rain() { Serial.print("Rain ammount is: " ); Serial.println(randNumber); send(msg_S_RAIN_A.set(randNumber)); Serial.print("Rain rate is: " ); Serial.println(randNumber/60); send(msg_S_RAIN_R.set(randNumber/60,1)); } #endif #ifdef ID_S_UV void uv() { Serial.print("Ultra Violet level is: " ); Serial.println(map(randNumber,1,100,0,15)); send(msg_S_UV.set(map(randNumber,1,100,0,15))); } #endif #ifdef ID_S_WEIGHT void weight() { Serial.print("Weight is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_WEIGHT.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_POWER void power() { Serial.print("Watt is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_POWER_W.set(map(randNumber,1,100,0,150))); Serial.print("KWH is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_POWER_K.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_HEATER void heater() { // float heater_setpoint=21.5; // float heater_temp=23.5; // bool heater_status=false; // String heatState="Off"; Serial.print("Heater flow state is: " ); Serial.println(heater_flow_state); send(msg_S_HEATER_FLOW_STATE.set(heater_flow_state.c_str())); // Serial.print("Heater on/off is: " ); // Serial.println((heater_status==true)?"On":"Off"); // send(msg_S_HEATER_STATUS.set(heater_status)); // Serial.print("Heater Temperature is: " ); // Serial.println(heater_temp,1); // send(msg_S_HEATER_TEMP.set(heater_temp,1)); Serial.print("Heater Setpoint: " ); Serial.println(heater_setpoint,1); send(msg_S_HEATER_SET_POINT.set(heater_setpoint,1)); } #endif #ifdef ID_S_DISTANCE void distance() { Serial.print("Distance is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_DISTANCE.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_LIGHT_LEVEL void light_level() { Serial.print("Light is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_LIGHT_LEVEL.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_LOCK void lock() { Serial.print("Lock is: " ); Serial.println((isLocked ? "Locked":"Unlocked")); send(msg_S_LOCK.set(isLocked)); } #endif #ifdef ID_S_IR void ir() { Serial.print("Infrared is: " ); Serial.println(irVal); send(msg_S_IR_S.set(irVal)); send(msg_S_IR_R.set(irVal)); } #endif #ifdef ID_S_WATER void water() { Serial.print("Water flow is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_WATER_F.set(map(randNumber,1,100,0,150))); Serial.print("Water volume is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_WATER_V.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_AIR_QUALITY void air() { Serial.print("Air Quality is: " ); Serial.println(randNumber); send(msg_S_AIR_QUALITY.set(randNumber)); } #endif #ifdef ID_S_DUST void dust() { Serial.print("Dust level is: " ); Serial.println(randNumber); send(msg_S_DUST.set(randNumber)); } #endif #ifdef ID_S_SCENE_CONTROLLER void scene() { Serial.print("Scene is: " ); Serial.println(scenes[sceneVal]); if(sceneValPrevious != sceneVal) { send(msg_S_SCENE_CONTROLLER_OF.set(sceneValPrevious)); send(msg_S_SCENE_CONTROLLER_ON.set(sceneVal)); sceneValPrevious=sceneVal; } } #endif #ifdef ID_S_RGB_LIGHT void rgbLight() { Serial.print("RGB Light state is: " ); Serial.println(rgbState); send(msg_S_RGB_LIGHT_V_RGB.set(rgbState.c_str())); Serial.print("RGB Light Watt is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_RGB_LIGHT_V_WATT.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_RGBW_LIGHT void rgbwLight() { Serial.print("RGBW Light state is: " ); Serial.println(rgbwState); send(msg_S_RGBW_LIGHT_V_RGBW.set(rgbwState.c_str())); Serial.print("RGBW Light Watt is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_RGBW_LIGHT_V_WATT.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_COLOR_SENSOR void color() { String colorState; String red = String(random(0,256),HEX); String green = String(random(0,256),HEX); String blue = String(random(0,256),HEX); colorState=String(red + green + blue); Serial.print("Color state is: " ); Serial.println(colorState); send(msg_S_COLOR_SENSOR_V_RGB.set(colorState.c_str())); } #endif #ifdef ID_S_HVAC void hvac() { // float hvac_SetPointHeat = 16.5; // float hvac_SetPointCool = 25.5; // String hvac_FlowState = "AutoChangeOver"; // String hvac_FlowMode = "Auto"; // String hvac_Speed = "Normal"; Serial.print("HVAC Set Point Heat is: " ); Serial.println(hvac_SetPointHeat); send(msg_S_HVAC_V_HVAC_SETPOINT_HEAT.set(hvac_SetPointHeat,1)); Serial.print("HVAC Set Point Cool is: " ); Serial.println(hvac_SetPointCool); send(msg_S_HVAC_V_HVAC_SETPOINT_COOL.set(hvac_SetPointCool,1)); Serial.print("HVAC Flow State is: " ); Serial.println(hvac_FlowState); send(msg_S_HVAC_V_HVAC_FLOW_STATET.set(hvac_FlowState.c_str())); Serial.print("HVAC Flow Mode is: " ); Serial.println(hvac_FlowMode); send(msg_S_HVAC_V_HVAC_FLOW_MODE.set(hvac_FlowMode.c_str())); Serial.print("HVAC Speed is: " ); Serial.println(hvac_Speed); send(msg_S_HVAC_V_HVAC_SPEED.set(hvac_Speed.c_str())); } #endif #ifdef ID_S_MULTIMETER void multimeter() { int impedance=map(randNumber,1,100,0,15000); int volt=map(randNumber,1,100,0,380); int amps=map(randNumber,1,100,0,16); Serial.print("Impedance is: " ); Serial.println(impedance); send(msg_S_MULTIMETER_V_IMPEDANCE.set(impedance)); Serial.print("Voltage is: " ); Serial.println(volt); send(msg_S_MULTIMETER_V_VOLTAGE.set(volt)); Serial.print("Current is: " ); Serial.println(amps); send(msg_S_MULTIMETER_V_CURRENT.set(amps)); } #endif #ifdef ID_S_SPRINKLER #endif #ifdef ID_S_WATER_LEAK #endif #ifdef ID_S_SOUND #endif #ifdef ID_S_VIBRATION #endif #ifdef ID_S_MOISTURE #endif #ifdef ID_S_MOISTURE void moisture() { Serial.print("Moisture level is: " ); Serial.println(randNumber); send(msg_S_MOISTURE.set(randNumber)); } #endif #ifdef ID_S_CUSTOM void custom() { Serial.print("Custom value is: " ); Serial.println(randNumber); send(msg_S_CUSTOM_1.set(randNumber)); send(msg_S_CUSTOM_2.set(randNumber)); send(msg_S_CUSTOM_3.set(randNumber)); send(msg_S_CUSTOM_4.set(randNumber)); send(msg_S_CUSTOM_5.set(randNumber)); } #endif void receive(const MyMessage &message) { switch (message.type) { #ifdef ID_S_ARMED case V_ARMED: isArmed = message.getBool(); Serial.print("Incoming change for ID_S_ARMED:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println((isArmed ? "Armed":"Disarmed" )); #ifdef ID_S_DOOR door();//temp ack for door #endif #ifdef ID_S_MOTION motion();//temp ack #endif #ifdef ID_S_SMOKE smoke();//temp ack #endif break; #endif case V_STATUS: // V_LIGHT: #ifdef ID_S_LIGHT if(message.sensor==ID_S_LIGHT) { isLightOn = message.getBool(); Serial.print("Incoming change for ID_S_LIGHT:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println((isLightOn ? "On":"Off")); light(); // temp ack } #endif // #ifdef ID_S_HEATER // if(message.sensor == ID_S_HEATER){ // heater_status = message.getBool(); // Serial.print("Incoming change for ID_S_HEATER:"); // Serial.print(message.sensor); // Serial.print(", New status: "); // Serial.println(heater_status); // heater();//temp ack // } // #endif break; #ifdef ID_S_DIMMER case V_DIMMER: if ((message.getInt()<0)||(message.getInt()>100)) { Serial.println( "V_DIMMER data invalid (should be 0..100)" ); break; } dimmerVal= message.getInt(); Serial.print("Incoming change for ID_S_DIMMER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(message.getInt()); dimmer();// temp ack break; #endif #ifdef ID_S_COVER case V_UP: coverState=1; Serial.print("Incoming change for ID_S_COVER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println("V_UP"); cover(); // temp ack break; case V_DOWN: coverState=-1; Serial.print("Incoming change for ID_S_COVER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println("V_DOWN"); cover(); //temp ack break; case V_STOP: coverState=0; Serial.print("Incoming change for ID_S_COVER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println("V_STOP"); cover(); //temp ack break; #endif case V_HVAC_SETPOINT_HEAT: #ifdef ID_S_HEATER if(message.sensor == ID_S_HEATER) { heater_setpoint=message.getFloat(); Serial.print("Incoming set point for ID_S_HEATER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(heater_setpoint,1); heater();//temp ack } #endif #ifdef ID_S_HVAC if(message.sensor == ID_S_HVAC) { hvac_SetPointHeat=message.getFloat(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_SetPointHeat,1); hvac();//temp ack } #endif break; case V_HVAC_FLOW_STATE: #ifdef ID_S_HEATER if(message.sensor == ID_S_HEATER) { heater_flow_state=message.getString(); Serial.print("Incoming flow state change for ID_S_HEATER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(heater_flow_state); heater();//temp ack } #endif #ifdef ID_S_HVAC if(message.sensor == ID_S_HVAC) { hvac_FlowState=message.getString(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_FlowState); hvac();//temp ack } #endif break; #ifdef ID_S_LOCK case V_LOCK_STATUS: isLocked = message.getBool(); Serial.print("Incoming change for ID_S_LOCK:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(message.getBool()?"Locked":"Unlocked"); lock(); //temp ack break; #endif #ifdef ID_S_IR case V_IR_SEND: irVal = message.getLong(); Serial.print("Incoming change for ID_S_IR:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(irVal); ir(); // temp ack break; case V_IR_RECEIVE: irVal = message.getLong(); Serial.print("Incoming change for ID_S_IR:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(irVal); ir(); // temp ack break; #endif #ifdef ID_S_SCENE_CONTROLLER case V_SCENE_ON: sceneVal = message.getInt(); Serial.print("Incoming change for ID_S_SCENE_CONTROLLER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.print(scenes[sceneVal]); Serial.println(" On"); scene();// temp ack break; case V_SCENE_OFF: sceneVal = message.getInt(); Serial.print("Incoming change for ID_S_SCENE_CONTROLLER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.print(scenes[sceneVal]); Serial.println(" Off"); scene();// temp ack break; #endif #ifdef ID_S_RGB_LIGHT case V_RGB: rgbState=message.getString(); Serial.print("Incoming flow state change for ID_S_RGB_LIGHT:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(rgbState); rgbLight(); // temp ack break; #endif #ifdef ID_S_RGBW_LIGHT case V_RGBW: rgbwState=message.getString(); Serial.print("Incoming flow state change for ID_S_RGBW_LIGHT:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(rgbwState); rgbwLight(); break; #endif #ifdef ID_S_HVAC // hvac_SetPointHeat // hvac_SetPointCool // hvac_FlowState // hvac_FlowMode // hvac_Speed case V_HVAC_SETPOINT_COOL: hvac_SetPointCool=message.getFloat(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_SetPointCool,1); hvac();//temp ack break; case V_HVAC_FLOW_MODE: hvac_Speed=message.getString(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_Speed); hvac();//temp ack break; case V_HVAC_SPEED: hvac_FlowMode=message.getString(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_FlowMode); hvac();//temp ack break; #endif default: Serial.print("Unknown/UnImplemented message type: "); Serial.println(message.type); } }
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Oops. Uncommented the wrong thing. I'll try again.
