def main(): client = TBDeviceMqttClient(THINGSBOARD_HOST, DEVICE_ACCESS_TOKEN) client.connect() rc = client.claim(secret_key=SECRET_KEY, duration=DURATION).get() if rc == 0: print("Claiming request was sent.") client.stop()
def prosesIOT(): print('IoT\n') clientthingsboard = TBDeviceMqttClient("202.46.7.33", "TEWSSiporaPower") clientthingsboard.connect() while True: if (powerDataQueue.empty() == False): #get data queue lock.acquire() powerdata = powerDataQueue.get() lock.release() #send to RDS #clientRDS = client() #payload = str(xdata) + ',' + str(ydata) + ',' + str(zdata) #clientRDS.setBrokerParameter("202.46.3.41",1883, userName="******", password="******") #clientRDS.publishData(payload, "node/sensor/siberut/accelerometer", sensorType=1, qosValue=1) #send to thingsboard telemetry_with_ts = { "ts": int(round(time.time() * 1000)), "values": { "volt1": float(powerdata), "volt2": float(powerdata) } } clientthingsboard.send_telemetry(telemetry_with_ts) clientthingsboard.disconnect()
def prosesACC(): print('ACC\n') serialACC = serial.Serial('COM19', 9600) clientthingsboard = TBDeviceMqttClient("202.46.7.33", "TEWSSiporaAccelero") clientthingsboard.max_inflight_messages_set(50) clientthingsboard.connect() while True: dataInput = serialACC.readline()[:-2] data = dataInput.decode() print(data) if data: dataacc = parsingACC(data) telemetry_with_ts = { "ts": int(round(time.time() * 1000)), "values": { "x": float(dataacc[0]), "y": float(dataacc[1]), "z": float(dataacc[2]) } } clientthingsboard.send_telemetry(telemetry_with_ts) lock.acquire() xDataQueue.put(dataacc[0]) yDataQueue.put(dataacc[1]) zDataQueue.put(dataacc[2]) timestampDataQueue.put(int(round(time.time() * 1000))) lock.release() writelogdataaccelerometer(dataacc)
def tb_client_start(telemetries, token): logging.basicConfig( filename=token + '_app.log', filemode='w', format='%(asctime)s : %(levelname)s : %(name)s : %(message)s', level=logging.INFO) client = TBDeviceMqttClient(mqtt_host, token) client.max_inflight_messages_set(50) client.connect() # logging.info("connect device: ", token) for telemetry in telemetries: logging.info("send telemetry: {0} for device with token: {1}".format( telemetries.index(telemetry), token)) client.send_telemetry(telemetry) time.sleep(delay) # Sending telemetry and checking the delivery status (QoS = 1 by default) result = client.send_telemetry(telemetry) logging.debug( "results of client.send_telemetry(telemetry): {}".format(result)) # get is a blocking call that awaits delivery status # success = result.get() == TBPublishInfo.TB_ERR_SUCCESS # if (success): # # print("Success") # logging.info("message sent successfully:{0} ".format(success)) # else: # logging.error("MQTT Failure: {0}".format(result)) # Disconnect from ThingsBoard client.disconnect() # logging.info("all thread: ", threading.enumerate()) global all_done all_done = True
def main(): client = TBDeviceMqttClient("127.0.0.1", "A2_TEST_TOKEN") client.connect() sub_id_1 = client.subscribe_to_attribute("uploadFrequency", callback) sub_id_2 = client.subscribe_to_all_attributes(callback) client.unsubscribe_from_attribute(sub_id_1) client.unsubscribe_from_attribute(sub_id_2)
def main(): client = TBDeviceMqttClient("127.0.0.1", "A2_TEST_TOKEN") client.connect() # call "getTime" on server and receive result, then process it with callback client.send_rpc_call("getTime", {}, callback) while not client.stopped: time.sleep(1)