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OK, confirmed. The full error message is:
Build options changed, rebuilding all C:\Users\CoolerMaster\Documents\Arduino\mysensors sketches\mockmysensors\MockMySensors_v002\MockMySensors_v002.ino: In function 'void multimeter()': MockMySensors_v002:1183: error: call of overloaded 'set(int&)' is ambiguous send(msg_S_MULTIMETER_V_IMPEDANCE.set(impedance)); ^ In file included from C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/MySensors.h:364:0, from C:\Users\CoolerMaster\Documents\Arduino\mysensors sketches\mockmysensors\MockMySensors_v002\MockMySensors_v002.ino:20: C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:269:12: note: candidate: MyMessage& MyMessage::set(bool) MyMessage& MyMessage::set(bool value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:277:12: note: candidate: MyMessage& MyMessage::set(uint8_t) MyMessage& MyMessage::set(uint8_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:294:12: note: candidate: MyMessage& MyMessage::set(uint32_t) MyMessage& MyMessage::set(uint32_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:302:12: note: candidate: MyMessage& MyMessage::set(int32_t) MyMessage& MyMessage::set(int32_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:310:12: note: candidate: MyMessage& MyMessage::set(uint16_t) MyMessage& MyMessage::set(uint16_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:318:12: note: candidate: MyMessage& MyMessage::set(int16_t) MyMessage& MyMessage::set(int16_t value) ^ MockMySensors_v002:1187: error: call of overloaded 'set(int&)' is ambiguous send(msg_S_MULTIMETER_V_VOLTAGE.set(volt)); ^ In file included from C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/MySensors.h:364:0, from C:\Users\CoolerMaster\Documents\Arduino\mysensors sketches\mockmysensors\MockMySensors_v002\MockMySensors_v002.ino:20: C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:269:12: note: candidate: MyMessage& MyMessage::set(bool) MyMessage& MyMessage::set(bool value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:277:12: note: candidate: MyMessage& MyMessage::set(uint8_t) MyMessage& MyMessage::set(uint8_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:294:12: note: candidate: MyMessage& MyMessage::set(uint32_t) MyMessage& MyMessage::set(uint32_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:302:12: note: candidate: MyMessage& MyMessage::set(int32_t) MyMessage& MyMessage::set(int32_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:310:12: note: candidate: MyMessage& MyMessage::set(uint16_t) MyMessage& MyMessage::set(uint16_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:318:12: note: candidate: MyMessage& MyMessage::set(int16_t) MyMessage& MyMessage::set(int16_t value) ^ MockMySensors_v002:1191: error: call of overloaded 'set(int&)' is ambiguous send(msg_S_MULTIMETER_V_CURRENT.set(amps)); ^ In file included from C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/MySensors.h:364:0, from C:\Users\CoolerMaster\Documents\Arduino\mysensors sketches\mockmysensors\MockMySensors_v002\MockMySensors_v002.ino:20: C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:269:12: note: candidate: MyMessage& MyMessage::set(bool) MyMessage& MyMessage::set(bool value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:277:12: note: candidate: MyMessage& MyMessage::set(uint8_t) MyMessage& MyMessage::set(uint8_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:294:12: note: candidate: MyMessage& MyMessage::set(uint32_t) MyMessage& MyMessage::set(uint32_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:302:12: note: candidate: MyMessage& MyMessage::set(int32_t) MyMessage& MyMessage::set(int32_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:310:12: note: candidate: MyMessage& MyMessage::set(uint16_t) MyMessage& MyMessage::set(uint16_t value) ^ C:\Users\CoolerMaster\Documents\Arduino\libraries\MySensors-development/core/MyMessage.cpp:318:12: note: candidate: MyMessage& MyMessage::set(int16_t) MyMessage& MyMessage::set(int16_t value) ^ exit status 1 call of overloaded 'set(int&)' is ambiguous
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@NeverDie
Ha Yes Sprinkler works fine.
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@NeverDie
So after running through all the sensors in the mockmysensors sketch there are quite a few that have the same problem.
I have done the same tests on my standard setup ATmega328 and all compile ok.
I also tried some of my own small sketches on both platforms and had problems on the nrf5 platform with the same error.
So is this a mySensors problem or is it something deeper?.
Why should it not work on both as far as the syntax is concerned.
Who if anybody do i report the problem too?I took the plunge and ordered a jlink/v2 programmer and a waveshare BLE400 motherboard and core module (I know it is nrf51822 but it is a start) but i hope the above problem can be sorted out.
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@rmtucker said in
MySensors NRF5 Platform:there are quite a few that have the same problem.
Yes, the ones I noticed that seem to have the problem are: motion, smoke, dimmer, cover, scene controller, and, of course, multimeter. The rest compiled.
I don't know the answers to your other good questions, but AFAIK @d00616 appears to be the point man. Perhaps @d00616 can comment?
Also, if you're not already aware of it, @rmtucker I invite you to join in on the constantly evolving discussion at: https://forum.mysensors.org/topic/6961/nrf5-bluetooth-action/498
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After trawling through posts on the forum the following changes compile ok.
Altered int to uint16_t#ifdef ID_S_MULTIMETER void multimeter() { uint16_t impedance=map(randNumber,1,100,0,15000); uint16_t volt=map(randNumber,1,100,0,380); uint16_t amps=map(randNumber,1,100,0,16); Serial.print("Impedance is: " ); Serial.println(impedance); send(msg_S_MULTIMETER_V_IMPEDANCE.set(impedance)); Serial.print("Voltage is: " ); Serial.println(volt); send(msg_S_MULTIMETER_V_VOLTAGE.set(volt)); Serial.print("Current is: " ); Serial.println(amps); send(msg_S_MULTIMETER_V_CURRENT.set(amps)); } #endif```
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@NeverDie
After adding a Few uint16_t the whole sketch now compiles with all the sensors turned on and only uses 19% of available memory space
,could never have done that on the ATmega platform.
Just wish we could work out why it had to be changed/* * MockMySensors * * This skecth is intended to crate fake sensors which register and respond to the controller * *** * Barduino 2015, GizMoCuz 2015 */ // Enable debug prints to serial monitor #define MY_DEBUG // Enable and select radio type attached //#define MY_RADIO_NRF24 //#define MY_RADIO_RFM69 #define MY_RADIO_NRF5_ESB #define MY_NODE_ID 254 #include <MySensors.h> #define RADIO_ERROR_LED_PIN 4 // Error led pin #define RADIO_RX_LED_PIN 6 // Receive led pin #define RADIO_TX_LED_PIN 5 // the PCB, on board LED // Wait times #define LONG_WAIT 500 #define SHORT_WAIT 50 #define SKETCH_NAME "MockMySensors " #define SKETCH_VERSION "v0.5" // Define Sensors ids /* S_DOOR, S_MOTION, S_SMOKE, S_LIGHT, S_DIMMER, S_COVER, S_TEMP, S_HUM, S_BARO, S_WIND, S_RAIN, S_UV, S_WEIGHT, S_POWER, S_HEATER, S_DISTANCE, S_LIGHT_LEVEL, S_ARDUINO_NODE, S_ARDUINO_REPEATER_NODE, S_LOCK, S_IR, S_WATER, S_AIR_QUALITY, S_CUSTOM, S_DUST, S_SCENE_CONTROLLER */ ////#define ID_S_ARDUINO_NODE //auto defined in initialization ////#define ID_S_ARDUINO_REPEATER_NODE //auto defined in initialization // Some of these ID's have not been updated for v1.5. Uncommenting too many of them // will make the sketch too large for a pro mini's memory so it's probably best to try // one at a time. #define ID_S_ARMED 0 // dummy to controll armed stated for several sensors #define ID_S_DOOR 1 #define ID_S_MOTION 2 #define ID_S_SMOKE 3 #define ID_S_LIGHT 4 #define ID_S_DIMMER 5 #define ID_S_COVER 6 #define ID_S_TEMP 7 #define ID_S_HUM 8 #define ID_S_BARO 9 #define ID_S_WIND 10 #define ID_S_RAIN 11 #define ID_S_UV 12 #define ID_S_WEIGHT 13 #define ID_S_POWER 14 #define ID_S_HEATER 15 #define ID_S_DISTANCE 16 #define ID_S_LIGHT_LEVEL 17 #define ID_S_LOCK 18 #define ID_S_IR 19 #define ID_S_WATER 20 #define ID_S_AIR_QUALITY 21 #define ID_S_DUST 22 #define ID_S_SCENE_CONTROLLER 23 //// Lib 1.5 sensors #define ID_S_RGB_LIGHT 24 #define ID_S_RGBW_LIGHT 25 #define ID_S_COLOR_SENSOR 26 #define ID_S_HVAC 27 #define ID_S_MULTIMETER 28 #define ID_S_SPRINKLER 29 #define ID_S_WATER_LEAK 30 #define ID_S_SOUND 31 #define ID_S_VIBRATION 32 #define ID_S_MOISTURE 33 // #define ID_S_CUSTOM 99 // Global Vars unsigned long SLEEP_TIME = 900000; // Sleep time between reads (in milliseconds) bool metric = true; long randNumber; //Instanciate Messages objects #ifdef ID_S_ARMED bool isArmed; #endif #ifdef ID_S_DOOR // V_TRIPPED, V_ARMED MyMessage msg_S_DOOR_T(ID_S_DOOR,V_TRIPPED); MyMessage msg_S_DOOR_A(ID_S_DOOR,V_ARMED); #endif #ifdef ID_S_MOTION // V_TRIPPED, V_ARMED MyMessage msg_S_MOTION_A(ID_S_MOTION,V_ARMED); MyMessage msg_S_MOTION_T(ID_S_MOTION,V_TRIPPED); #endif #ifdef ID_S_SMOKE // V_TRIPPED, V_ARMED MyMessage msg_S_SMOKE_T(ID_S_SMOKE,V_TRIPPED); MyMessage msg_S_SMOKE_A(ID_S_SMOKE,V_ARMED); #endif #ifdef ID_S_LIGHT MyMessage msg_S_LIGHT(ID_S_LIGHT,V_LIGHT); bool isLightOn=0; #endif #ifdef ID_S_DIMMER MyMessage msg_S_DIMMER(ID_S_DIMMER,V_DIMMER); uint16_t dimmerVal=100; #endif #ifdef ID_S_COVER MyMessage msg_S_COVER_U(ID_S_COVER,V_UP); MyMessage msg_S_COVER_D(ID_S_COVER,V_DOWN); MyMessage msg_S_COVER_S(ID_S_COVER,V_STOP); MyMessage msg_S_COVER_V(ID_S_COVER,V_VAR1); int coverState=0; //0=Stop; 1=up; -1=down #endif #ifdef ID_S_TEMP MyMessage msg_S_TEMP(ID_S_TEMP,V_TEMP); #endif #ifdef ID_S_HUM MyMessage msg_S_HUM(ID_S_HUM,V_HUM); #endif #ifdef ID_S_BARO MyMessage msg_S_BARO_P(ID_S_BARO,V_PRESSURE); MyMessage msg_S_BARO_F(ID_S_BARO,V_FORECAST); #endif #ifdef ID_S_WIND MyMessage msg_S_WIND_S(ID_S_WIND,V_WIND); MyMessage msg_S_WIND_G(ID_S_WIND,V_GUST); MyMessage msg_S_WIND_D(ID_S_WIND,V_DIRECTION); #endif #ifdef ID_S_RAIN MyMessage msg_S_RAIN_A(ID_S_RAIN,V_RAIN); MyMessage msg_S_RAIN_R(ID_S_RAIN,V_RAINRATE); #endif #ifdef ID_S_UV MyMessage msg_S_UV(ID_S_UV,V_UV); #endif #ifdef ID_S_WEIGHT MyMessage msg_S_WEIGHT(ID_S_WEIGHT,V_WEIGHT); #endif #ifdef ID_S_POWER MyMessage msg_S_POWER_W(ID_S_POWER,V_WATT); MyMessage msg_S_POWER_K(ID_S_POWER,V_KWH); #endif #ifdef ID_S_HEATER //////// REVIEW IMPLEMENTATION //////////// MyMessage msg_S_HEATER_SET_POINT(ID_S_HEATER, V_HVAC_SETPOINT_HEAT); // HVAC/Heater setpoint (Integer between 0-100). S_HEATER, S_HVAC MyMessage msg_S_HEATER_FLOW_STATE(ID_S_HEATER, V_HVAC_FLOW_STATE); // Mode of header. One of "Off", "HeatOn", "CoolOn", or "AutoChangeOver" // S_HVAC, S_HEATER //MyMessage msg_S_HEATER_STATUS(ID_S_HEATER,V_STATUS); //MyMessage msg_S_HEATER_TEMP(ID_S_HEATER,V_TEMP); float heater_setpoint=21.5; String heater_flow_state="Off"; // float heater_temp=23.5; // bool heater_status=false; // V_TEMP // Temperature // V_STATUS // Binary status. 0=off 1=on // V_HVAC_FLOW_STATE // Mode of header. One of "Off", "HeatOn", "CoolOn", or "AutoChangeOver" // V_HVAC_SPEED // HVAC/Heater fan speed ("Min", "Normal", "Max", "Auto") // V_HVAC_SETPOINT_HEAT // HVAC/Heater setpoint #endif #ifdef ID_S_DISTANCE MyMessage msg_S_DISTANCE(ID_S_DISTANCE,V_DISTANCE); #endif #ifdef ID_S_LIGHT_LEVEL MyMessage msg_S_LIGHT_LEVEL(ID_S_LIGHT_LEVEL,V_LIGHT_LEVEL); #endif #ifdef ID_S_LOCK MyMessage msg_S_LOCK(ID_S_LOCK,V_LOCK_STATUS); bool isLocked = 0; #endif #ifdef ID_S_IR MyMessage msg_S_IR_S(ID_S_IR,V_IR_SEND); MyMessage msg_S_IR_R(ID_S_IR,V_IR_RECEIVE); long irVal = 0; #endif #ifdef ID_S_WATER MyMessage msg_S_WATER_F(ID_S_WATER,V_FLOW); MyMessage msg_S_WATER_V(ID_S_WATER,V_VOLUME); #endif #ifdef ID_S_AIR_QUALITY MyMessage msg_S_AIR_QUALITY(ID_S_AIR_QUALITY,V_LEVEL); #endif #ifdef ID_S_DUST MyMessage msg_S_DUST(ID_S_DUST,V_LEVEL); #endif #ifdef ID_S_SCENE_CONTROLLER MyMessage msg_S_SCENE_CONTROLLER_ON(ID_S_SCENE_CONTROLLER,V_SCENE_ON); MyMessage msg_S_SCENE_CONTROLLER_OF(ID_S_SCENE_CONTROLLER,V_SCENE_OFF); // not sure if scene controller sends int or chars // betting on ints as Touch Display Scen by Hek // compiler warnings char *scenes[] = { (char *)"Good Morning", (char *)"Clean Up!", (char *)"All Lights Off", (char *)"Music On/Off" }; int sceneVal=0; int sceneValPrevious=0; #endif #ifdef ID_S_RGB_LIGHT MyMessage msg_S_RGB_LIGHT_V_RGB(ID_S_RGB_LIGHT,V_RGB); MyMessage msg_S_RGB_LIGHT_V_WATT(ID_S_RGB_LIGHT,V_WATT); String rgbState="000000"; //RGB light V_RGB, V_WATT //RGB value transmitted as ASCII hex string (I.e "ff0000" for red) #endif #ifdef ID_S_RGBW_LIGHT MyMessage msg_S_RGBW_LIGHT_V_RGBW(ID_S_RGBW_LIGHT,V_RGBW); MyMessage msg_S_RGBW_LIGHT_V_WATT(ID_S_RGBW_LIGHT,V_WATT); String rgbwState="00000000"; //RGBW light (with separate white component) V_RGBW, V_WATT //RGBW value transmitted as ASCII hex string (I.e "ff0000ff" for red + full white) S_RGBW_LIGHT #endif #ifdef ID_S_COLOR_SENSOR MyMessage msg_S_COLOR_SENSOR_V_RGB(ID_S_COLOR_SENSOR,V_RGB); //Color sensor V_RGB //RGB value transmitted as ASCII hex string (I.e "ff0000" for red) S_RGB_LIGHT, S_COLOR_SENSOR #endif #ifdef ID_S_HVAC MyMessage msg_S_HVAC_V_HVAC_SETPOINT_HEAT(ID_S_HVAC,V_HVAC_SETPOINT_HEAT); MyMessage msg_S_HVAC_V_HVAC_SETPOINT_COOL(ID_S_HVAC,V_HVAC_SETPOINT_COOL); MyMessage msg_S_HVAC_V_HVAC_FLOW_STATET(ID_S_HVAC,V_HVAC_FLOW_STATE); MyMessage msg_S_HVAC_V_HVAC_FLOW_MODE(ID_S_HVAC,V_HVAC_FLOW_MODE); MyMessage msg_S_HVAC_V_HVAC_SPEED(ID_S_HVAC,V_HVAC_SPEED); float hvac_SetPointHeat = 16.5; float hvac_SetPointCool = 25.5; String hvac_FlowState = "AutoChangeOver"; String hvac_FlowMode = "Auto"; String hvac_Speed = "Normal"; //Thermostat/HVAC device //V_HVAC_SETPOINT_HEAT, // HVAC/Heater setpoint //V_HVAC_SETPOINT_COOL, // HVAC cold setpoint //V_HVAC_FLOW_STATE, // Mode of header. One of "Off", "HeatOn", "CoolOn", or "AutoChangeOver" //V_HVAC_FLOW_MODE, // Flow mode for HVAC ("Auto", "ContinuousOn", "PeriodicOn") //V_HVAC_SPEED // HVAC/Heater fan speed ("Min", "Normal", "Max", "Auto") // NOT IMPLEMENTED YET //V_TEMP // Temperature //V_STATUS // Binary status. 0=off 1=on #endif #ifdef ID_S_MULTIMETER MyMessage msg_S_MULTIMETER_V_IMPEDANCE(ID_S_MULTIMETER,V_IMPEDANCE); MyMessage msg_S_MULTIMETER_V_VOLTAGE(ID_S_MULTIMETER,V_VOLTAGE); MyMessage msg_S_MULTIMETER_V_CURRENT(ID_S_MULTIMETER,V_CURRENT); // Multimeter device V_VOLTAGE, V_CURRENT, V_IMPEDANCE // V_IMPEDANCE 14 Impedance value // V_VOLTAGE 38 Voltage level // V_CURRENT 39 Current level #endif #ifdef ID_S_SPRINKLER // S_SPRINKLER 31 Sprinkler device V_STATUS (turn on/off), V_TRIPPED (if fire detecting device) // V_STATUS 2 Binary status. 0=off 1=on // V_ARMED 15 Armed status of a security sensor. 1=Armed, 0=Bypassed // V_TRIPPED 16 Tripped status of a security sensor. 1=Tripped, 0=Untripped #endif #ifdef ID_S_WATER_LEAK #endif #ifdef ID_S_SOUND #endif #ifdef ID_S_VIBRATION #endif #ifdef ID_S_MOISTURE #endif #ifdef ID_S_MOISTURE MyMessage msg_S_MOISTURE(ID_S_MOISTURE,V_LEVEL); #endif #ifdef ID_S_CUSTOM MyMessage msg_S_CUSTOM_1(ID_S_CUSTOM,V_VAR1); MyMessage msg_S_CUSTOM_2(ID_S_CUSTOM,V_VAR2); MyMessage msg_S_CUSTOM_3(ID_S_CUSTOM,V_VAR3); MyMessage msg_S_CUSTOM_4(ID_S_CUSTOM,V_VAR4); MyMessage msg_S_CUSTOM_5(ID_S_CUSTOM,V_VAR5); #endif void setup() { // Random SEED randomSeed(analogRead(0)); wait(LONG_WAIT); Serial.println("GW Started"); } void presentation() { // Send the Sketch Version Information to the Gateway Serial.print("Send Sketch Info: "); sendSketchInfo(SKETCH_NAME, SKETCH_VERSION); Serial.print(SKETCH_NAME); Serial.println(SKETCH_VERSION); wait(LONG_WAIT); // Get controller configuration Serial.print("Get Config: "); metric = getControllerConfig().isMetric; Serial.println(metric ? "Metric":"Imperial"); wait(LONG_WAIT); // Init Armed #ifdef ID_S_ARMED isArmed = true; #endif // Register all sensors to gw (they will be created as child devices) Serial.println("Presenting Nodes"); Serial.println("________________"); #ifdef ID_S_DOOR Serial.println(" S_DOOR"); present(ID_S_DOOR,S_DOOR,"Outside Door"); wait(SHORT_WAIT); #endif #ifdef ID_S_MOTION Serial.println(" S_MOTION"); present(ID_S_MOTION,S_MOTION,"Outside Motion"); wait(SHORT_WAIT); #endif #ifdef ID_S_SMOKE Serial.println(" S_SMOKE"); present(ID_S_SMOKE,S_SMOKE,"Kitchen Smoke"); wait(SHORT_WAIT); #endif #ifdef ID_S_LIGHT Serial.println(" S_LIGHT"); present(ID_S_LIGHT,S_LIGHT,"Hall Light"); wait(SHORT_WAIT); #endif #ifdef ID_S_DIMMER Serial.println(" S_DIMMER"); present(ID_S_DIMMER,S_DIMMER,"Living room dimmer"); wait(SHORT_WAIT); #endif #ifdef ID_S_COVER Serial.println(" S_COVER"); present(ID_S_COVER,S_COVER,"Window cover"); wait(SHORT_WAIT); #endif #ifdef ID_S_TEMP Serial.println(" S_TEMP"); present(ID_S_TEMP,S_TEMP,"House Temperarue"); wait(SHORT_WAIT); #endif #ifdef ID_S_HUM Serial.println(" S_HUM"); present(ID_S_HUM,S_HUM,"Current Humidity"); wait(SHORT_WAIT); #endif #ifdef ID_S_BARO Serial.println(" S_BARO"); present(ID_S_BARO,S_BARO," Air pressure"); wait(SHORT_WAIT); #endif #ifdef ID_S_WIND Serial.println(" S_WIND"); present(ID_S_WIND,S_WIND,"Wind Station"); wait(SHORT_WAIT); #endif #ifdef ID_S_RAIN Serial.println(" S_RAIN"); present(ID_S_RAIN,S_RAIN,"Rain Station"); wait(SHORT_WAIT); #endif #ifdef ID_S_UV Serial.println(" S_UV"); present(ID_S_UV,S_UV,"Ultra Violet"); wait(SHORT_WAIT); #endif #ifdef ID_S_WEIGHT Serial.println(" S_WEIGHT"); present(ID_S_WEIGHT,S_WEIGHT,"Outdoor Scale"); wait(SHORT_WAIT); #endif #ifdef ID_S_POWER Serial.println(" S_POWER"); present(ID_S_POWER,S_POWER,"Power Metric"); wait(SHORT_WAIT); #endif #ifdef ID_S_HEATER Serial.println(" S_HEATER"); present(ID_S_HEATER,S_HEATER,"Garage Heater"); wait(SHORT_WAIT); #endif #ifdef ID_S_DISTANCE Serial.println(" S_DISTANCE"); present(ID_S_DISTANCE,S_DISTANCE,"Distance Measure"); wait(SHORT_WAIT); #endif #ifdef ID_S_LIGHT_LEVEL