def hello(event, context): telemetry = [] for result in event['Records']: base64_message = result['kinesis']['data'] base64_bytes = base64_message.encode('ascii') message_bytes = base64.b64decode(base64_bytes) message = message_bytes.decode('ascii') message = json.loads(message) if message['heat_index'] != 0: celsius = (message['heat_index'] - 32) / 1.8 if celsius <= 27.0: message['warning'] = "Normal" elif celsius >= 27.0 and celsius <= 32.0: message['warning'] = "Caution" elif celsius >= 32.1 and celsius <= 41.0: message['warning'] = "Extreme caution" elif celsius >= 41.1 and celsius <= 54.0: message['warning'] = "Danger" else: message['warning'] = "Extreme danger" message['heat_index'] = celsius else: message['warning'] = "Normal" telemetry.append(message) print(telemetry) try: #telemetry = [{"uf": "fd","index": 20.5}, {"uf": "df","index": 110.5}] client = TBDeviceMqttClient("demo.thingsboard.io", "ONISUjegn6ndL5GBIHNf") client.connect() for station in telemetry: print(station) result = client.send_telemetry(station) #print(result) success = result.get() == TBPublishInfo.TB_ERR_SUCCESS #print(success) client.disconnect() except: print("Unable to send telemetry") # serverless invoke local --function hello
def main(): client = TBDeviceMqttClient("127.0.0.1", "A2_TEST_TOKEN") # we set maximum amount of messages sent to send them at the same time. it may stress memory but increases performance client.max_inflight_messages_set(100) client.connect() results = [] result = True for i in range(0, 100): results.append(client.send_telemetry(telemetry_with_ts)) for tmp_result in results: result &= tmp_result.get() == TBPublishInfo.TB_ERR_SUCCESS print("Result " + str(result)) client.stop()
def main(): client = TBDeviceMqttClient("127.0.0.1", "A2_TEST_TOKEN") client.connect() # Sending data in async way client.send_attributes(attributes) client.send_telemetry(telemetry) client.send_telemetry(telemetry_as_array, quality_of_service=1) client.send_telemetry(telemetry_with_ts) client.send_telemetry(telemetry_with_ts_as_array) # Waiting for data to be delivered result = client.send_attributes(attributes) result.get() print("Attribute update sent: " + str(result.rc() == TBPublishInfo.TB_ERR_SUCCESS)) result = client.send_attributes(attributes) result.get() print("Telemetry update sent: " + str(result.rc() == TBPublishInfo.TB_ERR_SUCCESS)) client.stop()
def main(): """ We can provide the following parameters to provisioning function: host - required - Host of ThingsBoard provision_device_key - required - device provision key from device profile provision_device_secret - required - device provision secret from device profile port=1883 - not required - MQTT port of ThingsBoard instance device_name=None - may be generated on ThingsBoard - You may pass here name for device, if this parameter is not assigned, the name will be generated ### Credentials type = ACCESS_TOKEN access_token=None - may be generated on ThingsBoard - You may pass here some access token and it will be saved as accessToken for device on ThingsBoard. ### Credentials type = MQTT_BASIC client_id=None - not required (if username is not None) - You may pass here client Id for your device and use it later for connecting username=None - not required (if client id is not None) - You may pass here username for your client and use it later for connecting password=None - not required - You may pass here password and use it later for connecting ### Credentials type = X509_CERTIFICATE hash=None - required (If you wanna use this credentials type) - You should pass here public key of the device, generated from mqttserver.jks """ # Call device provisioning, to do this we don't need an instance of the TBDeviceMqttClient to provision device credentials = TBDeviceMqttClient.provision("127.0.0.1", "PROVISION_DEVICE_KEY", "PROVISION_DEVICE_SECRET") if credentials is not None: client = TBDeviceMqttClient("127.0.0.1", credentials) client.connect() # Sending data in async way client.stop()
def prosesBPR(): print('BPR\n') global pressurebuffer global serialBPR clientthingsboard = TBDeviceMqttClient("202.46.7.33", "TEWSSiporaBPR") clientthingsboard.max_inflight_messages_set(10) clientthingsboard.connect() while True: dataInput = serialBPR.readline()[:-2] data=dataInput.decode() print(data) if data: databpr = parsingBPR(data) #send to thingsboard telemetry_with_ts = {"ts": int(round(time.time() * 1000)), "values": {"pressure": float(pressuredata), "temperature": float(temperaturedata)}} clientthingsboard.send_telemetry(telemetry_with_ts) lock.acquire() pressureDataQueue.put(databpr[1]) temperatureDataQueue.put(databpr[2]) timestampDataQueue.put(int(round(time.time() * 1000))) lock.release() pressurebuffer = databpr[1] writelogdataBPR(databpr)
#Access token of Controller ACCESS_TOKEN = 'M5enL3ND6Jl9KX1mRwje' INTERVAL = 2 #Access token of edge device 1 ACCESS_TOKEN_EDGE_1 = 'CnpDrS1iinb5fZ4dQD90' #Sample sensor_data = {'temperature': 1414114, 'humidity': 0} #Controller device client = TBDeviceMqttClient(THINGSBOARD_HOST, ACCESS_TOKEN) client_to_edge = TBDeviceMqttClient(THINGSBOARD_HOST, ACCESS_TOKEN_EDGE_1) client.connect() client_to_edge.connect() # Sending to attribute and checking the delivery status (QoS = 1 by default) result = client.send_attributes({ "Edge1_Len": 10, "Edge1_Straight": 7, "Edge1_Right": 3 }) # send to edge attribute result2 = client_to_edge.send_attributes({ "Edge1_Len": 10, "Edge1_Straight": 7, "Edge1_Right": 3 })
class SendAiDetections: """ Sends JSON representation of Ai Object Detections """ def __init__(self, tot_cams): self.json_dict = \ { "dnn_inference_device": { "sbc_id": "ZARGAU00020000010001", "sbc_name": "Intel UP Squared", "sbc_ie_details": { "vpu_device id": "0", "vpu_device name": "MYRIAD 2", "model_id": "0", "model_name": "MobilenetSSD", "model_detection_details":[] #[ #{ # "capture_id": "0", # "zone_id": "0", # "classification": "null", # "probability": "00.00", # "bb_coordinates": ["0","0","0","0"] #}, #{ # "capture_id": "0", # "zone_id": "0", # "classification": "person", # "probability": "65.21", # "bb_coordinates": ["100","50","170","101"] #} #] } } } self.total_cams = tot_cams # Telemetry buffer self.telemetry_buf_max = 100 self.telemetry_buf = [] # Create a dictionary list of the total number of dnn_detector streams self.json_dict_list = [] for i in range(self.total_cams): self.json_dict_list.append(self.json_dict) self.send_buffer = [] self.reset_buffer() self.stopped = False self.name = "JSON message sender" self.tb_telemetry = False if settings.TB_CONNECT: try: self.tb_client = TBDeviceMqttClient(settings.TB_URL, settings.TB_TOKEN) self.tb_client.connect() self.tb_telemetry = True log = "TB connected!" logging.info(log) print("[", colored("INFO", 'green', attrs=['bold']), " ] " + log) except Exception as e: print("[", colored("ERROR", 'red', attrs=['bold']), " ] TB connection failed: ", str(e)) def start(self): t = Thread(target=self.update, name=self.name, args=()) t.daemon = True t.start() log = "message sender started" logging.info(log) print("[", colored("INFO", 'green', attrs=['bold']), " ] " + log) return self def stop(self): self.stopped = True def update(self): prctl.set_name("E:T Message JSON Sender") while True: # Send update over socket every second time.sleep(1) if self.stopped: log = "message sender has stopped" logging.info(log) print("[", colored("INFO", 'green', attrs=['bold']), " ] " + log) #self.sock0.shutdown(socket.SHUT_RDWR) #self.sock0.detach() if settings.TB_CONNECT: try: self.tb_client.disconnect() log = "disconnecting mqtt clients" logging.info(log) print("[", colored("INFO", 'green', attrs=['bold']), " ] " + log) except Exception as e: print("[", colored("ERROR", 'red', attrs=['bold']), " ] TB disconnect failed: ", str(e)) return if settings.JP_SOCK: self.send_json() if self.tb_telemetry: self.send_telemetry() def create_socket(self): # Create sockets