Serial.println(" S_LIGHT_LEVEL"); present(ID_S_LIGHT_LEVEL,S_LIGHT_LEVEL,"Outside Light Level"); wait(SHORT_WAIT); #endif #ifdef ID_S_LOCK Serial.println(" S_LOCK"); present(ID_S_LOCK,S_LOCK,"Front Door Lock"); wait(SHORT_WAIT); #endif #ifdef ID_S_IR Serial.println(" S_IR"); present(ID_S_IR,S_IR,"Univeral Command"); wait(SHORT_WAIT); #endif #ifdef ID_S_WATER Serial.println(" S_WATER"); present(ID_S_WATER,S_WATER,"Water Level"); wait(SHORT_WAIT); #endif #ifdef ID_S_AIR_QUALITY Serial.println(" S_AIR_QUALITY"); present(ID_S_AIR_QUALITY,S_AIR_QUALITY,"Air Station"); wait(SHORT_WAIT); #endif #ifdef ID_S_DUST Serial.println(" S_DUST"); present(ID_S_DUST,S_DUST,"Dust Level"); wait(SHORT_WAIT); #endif #ifdef ID_S_SCENE_CONTROLLER Serial.println(" S_SCENE_CONTROLLER"); present(ID_S_SCENE_CONTROLLER,S_SCENE_CONTROLLER,"Scene Controller"); wait(SHORT_WAIT); #endif #ifdef ID_S_RGB_LIGHT Serial.println(" RGB_LIGHT"); present(ID_S_RGB_LIGHT,S_RGB_LIGHT,"Mood Light"); wait(SHORT_WAIT); #endif #ifdef ID_S_RGBW_LIGHT Serial.println(" RGBW_LIGHT"); present(ID_S_RGBW_LIGHT,S_RGBW_LIGHT,"Mood Light 2"); wait(SHORT_WAIT); #endif #ifdef ID_S_COLOR_SENSOR Serial.println(" COLOR_SENSOR"); present(ID_S_COLOR_SENSOR,S_COLOR_SENSOR,"Hall Painting"); wait(SHORT_WAIT); #endif #ifdef ID_S_HVAC Serial.println(" HVAC"); present(ID_S_HVAC,S_HVAC,"HVAC"); wait(SHORT_WAIT); #endif #ifdef ID_S_MULTIMETER Serial.println(" MULTIMETER"); present(ID_S_MULTIMETER,S_MULTIMETER,"Electric Staion"); wait(SHORT_WAIT); #endif #ifdef ID_S_SPRINKLER #endif #ifdef ID_S_WATER_LEAK #endif #ifdef ID_S_SOUND #endif #ifdef ID_S_VIBRATION #endif #ifdef ID_S_MOISTURE #endif #ifdef ID_S_MOISTURE Serial.println(" S_MOISTURE"); present(ID_S_MOISTURE,S_MOISTURE,"Basement Sensor"); wait(SHORT_WAIT); #endif #ifdef ID_S_CUSTOM Serial.println(" S_CUSTOM"); present(ID_S_CUSTOM,S_CUSTOM,"Other Stuff"); wait(SHORT_WAIT); #endif Serial.println("________________"); } void loop() { Serial.println(""); Serial.println(""); Serial.println(""); Serial.println("#########################"); randNumber=random(0,101); Serial.print("RandomNumber:"); Serial.println(randNumber); // Send fake battery level Serial.println("Send Battery Level"); sendBatteryLevel(randNumber); wait(LONG_WAIT); // Request time Serial.println("Request Time"); requestTime(); wait(LONG_WAIT); //Read Sensors #ifdef ID_S_DOOR door(); #endif #ifdef ID_S_MOTION motion(); #endif #ifdef ID_S_SMOKE smoke(); #endif #ifdef ID_S_LIGHT light(); #endif #ifdef ID_S_DIMMER dimmer(); #endif #ifdef ID_S_COVER cover(); #endif #ifdef ID_S_TEMP temp(); #endif #ifdef ID_S_HUM hum(); #endif #ifdef ID_S_BARO baro(); #endif #ifdef ID_S_WIND wind(); #endif #ifdef ID_S_RAIN rain(); #endif #ifdef ID_S_UV uv(); #endif #ifdef ID_S_WEIGHT weight(); #endif #ifdef ID_S_POWER power(); #endif #ifdef ID_S_HEATER heater(); #endif #ifdef ID_S_DISTANCE distance(); #endif #ifdef ID_S_LIGHT_LEVEL light_level(); #endif #ifdef ID_S_LOCK lock(); #endif #ifdef ID_S_IR ir(); #endif #ifdef ID_S_WATER water(); #endif #ifdef ID_S_AIR_QUALITY air(); #endif #ifdef ID_S_DUST dust(); #endif #ifdef ID_S_SCENE_CONTROLLER scene(); #endif #ifdef ID_S_RGB_LIGHT rgbLight(); #endif #ifdef ID_S_RGBW_LIGHT rgbwLight(); #endif #ifdef ID_S_COLOR_SENSOR color(); #endif #ifdef ID_S_HVAC hvac(); #endif #ifdef ID_S_MULTIMETER multimeter(); #endif #ifdef ID_S_SPRINKLER #endif #ifdef ID_S_WATER_LEAK #endif #ifdef ID_S_SOUND #endif #ifdef ID_S_VIBRATION #endif #ifdef ID_S_MOISTURE #endif #ifdef ID_S_MOISTURE moisture(); #endif #ifdef ID_S_CUSTOM custom(); #endif sendBatteryLevel(randNumber); wait(SHORT_WAIT); Serial.println("#########################"); wait(SLEEP_TIME); //sleep a bit } // This is called when a new time value was received void receiveTime(unsigned long controllerTime) { Serial.print("Time value received: "); Serial.println(controllerTime); } //void door(){} #ifdef ID_S_DOOR void door() { Serial.print("Door is: " ); if (randNumber <= 50) { Serial.println("Open"); send(msg_S_DOOR_T.set((int16_t)1)); } else { Serial.println("Closed"); send(msg_S_DOOR_T.set((int16_t)0)); } #ifdef ID_S_ARMED Serial.print("System is: " ); Serial.println((isArmed ? "Armed":"Disarmed")); send(msg_S_DOOR_A.set(isArmed)); #endif } #endif #ifdef ID_S_MOTION void motion() { Serial.print("Motion is: " ); if (randNumber <= 50) { Serial.println("Active"); send(msg_S_MOTION_T.set((uint16_t) 1)); } else { Serial.println("Quiet"); send(msg_S_MOTION_T.set((uint16_t) 0)); } #ifdef ID_S_ARMED Serial.print("System is: " ); Serial.println((isArmed ? "Armed":"Disarmed")); send(msg_S_MOTION_A.set(isArmed)); #endif } #endif #ifdef ID_S_SMOKE void smoke() { Serial.print("Smoke is: " ); if (randNumber <= 50) { Serial.println("Active"); send(msg_S_SMOKE_T.set((uint16_t) 1)); } else { Serial.println("Quiet"); send(msg_S_SMOKE_T.set((uint16_t) 0)); } #ifdef ID_S_ARMED Serial.print("System is: " ); Serial.println((isArmed ? "Armed":"Disarmed")); send(msg_S_SMOKE_A.set(isArmed)); #endif } #endif #ifdef ID_S_LIGHT void light() { Serial.print("Light is: " ); Serial.println((isLightOn ? "On":"Off")); send(msg_S_LIGHT.set(isLightOn)); } #endif #ifdef ID_S_DIMMER void dimmer() { Serial.print("Dimmer is set to: " ); Serial.println(dimmerVal); send(msg_S_DIMMER.set(dimmerVal)); } #endif #ifdef ID_S_COVER void cover() { Serial.print("Cover is : " ); if (coverState == 1) { Serial.println("Opening"); send(msg_S_COVER_U.set((uint16_t) 1)); } else if (coverState == -1) { Serial.println("Closing"); send(msg_S_COVER_D.set((uint16_t) 0)); } else { Serial.println("Idle"); send(msg_S_COVER_S.set((uint16_t) -1)); } send(msg_S_COVER_V.set((uint16_t) coverState)); } #endif #ifdef ID_S_TEMP void temp() { Serial.print("Temperature is: " ); Serial.println(map(randNumber,1,100,0,45)); send(msg_S_TEMP.set(map(randNumber,1,100,0,45))); } #endif #ifdef ID_S_HUM void hum() { Serial.print("Humitidty is: " ); Serial.println(randNumber); send(msg_S_HUM.set(randNumber)); } #endif #ifdef ID_S_BARO void baro() { const char *weather[] = {"stable","sunny","cloudy","unstable","thunderstorm","unknown"}; long pressure = map(randNumber,1,100,870,1086);// hPa? int forecast = map(randNumber,1,100,0,5); Serial.print("Atmosferic Pressure is: " ); Serial.println(pressure); send(msg_S_BARO_P.set(pressure)); Serial.print("Weather forecast: " ); Serial.println(weather[forecast]); send(msg_S_BARO_F.set(weather[forecast])); } #endif #ifdef ID_S_WIND void wind() { Serial.print("Wind Speed is: " ); Serial.println(randNumber); send(msg_S_WIND_S.set(randNumber)); Serial.print("Wind Gust is: " ); Serial.println(randNumber+10); send(msg_S_WIND_G.set(randNumber+10)); Serial.print("Wind Direction is: " ); Serial.println(map(randNumber,1,100,0,360)); send(msg_S_WIND_D.set(map(randNumber,1,100,0,360))); } #endif #ifdef ID_S_RAIN void rain() { Serial.print("Rain ammount is: " ); Serial.println(randNumber); send(msg_S_RAIN_A.set(randNumber)); Serial.print("Rain rate is: " ); Serial.println(randNumber/60); send(msg_S_RAIN_R.set(randNumber/60,1)); } #endif #ifdef ID_S_UV void uv() { Serial.print("Ultra Violet level is: " ); Serial.println(map(randNumber,1,100,0,15)); send(msg_S_UV.set(map(randNumber,1,100,0,15))); } #endif #ifdef ID_S_WEIGHT void weight() { Serial.print("Weight is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_WEIGHT.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_POWER void power() { Serial.print("Watt is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_POWER_W.set(map(randNumber,1,100,0,150))); Serial.print("KWH is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_POWER_K.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_HEATER void heater() { // float heater_setpoint=21.5; // float heater_temp=23.5; // bool heater_status=false; // String heatState="Off"; Serial.print("Heater flow state is: " ); Serial.println(heater_flow_state); send(msg_S_HEATER_FLOW_STATE.set(heater_flow_state.c_str())); // Serial.print("Heater on/off is: " ); // Serial.println((heater_status==true)?"On":"Off"); // send(msg_S_HEATER_STATUS.set(heater_status)); // Serial.print("Heater Temperature is: " ); // Serial.println(heater_temp,1); // send(msg_S_HEATER_TEMP.set(heater_temp,1)); Serial.print("Heater Setpoint: " ); Serial.println(heater_setpoint,1); send(msg_S_HEATER_SET_POINT.set(heater_setpoint,1)); } #endif #ifdef ID_S_DISTANCE void distance() { Serial.print("Distance is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_DISTANCE.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_LIGHT_LEVEL void light_level() { Serial.print("Light is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_LIGHT_LEVEL.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_LOCK void lock() { Serial.print("Lock is: " ); Serial.println((isLocked ? "Locked":"Unlocked")); send(msg_S_LOCK.set(isLocked)); } #endif #ifdef ID_S_IR void ir() { Serial.print("Infrared is: " ); Serial.println(irVal); send(msg_S_IR_S.set(irVal)); send(msg_S_IR_R.set(irVal)); } #endif #ifdef ID_S_WATER void water() { Serial.print("Water flow is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_WATER_F.set(map(randNumber,1,100,0,150))); Serial.print("Water volume is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_WATER_V.