self.sock0 = socket.socket(socket.AF_INET, socket.SOCK_STREAM) # Create a socket object # Connect the socket to the port where the server is listening server_address_0 = ('127.0.0.1', 55001) #connection = ('%s port %s ' % server_address_0) #print("[", colored("INFO", 'green', attrs=['bold']), " ] connecting to ", connection) try: self.sock0.connect(server_address_0) connected = True except socket.error as msg: #log = "socket failed: ", str(msg)" #logging.error(log) print("[", colored("ERROR", 'red', attrs=['bold']), " ] socket failed: ", str(msg)) connected = False return connected def send_json(self): if self.create_socket(): time.sleep(0.1) for i in range(len(self.json_dict_list)): # Dumps = dict->str, Loads= str->dict #packet = ast.literal_eval(send_buffer[x]) #send_packet = json.dumps(packet) send_packet = json.dumps(self.json_dict_list[i]) try: self.sock0.send(send_packet.encode()) time.sleep(0.12) except socket.error as msg: #log = "socket failed: ", str(msg) #logging.error(log) print("[", colored("ERROR", 'red', attrs=['bold']), " ] socket failed: ", str(msg)) self.sock0.close() def send_telemetry(self): if self.telemetry_buf: while self.telemetry_buf: send_packet = self.telemetry_buf[0] try: # Sending telemetry result = self.tb_client.send_telemetry(send_packet) # Checking the delivery status (QoS = 1 by default) # get is a blocking call that awaits delivery status # success = result.get() == TBPublishInfo.TB_ERR_SUCCESS # if success: # log = "Telemetry data success" # logging.info(log) # print("[", colored("INFO", 'green', attrs=['bold']), " ] " + log) time.sleep(0.12) except Exception as e: log = "Telemetry send failed: ", str(e) logging.error(log) print("[", colored("ERROR", 'red', attrs=['bold']), " ] ", str(log)) self.telemetry_buf.pop(0) else: # If no data, send a keep-alive timestamp send_packet = dict(ts=int(time.time() * 1000.0)) self.tb_client.send_telemetry(send_packet) def add_to_buffer(self, dictionary, position=0): #self.send_buffer[position] = dictionary self.json_dict_list[position] = dictionary if len(self.telemetry_buf) < self.telemetry_buf_max: self.telemetry_buf.insert(0, dictionary) def reset_buffer(self): for i in range(len(self.json_dict_list)): dictionary = \ { "dnn_inference_device": { "sbc_id": "ZARGAU00020000010001", "sbc_name": "Intel UP Squared", "sbc_ie_details": { "vpu_device id": "0", "vpu_device name": "MYRIAD 2", "model_id": "0", "model_name": "MobilenetSSD", "model_detection_details": [] } } } dict_array = [] dict_array.append(dict(capture_id=str(i), zone_id="0", classification=None, probability="0.00", bb_coordinates=["0", "0", "0", "0"])) dictionary["dnn_inference_device"]["sbc_ie_details"]["model_detection_details"] = dict_array # Convert dictionary to string otherwise capture id will not increment in the array self.json_dict_list[i] = dictionary """ def reset_buffer(self): self.send_buffer = [] for cams in range(self.total_cams): dictionary = self.json_dict dict_array = [] dict_array.append(dict(capture_id=str(cams), zone_id="0", classification=None, probability="0.00", bb_coordinates=["0","0","0","0"])) dictionary["dnn_inference_device"]["sbc_ie_details"]["model_detection_details"] = dict_array # Convert dictionary to string otherwise capture id will not increment in the array self.send_buffer.append(str(dictionary)) """ def close_socket(self): self.sock0.close()
import logging from tb_device_mqtt import TBDeviceMqttClient import socket logging.basicConfig(level=logging.DEBUG) # connecting to localhost client = TBDeviceMqttClient(socket.gethostname()) client.connect(tls=True, ca_certs="mqttserver.pub.pem", cert_file="mqttclient.nopass.pem") client.disconnect()