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_AIR_QUALITY void air() { Serial.print("Air Quality is: " ); Serial.println(randNumber); send(msg_S_AIR_QUALITY.set(randNumber)); } #endif #ifdef ID_S_DUST void dust() { Serial.print("Dust level is: " ); Serial.println(randNumber); send(msg_S_DUST.set(randNumber)); } #endif #ifdef ID_S_SCENE_CONTROLLER void scene() { Serial.print("Scene is: " ); Serial.println(scenes[sceneVal]); if(sceneValPrevious != sceneVal) { send(msg_S_SCENE_CONTROLLER_OF.set((uint16_t) sceneValPrevious)); send(msg_S_SCENE_CONTROLLER_ON.set((uint16_t) sceneVal)); sceneValPrevious=sceneVal; } } #endif #ifdef ID_S_RGB_LIGHT void rgbLight() { Serial.print("RGB Light state is: " ); Serial.println(rgbState); send(msg_S_RGB_LIGHT_V_RGB.set(rgbState.c_str())); Serial.print("RGB Light Watt is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_RGB_LIGHT_V_WATT.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_RGBW_LIGHT void rgbwLight() { Serial.print("RGBW Light state is: " ); Serial.println(rgbwState); send(msg_S_RGBW_LIGHT_V_RGBW.set(rgbwState.c_str())); Serial.print("RGBW Light Watt is: " ); Serial.println(map(randNumber,1,100,0,150)); send(msg_S_RGBW_LIGHT_V_WATT.set(map(randNumber,1,100,0,150))); } #endif #ifdef ID_S_COLOR_SENSOR void color() { String colorState; String red = String(random(0,256),HEX); String green = String(random(0,256),HEX); String blue = String(random(0,256),HEX); colorState=String(red + green + blue); Serial.print("Color state is: " ); Serial.println(colorState); send(msg_S_COLOR_SENSOR_V_RGB.set(colorState.c_str())); } #endif #ifdef ID_S_HVAC void hvac() { // float hvac_SetPointHeat = 16.5; // float hvac_SetPointCool = 25.5; // String hvac_FlowState = "AutoChangeOver"; // String hvac_FlowMode = "Auto"; // String hvac_Speed = "Normal"; Serial.print("HVAC Set Point Heat is: " ); Serial.println(hvac_SetPointHeat); send(msg_S_HVAC_V_HVAC_SETPOINT_HEAT.set(hvac_SetPointHeat,1)); Serial.print("HVAC Set Point Cool is: " ); Serial.println(hvac_SetPointCool); send(msg_S_HVAC_V_HVAC_SETPOINT_COOL.set(hvac_SetPointCool,1)); Serial.print("HVAC Flow State is: " ); Serial.println(hvac_FlowState); send(msg_S_HVAC_V_HVAC_FLOW_STATET.set(hvac_FlowState.c_str())); Serial.print("HVAC Flow Mode is: " ); Serial.println(hvac_FlowMode); send(msg_S_HVAC_V_HVAC_FLOW_MODE.set(hvac_FlowMode.c_str())); Serial.print("HVAC Speed is: " ); Serial.println(hvac_Speed); send(msg_S_HVAC_V_HVAC_SPEED.set(hvac_Speed.c_str())); } #endif #ifdef ID_S_MULTIMETER void multimeter() { uint16_t impedance=map(randNumber,1,100,0,15000); uint16_t volt=map(randNumber,1,100,0,380); uint16_t amps=map(randNumber,1,100,0,16); Serial.print("Impedance is: " ); Serial.println(impedance); send(msg_S_MULTIMETER_V_IMPEDANCE.set(impedance)); Serial.print("Voltage is: " ); Serial.println(volt); send(msg_S_MULTIMETER_V_VOLTAGE.set(volt)); Serial.print("Current is: " ); Serial.println(amps); send(msg_S_MULTIMETER_V_CURRENT.set(amps)); } #endif #ifdef ID_S_SPRINKLER #endif #ifdef ID_S_WATER_LEAK #endif #ifdef ID_S_SOUND #endif #ifdef ID_S_VIBRATION #endif #ifdef ID_S_MOISTURE #endif #ifdef ID_S_MOISTURE void moisture() { Serial.print("Moisture level is: " ); Serial.println(randNumber); send(msg_S_MOISTURE.set(randNumber)); } #endif #ifdef ID_S_CUSTOM void custom() { Serial.print("Custom value is: " ); Serial.println(randNumber); send(msg_S_CUSTOM_1.set(randNumber)); send(msg_S_CUSTOM_2.set(randNumber)); send(msg_S_CUSTOM_3.set(randNumber)); send(msg_S_CUSTOM_4.set(randNumber)); send(msg_S_CUSTOM_5.set(randNumber)); } #endif void receive(const MyMessage &message) { switch (message.type) { #ifdef ID_S_ARMED case V_ARMED: isArmed = message.getBool(); Serial.print("Incoming change for ID_S_ARMED:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println((isArmed ? "Armed":"Disarmed" )); #ifdef ID_S_DOOR door();//temp ack for door #endif #ifdef ID_S_MOTION motion();//temp ack #endif #ifdef ID_S_SMOKE smoke();//temp ack #endif break; #endif case V_STATUS: // V_LIGHT: #ifdef ID_S_LIGHT if(message.sensor==ID_S_LIGHT) { isLightOn = message.getBool(); Serial.print("Incoming change for ID_S_LIGHT:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println((isLightOn ? "On":"Off")); light(); // temp ack } #endif // #ifdef ID_S_HEATER // if(message.sensor == ID_S_HEATER){ // heater_status = message.getBool(); // Serial.print("Incoming change for ID_S_HEATER:"); // Serial.print(message.sensor); // Serial.print(", New status: "); // Serial.println(heater_status); // heater();//temp ack // } // #endif break; #ifdef ID_S_DIMMER case V_DIMMER: if ((message.getInt()<0)||(message.getInt()>100)) { Serial.println( "V_DIMMER data invalid (should be 0..100)" ); break; } dimmerVal= message.getInt(); Serial.print("Incoming change for ID_S_DIMMER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(message.getInt()); dimmer();// temp ack break; #endif #ifdef ID_S_COVER case V_UP: coverState=1; Serial.print("Incoming change for ID_S_COVER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println("V_UP"); cover(); // temp ack break; case V_DOWN: coverState=-1; Serial.print("Incoming change for ID_S_COVER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println("V_DOWN"); cover(); //temp ack break; case V_STOP: coverState=0; Serial.print("Incoming change for ID_S_COVER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println("V_STOP"); cover(); //temp ack break; #endif case V_HVAC_SETPOINT_HEAT: #ifdef ID_S_HEATER if(message.sensor == ID_S_HEATER) { heater_setpoint=message.getFloat(); Serial.print("Incoming set point for ID_S_HEATER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(heater_setpoint,1); heater();//temp ack } #endif #ifdef ID_S_HVAC if(message.sensor == ID_S_HVAC) { hvac_SetPointHeat=message.getFloat(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_SetPointHeat,1); hvac();//temp ack } #endif break; case V_HVAC_FLOW_STATE: #ifdef ID_S_HEATER if(message.sensor == ID_S_HEATER) { heater_flow_state=message.getString(); Serial.print("Incoming flow state change for ID_S_HEATER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(heater_flow_state); heater();//temp ack } #endif #ifdef ID_S_HVAC if(message.sensor == ID_S_HVAC) { hvac_FlowState=message.getString(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_FlowState); hvac();//temp ack } #endif break; #ifdef ID_S_LOCK case V_LOCK_STATUS: isLocked = message.getBool(); Serial.print("Incoming change for ID_S_LOCK:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(message.getBool()?"Locked":"Unlocked"); lock(); //temp ack break; #endif #ifdef ID_S_IR case V_IR_SEND: irVal = message.getLong(); Serial.print("Incoming change for ID_S_IR:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(irVal); ir(); // temp ack break; case V_IR_RECEIVE: irVal = message.getLong(); Serial.print("Incoming change for ID_S_IR:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(irVal); ir(); // temp ack break; #endif #ifdef ID_S_SCENE_CONTROLLER case V_SCENE_ON: sceneVal = message.getInt(); Serial.print("Incoming change for ID_S_SCENE_CONTROLLER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.print(scenes[sceneVal]); Serial.println(" On"); scene();// temp ack break; case V_SCENE_OFF: sceneVal = message.getInt(); Serial.print("Incoming change for ID_S_SCENE_CONTROLLER:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.print(scenes[sceneVal]); Serial.println(" Off"); scene();// temp ack break; #endif #ifdef ID_S_RGB_LIGHT case V_RGB: rgbState=message.getString(); Serial.print("Incoming flow state change for ID_S_RGB_LIGHT:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(rgbState); rgbLight(); // temp ack break; #endif #ifdef ID_S_RGBW_LIGHT case V_RGBW: rgbwState=message.getString(); Serial.print("Incoming flow state change for ID_S_RGBW_LIGHT:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(rgbwState); rgbwLight(); break; #endif #ifdef ID_S_HVAC // hvac_SetPointHeat // hvac_SetPointCool // hvac_FlowState // hvac_FlowMode // hvac_Speed case V_HVAC_SETPOINT_COOL: hvac_SetPointCool=message.getFloat(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_SetPointCool,1); hvac();//temp ack break; case V_HVAC_FLOW_MODE: hvac_Speed=message.getString(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_Speed); hvac();//temp ack break; case V_HVAC_SPEED: hvac_FlowMode=message.getString(); Serial.print("Incoming set point for ID_S_HVAC:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(hvac_FlowMode); hvac();//temp ack break; #endif default: Serial.print("Unknown/UnImplemented message type: "); Serial.println(message.type); } }```
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@rmtucker said in
MySensors NRF5 Platform:After trawling through posts on the forum the following changes compile ok.
Altered int to uint16_tThis issue seems to be an 32 bit platform issue. With SAMD I see equal error messages. This needs fixing at message level.
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@d00616
So is this a mysensors issue and will you rase this issue please.
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@rmtucker said in
MySensors NRF5 Platform:So is this a mysensors issue and will you rase this issue please.
I have ask the other members of the core team if someone can take a look at this issue. I have time to do this not earlier than Sunday.
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@NeverDie
Just wondering about mysensors debug.
If you have the jlink plugged in for programming but you also want to see the mysensors debug.
Where is the ftdi adapter plugged in to for tx and rx ?
And also i suspect that the vcc is not connected on the ftdi adapter because the jlink is supplying the board?
Oh so many questions??
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@rmtucker said in
MySensors NRF5 Platform:Where is the ftdi adapter plugged in to for tx and rx ?
That's determined by the "board" that you tell the compiler you are using. For example, on the nRF52 DK, the Rx pin is on P0.06. Presently, for simplicity, when I compile for the Ebyte module, I tell the Arduino IDE that it's an nRF52 DK, so then Rx is also on P0.06 and Tx is on P0.08.
A more advanced way of doing it is to tell the Arduino IDE that the board is a "MyNrf5Board nRF52832", and then you can use d00616's method of pin mapping to make the Rx pin whichever of the mappable pins you want. That's a bit more involved though.And also i suspect that the vcc is not connected on the ftdi adapter because the jlink is supplying the board?
Right. For old fashioned debugging using serial.println(), just Rx and GND is all I use.
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@NeverDie
Disappointed so far with the NRF51822.
Basically it can not connect to any i2c sensors which mysensors relies on heavily.
So not a lot can be done with it.
It does integrate with mysensors well though,proved that with mockmysensors sketch.
I dare not even try the spi interface.
I would advise not trying this till the i2c problems are sorted out.
At the moment it is running Blinky and thats it.
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@rmtucker can't you just bit bang the I2C sensors? Should not be any mcu incapable of that. There should be plenty drivers available that implement a bit banged I2C driver.
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@Anticimex
I managed to get a nokia 5110 display connected and working using the u8glib and softspi.
I can not get the easier to use adafruit library to compile though.
Nor have i been able to find a Soft i2c library that will compile without errors.
So i am afraid i2c is still a non starter.
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@rmtucker said in
MySensors NRF5 Platform:So i am afraid i2c is still a non starter.
maybe try this one https://github.com/felias-fogg/SlowSoftWire
I don't use it, but it compiles fine for nrf52. I already tested it a while ago, and it worked for me.
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@scalz
my head is battered with this.
tried the library you mentioned and it compiled fine but still gave spurious readings.
so i plugged the htu21d back in to a nano and used the sparkfun library demo.
the readings were perfect.
so frustrated with this because all my nodes use i2c sensors.
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@rmtucker
Stupid question, but are your i2c sensors getting all the voltage that they need? After all, a nano runs at 5v, right? I know that some of the TH i2c sensors include voltage regulators, which would drop the voltage even further. If necessary, those could be removed. That's what I generally do.
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@NeverDie
Yes They are 3.3v sensors.
What we need is someone else using nrf51822 and i2c sensors that can shine some light.
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@rmtucker said in
MySensors NRF5 Platform:@NeverDie
Yes They are 3.3v sensors.
What we need is someone else using nrf51822 and i2c sensors that can shine some light.I'll try soon, hopefully I'll have time tomorrow, my nrf51 module is soldered on a breadboard. I need to make the promised tests on the nrf52 too ...
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@Nca78
Just an observation after many hours of tinkering.
There is no problem reading one byte back from i2c,like when doing an i2c scan.
It comes back with the address of the htu21d no problem.
But if you try to read 3 bytes which is what you do when reading the temp etc,it goes T*TS up.
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Well guys after all that
I had not installed the development version from git.
After installling the development version the i2c is working fine.
Suprised no one else has done this??From git (for core development) Follow steps from Board Manager section above cd <SKETCHBOOK>, where <SKETCHBOOK> is your Arduino Sketch folder: OS X: ~/Documents/Arduino Linux: ~/Arduino Windows: ~/Documents/Arduino Create a folder named hardware, if it does not exist, and change directories to it Clone this repo: git clone https://github.com/sandeepmistry/arduino-nRF5.git sandeepmistry/nRF5 Restart the Arduino IDE```
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Please can someone update the instructions below to mention installing the development version
Preparing Arduino Arduino doesn't support the nRF5 platform in a standard setup. You have to add the arduino-nRF5 platform via Arduino's Board Manager like described in https://github.com/sandeepmistry/arduino-nRF5/#installing
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@rmtucker said in
MySensors NRF5 Platform:Please can someone update the instructions below to mention installing the development version
Preparing Arduino Arduino doesn't support the nRF5 platform in a standard setup. You have to add the arduino-nRF5 platform via Arduino's Board Manager like described in https://github.com/sandeepmistry/arduino-nRF5/#installing@d00616 maybe ?
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If there are multiple libraries with the same name (as there seem to be), then how does the compiler know which one to pick? Is it just the first one whose name matches in whatever pathway it follows? Since it obviously compiled even though rmtucker was missing the proper libraries... this just sounds like a heartache waiting to happen unless everything is setup just-so. rmtucker's case seems to prove there won't be any warnings if it picks the wrong one.
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looking at d00616 howto it's explained to use Mysensors development branch (or maybe he added it today
). but that makes sense as this port is newer than master branch.@NeverDie
it uses the core libraries depending on the board used in Arduino.
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@scalz: I think @rmtucker was discussing using the development version of the sandeepmistry nrf5 Arduino library, it was not related to the MySensors library.
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@mfalkvidd
Sorry i should have made it more understandable.
When you follow the instructions below as per sandeeps site it does not install the latest NR5 libraries that you see on github.Installing Board Manager Download and install the Arduino IDE (At least v1.6.12) Start the Arduino IDE Go into Preferences Add https://sandeepmistry.github.io/arduino-nRF5/package_nRF5_boards_index.json as an "Additional Board Manager URL" Open the Boards Manager from the Tools -> Board menu and install "Nordic Semiconductor nRF5 Boards" Select your nRF5 board from the Tools -> Board menuFollowing this you must install the development version aswell which is what you see on github by doing this.
From git (for core development) Follow steps from Board Manager section above cd <SKETCHBOOK>, where <SKETCHBOOK> is your Arduino Sketch folder: OS X: ~/Documents/Arduino Linux: ~/Arduino Windows: ~/Documents/Arduino Create a folder named hardware, if it does not exist, and change directories to it Clone this repo: git clone https://github.com/sandeepmistry/arduino-nRF5.git sandeepmistry/nRF5 Restart the Arduino IDEOtherwise you run into all kinds of problems using the old library.
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I have added a note at the end of the installation documentation. To make things easier, I have opened an issue to update the Arduino-nRF5 release.
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I2C should be fixed now. Version 0.4.0 is released!
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@d00616
So should i be able to delete the hardware folder that the development version created from github and just update from boards manager?.
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@rmtucker said in
MySensors NRF5 Platform:So should i be able to delete the hardware folder that the development version created from github and just update from boards manager?.
If this don't work, remove all folder created by hardware and boards manager, close Arduino IDE and reinstall it via Boards Manager.
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Hi, I don't us nrf52 yet but as i'm a platformio supporter, There is a new release for nrf52 platform with initial arduino framework support ! Good news, i think I will test nrf52 in few weeks.
https://github.com/platformio/platform-nordicnrf52/releases/tag/v1.2.0
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@d00616 said in
MySensors NRF5 Platform:I2C should be fixed now. Version 0.4.0 is released!