import logging import time from tb_device_mqtt import TBDeviceMqttClient logging.basicConfig(level=logging.DEBUG) def callback(result): print(result) client = TBDeviceMqttClient("127.0.0.1", "A2_TEST_TOKEN") client.connect() sub_id_1 = client.subscribe_to_attribute("uploadFrequency", callback) sub_id_2 = client.subscribe_to_all_attributes(callback) client.unsubscribe_from_attribute(sub_id_1) client.unsubscribe_from_attribute(sub_id_2) while True: time.sleep(1)
def parse_msg(msg): print("MSG: ", msg) # print(msg.split(";")) telemetry = {} # msg = "1060;003368;2;20;1;22;220;05:46:52 IST 05/21/2019;00:06:8E:03:57:0B;0;0;0000020F000000000000000000000000;26" if (msg.strip().split(";")[0] == "1060" and msg.strip() != ""): if (msg.split(";")[4] == "1" and msg.split(";")[5] == "22"): print("MSG Inside: ", msg) telemetry["eventid"] = msg.split(";")[0] telemetry["msgid"] = msg.split(";")[1] telemetry["eventmessagetype"] = msg.split(";")[2] telemetry["classcode"] = msg.split(";")[3] telemetry["taskcode"] = msg.split(";")[4] telemetry["eventcode"] = msg.split(";")[5] telemetry["priority"] = msg.split(";")[6] telemetry["msgtime"] = msg.split(";")[7] telemetry["macaddr"] = msg.split(";")[8] telemetry["Interface Adddress"] = msg.split(";")[9] telemetry["Reader Adddress"] = msg.split(";")[10] telemetry["Card Number "] = msg.split(";")[11] telemetry["Card byte "] = msg.split(";")[12] # telemetry = {"temperature": 41.9, "enabled": False, "currentFirmwareVersion": "v1.2.2"} client = TBDeviceMqttClient("dev.dataexchange.io", "JUSf1I0L3cGBTskcTDgw") # Connect to ThingsBoard client.connect() # Sending telemetry without checking the delivery status client.send_telemetry(telemetry) # Sending telemetry and checking the delivery status (QoS = 1 by default) result = client.send_telemetry(telemetry) # get is a blocking call that awaits delivery status success = result.get() == TBPublishInfo.TB_ERR_SUCCESS print("MESSAGE SENT: ", success) print(success) # Disconnect from ThingsBoard client.disconnect() elif (msg.strip().split(";")[0] == "1060" and msg.strip() != ""): if (msg.split(";")[4] == "2" and msg.split(";")[5] == "20"): print("MSG Inside: ", msg) telemetry["eventid"] = msg.split(";")[0] telemetry["msgid"] = msg.split(";")[1] telemetry["eventmessagetype"] = msg.split(";")[2] telemetry["classcode"] = msg.split(";")[3] telemetry["taskcode"] = msg.split(";")[4] telemetry["eventcode"] = msg.split(";")[5] telemetry["priority"] = msg.split(";")[6] telemetry["msgtime"] = msg.split(";")[7] telemetry["macaddr"] = msg.split(";")[8] telemetry["Interface Adddress"] = msg.split(";")[9] telemetry["Reader Adddress"] = msg.split(";")[10] telemetry["Card Number "] = msg.split(";")[11] # telemetry = {"temperature": 41.9, "enabled": False, "currentFirmwareVersion": "v1.2.2"} client = TBDeviceMqttClient("dev.dataexchange.io", "JUSf1I0L3cGBTskcTDgw") # Connect to ThingsBoard client.connect() # Sending telemetry without checking the delivery status client.send_telemetry(telemetry) # Sending telemetry and checking the delivery status (QoS = 1 by default) result = client.send_telemetry(telemetry) # get is a blocking call that awaits delivery status success = result.get() == TBPublishInfo.TB_ERR_SUCCESS print("MESSAGE SENT: ", success) print(success) # Disconnect from ThingsBoard client.disconnect()
def main(): # Grove - Servo connected to PWM port servo = GroveServo(12) servo_angle = 90 # Grove - mini PIR motion pir_sensor connected to port D5 pir_sensor = GroveMiniPIRMotionSensor(5) # Grove - Ultrasonic Ranger connected to port D16 ultrasonic_sensor = GroveUltrasonicRanger(16) # Grove - LED Button connected to port D18 button = GroveLedButton(18) # Grove - Moisture Sensor connected to port A0 moisture_sensor = GroveMoistureSensor(0) # Grove - Light Sensor connected to port A2 light_sensor = GroveLightSensor(2) light_state = False # Grove - Temperature&Humidity Sensor connected to port D22 dht_sensor = DHT('11', 22) # Callback for server RPC requests (Used for control servo and led blink) def on_server_side_rpc_request(request_id, request_body): log.info('received rpc: {}, {}'.format(request_id, request_body)) if request_body['method'] == 'getLedState': client.send_rpc_reply(request_id, light_state) elif request_body['method'] == 'setLedState': light_state = request_body['params'] button.led.light(light_state) elif request_body['method'] == 'setServoAngle': servo_angle = float(request_body['params']) servo.setAngle(servo_angle) elif request_body['method'] == 'getServoAngle': client.send_rpc_reply(request_id, servo_angle) # Connecting to ThingsBoard client = TBDeviceMqttClient(thingsboard_server, access_token) client.set_server_side_rpc_request_handler(on_server_side_rpc_request) client.connect() # Callback on detect the motion from motion sensor def on_detect(): log.info('motion detected') telemetry = {"motion": True} client.send_telemetry(telemetry) time.sleep(5) # Deactivating the motion in Dashboard client.send_telemetry({"motion": False}) log.info("Motion alert deactivated") # Callback from button if it was pressed or unpressed def on_event(index, event, tm): if button._GroveLedButton__btn.is_pressed(): log.debug('button: single click') telemetry = {"button_press": True} client.send_telemetry(telemetry) log.info("Pressed") else: log.debug('button: single click') telemetry = {"button_press": False} client.send_telemetry(telemetry) log.info("Unpressed") if event & Button.EV_SINGLE_CLICK: button.led.light(True) elif event & Button.EV_DOUBLE_CLICK: button.led.blink() elif event & Button.EV_LONG_PRESS: button.led.light(False) # Adding the callback to the motion sensor pir_sensor.on_detect = on_detect # Adding the callback to the button button.on_event = on_event try: while True: distance = ultrasonic_sensor.get_distance() log.debug('distance: {} cm'.format(distance)) humidity, temperature = dht_sensor.read() log.debug('temperature: {}C, humidity: {}%'.format( temperature, humidity)) moisture = moisture_sensor.moisture log.debug('moisture: {}'.format(moisture)) log.debug('light: {}'.format(light_sensor.light)) # Formatting the data for sending to ThingsBoard telemetry = { 'distance': distance, 'temperature': temperature, 'humidity': humidity, 'moisture': moisture, 'light': light_sensor.light } # Sending the data client.send_telemetry(telemetry).get() time.sleep(.1) except Exception as e: raise e finally: client.disconnect()
def main(): #declaration des ports temperature temp_meteo_1 = 2 temp_meteo_2 = 3 temp_meteo_3 = 4 temp_meteo_4 = 5 temp_piece = 6 temp_exte = 16 #declaration des ports relais chauffe_meteo = 8 chauffe_piece = 15 ventilateur = 14 grovepi.pinMode(chauffe_meteo, "OUTPUT") grovepi.pinMode(chauffe_piece, "OUTPUT") grovepi.pinMode(ventilateur, "OUTPUT") #declaration led led = 7 count = 4 grovepi.pinMode(led, "OUTPUT") grovepi.analogWrite(led, 255) #déclaration des différents états à gérer #état des chauffages ChauffePieceState = False ChauffeMeteoState = False #etat des ventilateurs VentilateurState = False #etat des modes de chauffages MeteoAutoState = False PieceAutoState = False # Définition de la fonction servant à gérer les RPC (remote prcedure calls) entre l'interface et le rapsberry def on_server_side_rpc_request(request_id, request_body): #on affiche en log le rpc reçu log.info('received rpc: {}, {}'.format(request_id, request_body)) #get et set du chauffage de la piéce if request_body['method'] == 'getChauffePieceState': client.send_rpc_reply(request_id, ChauffePieceState) elif request_body['method'] == 'setChauffePieceState': ChauffePieceState = request_body['params'] grovepi.digitalWrite(chauffe_piece, ChauffePieceState) #get et