To help clarify for others who are reading this: the Arduino IDE board manager let me upgrade to 0.4.0 from 0.3.0 by just clicking on the board entry "Nordic Semiconductor NRF5 Boards by Sandeep Mistry", selecting the 0.4.0 version, and then clicking Install.
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- I have updated the radio driver with fixes for some hardware errata.
- I have updated the https://github.com/mysensors/ArduinoHwNRF5 with an enhanced definition format. File name and contents are changed! The board description is compatible with the NRF5 variant provided by Arduino, but it's not possible to use this variant at the moment.
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@d00616 said in
MySensors NRF5 Platform:I have updated the radio driver with fixes for some hardware errata.
Where do we find the update? i.e. is it baked into the regular MySensors development code thread, or is it elsewhere?
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I'm guessing it's this one? https://github.com/mysensors/ArduinoHwNRF5
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I refreshed all the libraries. I'm able to compile and upload my sketches, but now it complains a lot about "invalid libraries."
WARNING: Spurious .ci folder in 'MySensors' library WARNING: Spurious .mystools folder in 'MySensors' library Sketch uses 3836 bytes (0%) of program storage space. Maximum is 524288 bytes. Open On-Chip Debugger 0.10.0-dev-00254-g696fc0a (2016-04-10-10:13) Licensed under GNU GPL v2 For bug reports, read http://openocd.org/doc/doxygen/bugs.html debug_level: 0 0 adapter speed: 10000 kHz cortex_m reset_config sysresetreq nrf52.cpu: target state: halted target halted due to debug-request, current mode: Thread xPSR: 0x01000000 pc: 0x000006e8 msp: 0x20010000 ** Programming Started ** auto erase enabled wrote 4096 bytes from file C:\Users\David\AppData\Local\Temp\arduino_build_255419/Interrupt_button_test_v005.ino.hex in 0.800001s (5.000 KiB/s) ** Programming Finished ** ** Verify Started ** verified 3964 bytes in 0.060000s (64.518 KiB/s) ** Verified OK ** ** Resetting Target ** shutdown command invoked Invalid library found in C:\Users\David\Documents\Arduino\libraries\arduino-nRF5: C:\Users\David\Documents\Arduino\libraries\arduino-nRF5 Invalid library found in C:\Users\David\Documents\Arduino\libraries\ArduinoHwNRF5: C:\Users\David\Documents\Arduino\libraries\ArduinoHwNRF5 Invalid library found in C:\Users\David\Documents\Arduino\libraries\arduino-nRF5: C:\Users\David\Documents\Arduino\libraries\arduino-nRF5 Invalid library found in C:\Users\David\Documents\Arduino\libraries\ArduinoHwNRF5: C:\Users\David\Documents\Arduino\libraries\ArduinoHwNRF5
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@NeverDie said in
MySensors NRF5 Platform:I refreshed all the libraries. I'm able to compile and upload my sketches, but now it complains a lot about "invalid libraries."
At the moment, I cannot reproduce this with Linux and Arduino 1.8.2. I try to find out what's wrong.
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@d00616 said in
MySensors NRF5 Platform:@NeverDie said in
MySensors NRF5 Platform:I refreshed all the libraries. I'm able to compile and upload my sketches, but now it complains a lot about "invalid libraries."
At the moment, I cannot reproduce this with Linux and Arduino 1.8.2. I try to find out what's wrong.
Can you try to remove the .ci and .mystools folders?
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@d00616 said in
MySensors NRF5 Platform:Can you try to remove the .ci and .mystools folders?
Done. So, here it is now:
Archiving built core (caching) in: C:\Users\David\AppData\Local\Temp\arduino_cache_16539\core\core_MySensors_nRF5_MyBoard_nRF52832_bootcode_none,lfclk_lfxo,reset_notenable_2d457965a40837233e636c052c58b359.a Sketch uses 3872 bytes (0%) of program storage space. Maximum is 524288 bytes. Open On-Chip Debugger 0.10.0-dev-00254-g696fc0a (2016-04-10-10:13) Licensed under GNU GPL v2 For bug reports, read http://openocd.org/doc/doxygen/bugs.html debug_level: 0 0 adapter speed: 10000 kHz cortex_m reset_config sysresetreq nrf52.cpu: target state: halted target halted due to debug-request, current mode: Thread xPSR: 0x01000000 pc: 0x0000070c msp: 0x20010000 ** Programming Started ** auto erase enabled wrote 4096 bytes from file C:\Users\David\AppData\Local\Temp\arduino_build_610023/Interrupt_button_test_v006.ino.hex in 0.800001s (5.000 KiB/s) ** Programming Finished ** ** Verify Started ** verified 4000 bytes in 0.060000s (65.104 KiB/s) ** Verified OK ** ** Resetting Target ** shutdown command invoked Invalid library found in C:\Users\David\Documents\Arduino\libraries\arduino-nRF5: C:\Users\David\Documents\Arduino\libraries\arduino-nRF5 Invalid library found in C:\Users\David\Documents\Arduino\libraries\ArduinoHwNRF5: C:\Users\David\Documents\Arduino\libraries\ArduinoHwNRF5 Invalid library found in C:\Users\David\Documents\Arduino\libraries\arduino-nRF5: C:\Users\David\Documents\Arduino\libraries\arduino-nRF5 Invalid library found in C:\Users\David\Documents\Arduino\libraries\ArduinoHwNRF5: C:\Users\David\Documents\Arduino\libraries\ArduinoHwNRF5BTW, I'm using the Windows version of Arduino IDE 1.8.5, which is the most current.
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@NeverDie said in
MySensors NRF5 Platform:BTW, I'm using the Windows version of Arduino IDE 1.8.5, which is the most current.
I don't know the correct path on an Windows system. On my system the Sketches are in the ~/Arduino folder in my home directory (~). The arduino-nrf5 is in ~/.arduino15/packages/sandeepmistry/hardware/nRF5/0.4.0 and the ArduinoHwNRF5 files are in ~/.arduino15/packages/MySensors/hardware/nRF5/0.2.1
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on my Windows machine, all boards are located in c:\Users<username>\AppData\Local\Arduino15\packages
Strange that they've been installed to C:\Users\David\Documents\Arduino\libraries\ on your machine.Maybe just delete the folders and re-install using the board manager?
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@mfalkvidd All I know is that if I put a library in the folder: C:\Users\David\Documents\Arduino\libraries
it always gets detected and used. It also means you can completely uninstall/re-install the arduino IDE, and nothing gets lost. I'm not sure about other locations.Am I the only one doing it this way?
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@NeverDie for libraries, doing what you do should result in the same behavior as when using the Library Manager.
But I'm not sure it works with boards (especially given that the Arduino IDE complains when you put boards in the libraries folder).
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I use the board manager to manage the boards. I believe it connects directly into github.
Anyhow, I stripped out all the non-library stuff, and now Windows IDE works without complaining.
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Has anyone here yet figured out how to have more than one type of interrupt at a time wake-up the MCU from sleep? Based on the examples so far, it seems as though only one type at a time can be active. I'm sure there must be some way to do it. For instance, it would be desirable if the MCU could wake up not just from a timer event every, say, 5 minutes, to take a temperature reading, but also immediately if there is a leak detected. Right now it's just one or the other.
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So we can not use the normal statement
int8_t sleep(int interrupt, int mode, unsigned long ms=0);
I did not realize that was the case as i have never tried it.
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I believe hwSleep(..) is the preferred incantation, but beyond that I'm not sure of anything. Maybe @d00616 can comment?
I should be receiving a number of different PCB projects tomorrow for final assembly and test, and if I can't resolve this soon, I'm simply going to release them without full demo code.
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@NeverDie said in
MySensors NRF5 Platform:I believe hwSleep(..) is the preferred incantation, but beyond that I'm not sure of anything.
In MySensors, the regular way to use sleep mode is by using the sleep() functions:
https://www.mysensors.org/download/sensor_api_20#sleepingBut like you said, you can also use the raw hwSleep() from the hw abstraction layer. Or you could also rewrite it!
Which means at each abstraction layer, there are additional logics. sleep() functions have more logics (regarding MySensors states and features) than the raw hwSleep for example (like testing if there is an ongoing ota, smartsleep, heartbeat etc..). I have nodes where i use raw or not, but it's good to know what's behind.
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@scalz
So the statement
int8_t sleep(int interrupt, int mode, unsigned long ms=0);
Can be used for timer and pin interrupt at he same time on the NRF5 platform just like the arduino?
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I'll try it, but I have strong doubts that it's going to work.
FWIW, here's the pin mapping currently being supplied by digitalPinToInterrupt(..) for the nRF5:
Digital pin 0 = interrupt pin 0
Digital pin 1 = interrupt pin 1
Digital pin 2 = interrupt pin 2
Digital pin 3 = interrupt pin 3
Digital pin 4 = interrupt pin 4
Digital pin 5 = interrupt pin 5
Digital pin 6 = interrupt pin 6
Digital pin 7 = interrupt pin 7
Digital pin 8 = interrupt pin 8
Digital pin 9 = interrupt pin 9
Digital pin 10 = interrupt pin 10
Digital pin 11 = interrupt pin 11
Digital pin 12 = interrupt pin 12
Digital pin 13 = interrupt pin 13
Digital pin 14 = interrupt pin 14
Digital pin 15 = interrupt pin 15
Digital pin 16 = interrupt pin 16
Digital pin 17 = interrupt pin 17
Digital pin 18 = interrupt pin 18
Digital pin 19 = interrupt pin 19
Digital pin 20 = interrupt pin 20
Digital pin 21 = interrupt pin 21
Digital pin 22 = interrupt pin 22
Digital pin 23 = interrupt pin 23
Digital pin 24 = interrupt pin 24
Digital pin 25 = interrupt pin 25
Digital pin 26 = interrupt pin 26
Digital pin 27 = interrupt pin 27
Digital pin 28 = interrupt pin 28
Digital pin 29 = interrupt pin 29
Digital pin 30 = interrupt pin 30
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The last I heard, from @d00616 , we had to supply code such as:
// Enable interrupt NVIC_SetPriority(RTC0_IRQn, 15); NVIC_ClearPendingIRQ(RTC0_IRQn); NVIC_EnableIRQ(RTC0_IRQn);and
// This must be in one line extern "C" { void RTC0_IRQHandler(void) {rtcInterruptCounter++; NRF5_RESET_EVENT(NRF_RTC0->EVENTS_OVRFLW); NRF_RTC0->EVENTS_OVRFLW=0; }}to get interrupts to work. Even with that approach, though, I haven't gotten it to support any interrupts in addition to a timed sleeping, though I have gotten it to support one interrupt that's separate from a timed sleeping (basically, sleeps indefinitely until the interrupt happens).
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OK, I just now tried:
sleep(3,CHANGE,3000);and, as I suspected, it does nothing but sleep for 3 seconds. It's not responsive to any changes on pin P03 on an nRF52.
@scalz Are you getting a different result? It seems like there's a strong disconnect somewhere between what you're recommending and what I am experiencing.
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@NeverDie said in
MySensors NRF5 Platform:@scalz Are you getting a different result? It seems like there's a strong disconnect somewhere between what you're recommending and what I am experiencing.
I didn't give any recommandation, you misread. I just said the regular way to use sleep feature in mysensors, for users, is with sleep(..). But I agree, I misread you too! when you were asking for the specific nrf52 case I guess
That said, I got this working when I made my recessed node for door (accelerometer and hall effect sensor with sleeping). Maybe things have changed in the lib?? or not. I'm struggling between different version of the lib, and some are different from the dev branch.. I'll recheck this asap (not sure for this evening).
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I tried toying around with it a bit, and I got a useful result:
#define MY_CORE_ONLY #include <nrf.h> #include <MySensors.h> const byte ledPin = LED_BUILTIN; const byte interruptPin = 3; volatile byte state = LOW; void blinkityBlink(uint8_t pulses, uint8_t repetitions) { for (int x=0;x<repetitions;x++) { for (int i=0;i<pulses;i++) { digitalWrite(LED_BUILTIN,HIGH); wait(20); digitalWrite(LED_BUILTIN,LOW); wait(100); } wait(500); } } void setup() { hwPinMode(LED_BUILTIN,OUTPUT_D0H1); hwPinMode(interruptPin, INPUT); attachInterrupt(digitalPinToInterrupt(interruptPin), blink, RISING); blinkityBlink(2,1); //signify power-on and start of main loop } volatile bool buttonPressed=false; void loop() { state = !state; digitalWrite(ledPin, state); sleep(digitalPinToInterrupt(interruptPin), RISING, 3000); wait(20); //wait 20 milliseconds for button to debounce if it was pressed if (digitalRead(interruptPin)) { //if button is pressed blinkityBlink(2,1); } if (buttonPressed) { buttonPressed=false; blinkityBlink(20,1); } } void blink() { buttonPressed=true; }So, with this approach, pushing the button on pin 3 does wake up the nRF52 from sleep, whereupon the button press can still be detected and serviced, but it also demonstrates that the ISR per se isn't working.
Anyhow, with this I'm able to get the PIR or leak sensor or magnet sensor or light sensor doing useful things in a timely manner, even if it isn't ideal. That puts me further ahead than I was before.
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@NeverDie
This is a test program that wakes up from either that i was using some time ago./** The MySensors Arduino library handles the wireless radio link and protocol between your home built sensors/actuators and HA controller of choice. The sensors forms a self healing radio network with optional repeaters. Each repeater and gateway builds a routing tables in EEPROM which keeps track of the network topology allowing messages to be routed to nodes. Created by Henrik Ekblad <henrik.ekblad@mysensors.org> Copyright (C) 2013-2015 Sensnology AB Full contributor list: https://github.com/mysensors/Arduino/graphs/contributors Documentation: http://www.mysensors.org Support Forum: http://forum.mysensors.org This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License version 2 as published by the Free Software Foundation. ******************************* REVISION HISTORY Version 1.0 - Henrik EKblad DESCRIPTION This sketch provides an example how to implement a distance sensor using HC-SR04 Use this sensor to measure KWH and Watt of your house meeter You need to set the correct pulsefactor of your meeter (blinks per KWH). The sensor starts by fetching current KWH value from gateway. Reports both KWH and Watt back to gateway. Unfortunately millis() won't increment when the Arduino is in sleepmode. So we cannot make this sensor sleep if we also want to calculate/report watt-number. http://www.mysensors.org/build/pulse_power */ // Enable debug prints #define MY_DEBUG // Enable and select radio type attached //#define MY_RADIO_NRF24 #define MY_RADIO_NRF5_ESB //#define MY_RADIO_RFM69 //#define MY_RADIO_RFM95 #include <MySensors.h> #include <Wire.h> // must be included here so that Arduino library object file references work #include <RtcDS3231.h> RtcDS3231<TwoWire> Rtc(Wire); #define DIGITAL_INPUT_SENSOR 2 // The digital input you attached your light sensor. (Only 2 and 3 generates interrupt!) #define PULSE_FACTOR 1000 // Nummber of blinks per KWH of your meeter //#define SLEEP_MODE false // Watt-value can only be reported when sleep mode is false. #define MAX_WATT 10000 // Max watt value to report. This filetrs outliers. #define CHILD_ID 1 // Id of the sensor child unsigned long SEND_FREQUENCY = 20000; // Minimum time between send (in milliseconds). We don't wnat to spam the gateway. double ppwh = ((double)PULSE_FACTOR) / 1000; // Pulses per watt hour //bool pcReceived = false; volatile unsigned long pulseCount = 0; volatile unsigned long lastBlink = 0; volatile unsigned long watt = 0; volatile unsigned long kwh = 0; unsigned long oldWatt = 0; double oldKwh; unsigned long lastSend; MyMessage wattMsg(CHILD_ID, V_WATT); MyMessage kwhMsg(CHILD_ID, V_KWH); void setup() { Serial.begin(115200); Rtc.Begin(); Rtc.Enable32kHzPin(false); Rtc.SetSquareWavePinClockFrequency(DS3231SquareWaveClock_1Hz); Rtc.SetSquareWavePin(DS3231SquareWavePin_ModeClock); // Use the internal pullup to be able to hook up this sketch directly to an energy meter with S0 output // If no pullup is used, the reported usage will be too high because of the floating pin hwPinMode(DIGITAL_INPUT_SENSOR, INPUT_PULLUP); attachInterrupt(digitalPinToInterrupt(DIGITAL_INPUT_SENSOR), onPulse, FALLING); //pcReceived = true; lastSend = millis(); } void presentation() { // Send the sketch version information to the gateway and Controller sendSketchInfo("Energy Meter", "1.0"); // Register this device as power sensor present(CHILD_ID, S_POWER); } void loop() { unsigned long now = millis(); // Only send values at a maximum frequency or woken up from sleep bool sendTime = now - lastSend > SEND_FREQUENCY; if (sendTime) { // New watt value has been calculated if (watt != oldWatt) { // Check that we dont get unresonable large watt value. // could hapen when long wraps or false interrupt triggered if (watt < ((unsigned long)MAX_WATT)) { send(wattMsg.set(watt)); // Send watt value to gw } Serial.print("Watt:"); Serial.println(watt); oldWatt = watt; } // Pulse count has changed //kwh = pulseCount; //double kwh = ((double)pulseCount / ((double)PULSE_FACTOR)); send(kwhMsg.set(pulseCount)); // Send kwh value to gw Serial.print("Wh = "); Serial.println(pulseCount); pulseCount = 0; lastSend = now; } sleep(SEND_FREQUENCY); } void receive(const MyMessage &message) { } void onPulse() { unsigned long newBlink = micros(); unsigned long interval = newBlink - lastBlink; if (interval < 50000L) { // Sometimes we get interrupt on RISING return; } watt = (3600000000.0 / interval) / ppwh; lastBlink = newBlink; pulseCount++; }
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Well, that's interesting. In the sketch I posted, I invoked sleep with:
sleep(digitalPinToInterrupt(interruptPin), RISING, 3000);which caused the mcu to wake up immediately after I press the button, but it didn't process the ISR.
Using an invocation like yours in the sketch you just posted above:
sleep(3000);the ISR executes and then terminates when I press the button, but the MCU doesn't wake and continue with the loop as it did with the prior incantation. Instead, it has to wait for the timer cycle to finish.
What I want is for it to wake up, do the ISR, and continue with the loop where it left off until it is explicitly put back to sleep again. How do I do that?
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@NeverDie I have checked the sleep routine in all three variants. It's working with my setup.
There is no API stopping the sleep() by another ISR. Sleep only ends at one of the given conditions.
When you use the MY_CORE_ONLY define, please add "hwInit();" into the setup() routine.
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@d00616 said in
MySensors NRF5 Platform:@NeverDie I have checked the sleep routine in all three variants. It's working with my setup.
There is no API stopping the sleep() by another ISR. Sleep only ends at one of the given conditions.
When you use the MY_CORE_ONLY define, please add "hwInit();" into the setup() routine.
Would you please post the three demo code examples that you tested?
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@d00616 said in
MySensors NRF5 Platform:add "hwInit();" into the setup() routine.
OK, I just now did that, but I'm not getting any difference in the results.
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In any case, I'm sure the question will ultimately turn from "How do I wake up based on a pin change?" to "How do I wake up based on the LPCOMP output, which has that pin as its input?" The reason: as covered earlier in this thread, much lower current consumption while sleeping if doing it via LPCOMP rather than the more straightforward pin monitoring.
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@NeverDie said in
MySensors NRF5 Platform:In any case, I'm sure the question will ultimately turn from "How do I wake up based on a pin change?" to "How do I wake up based on the LPCOMP output, which has that pin as its input?" The reason: as covered earlier in this thread, much lower current consumption while sleeping if doing it via LPCOMP rather than the more straightforward pin monitoring.
It's a good question about, how to design the API to do this. I have no good idea.
Until an API, you can set MY_HW_RTC->CC[0] to (MY_HW_RTC->COUNTER+2). This ends sleep with some latency.
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Is it just me, or does the myBoardNrf5 cause I2c to fail during initialization? I have code which worked fine on mNrf5Board but which now hangs during initialization when using myBoardNrf5.
Is it working for anyone else?
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@NeverDie said in
MySensors NRF5 Platform:Is it just me, or does the myBoardNrf5 cause I2c to fail during initialization? I have code which worked fine on mNrf5Board but which now hangs during initialization when using myBoardNrf5.
Is it working for anyone else?I've re-installed everything and am still getting no joy using I2C currently. The non-I2C stuff seems to be working fine though.
So, before I spin more cycles trying to figure it out, is i2c working for anyone else right now using the latest builds and myBoardNrf5? Or, is I2C currently broken?
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It appears that the place where it hangs is this line here in Wire_nRF52.cpp:
while(!_p_twim->EVENTS_LASTTX && !_p_twim->EVENTS_ERROR);This is too bad, as I2C seemed to work fine prior to around a couple weeks ago. I think maybe (?) the latest update somehow broke it.
Please advise.
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Well, since I'm dead in the water as things stand, I moved the code over to run on an nRF52 DK. Then, usingy Sandeep's code and none of the mysensors code, I was able to get the nRF52 DK to read an attached Si7021 temperature-humidity sensor. i.e. that worked without hanging.
So, it would appear that there's something about the mysensors code that is causing the problems. @d00616 Can we please get it fixed?
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@NeverDie said in
MySensors NRF5 Platform:So, it would appear that there's something about the mysensors code that is causing the problems. @d00616 Can we please get it fixed?
I have no I2C Hardware for testing, but I take a look into the I2C and MySensors code soon.