set du chauffage de la météo elif request_body['method'] == 'setChauffeMeteoState': ChauffeMeteoState = request_body['params'] grovepi.digitalWrite(chauffe_meteo, ChauffeMeteoState) elif request_body['method'] == 'getChauffeMeteoState': client.send_rpc_reply(request_id, ChauffeMeteoState) #get et set de l'activation des ventilateurs elif request_body['method'] == 'setVentilateurState': VentilateurState = request_body['params'] grovepi.digitalWrite(ventilateur, VentilateurState) elif request_body['method'] == 'getVentilateurState': client.send_rpc_reply(request_id, VentilateurState) #get et set des modes de chauffages piéce et météo elif request_body['method'] == 'getMeteoAutoState': client.send_rpc_reply(request_id, MeteoAutoState) elif request_body['method'] == 'setMeteoAutoState': MeteoAutoState = request_body['params'] elif request_body['method'] == 'getPieceAutoState': client.send_rpc_reply(request_id, PieceAutoState) elif request_body['method'] == 'setPieceAutoState': PieceAutoState = request_body['params'] # Connection à Thingsboard client = TBDeviceMqttClient(thingsboard_server, access_token) client.set_server_side_rpc_request_handler(on_server_side_rpc_request) client.connect() #fonction retournant un dictionnaire avec toutes les temperatures def getTemperatures(): Temperatures = {} Temperatures['TemperatureMeteo1'] = grovepi.dht(temp_meteo_1, 1)[0] if isnan(Temperatures['TemperatureMeteo1']): Temperatures['TemperatureMeteo1'] = 0 Temperatures['TemperatureMeteo2'] = grovepi.dht(temp_meteo_2, 1)[0] if isnan(Temperatures['TemperatureMeteo2']): Temperatures['TemperatureMeteo2'] = 0 Temperatures['TemperatureMeteo3'] = grovepi.dht(temp_meteo_3, 1)[0] if isnan(Temperatures['TemperatureMeteo3']): Temperatures['TemperatureMeteo3'] = 0 Temperatures['TemperatureMeteo4'] = grovepi.dht(temp_meteo_4, 1)[0] if isnan(Temperatures['TemperatureMeteo4']): Temperatures['TemperatureMeteo4'] = 0 #moyenne des Températures extérieures TemperatureMoyenneMeteo = mean([ Temperatures.get('TemperatureMeteo1'), Temperatures.get('TemperatureMeteo2'), Temperatures.get('TemperatureMeteo3'), Temperatures.get('TemperatureMeteo4') ]) Temperatures['TemperatureMoyenneMeteo'] = TemperatureMoyenneMeteo if isnan(Temperatures['TemperatureMoyenneMeteo']): Temperatures['TemperatureMoyenneMeteo'] = 0 Temperatures['TemperaturePiece'] = grovepi.dht(temp_piece, 1)[0] if isnan(Temperatures['TemperaturePiece']): Temperatures['TemperaturePiece'] = 0 Temperatures['TemperatureExte'] = grovepi.dht(temp_exte, 1)[0] if isnan(Temperatures['TemperatureExte']): Temperatures['TemperatureExte'] = 0 return Temperatures #fonbction qui permet de déterminer l'état de chauffage nécessaire dans la piéce def HotOrColdPiece(TemperaturePiece): etat = False #ouverture du CSV CsvPiece = open("/home/pi/GrovePi/YES/automatisation/piece.csv", "r+") reader = csv.reader(CsvPiece) i = 0 for row in reader: #si On est à la premiére itération on regarde le mode de chauffage if i == 1: mode = row[0] log.info(mode) if i >= 1: #Si on est en monde conventionnel on récupére les créneux en les transformant #en format datetime.datetime.time(), on regarde si l'heure actuelle appartient à ce créneau #si c'est le cas on regarde la température nécessaire dans ce créneau et on en déduit l'état du #chauffage if mode == 'conv': debut = datetime.datetime.strptime(row[1], '%H:%M:%S').time() fin = datetime.datetime.strptime(row[2], '%H:%M:%S').time() if debut <= datetime.datetime.now().time() <= fin: log.info('bon créneau') if TemperaturePiece > int(row[3]): etat = False else: etat = True break #En mode smart on récupérer seulement l'état rentré du côté Matlab dans la derniére colonne du CSV if mode == "smart": if int(row[4]) == 1: etat = True else: etat = False break i = i + 1 CsvPiece.close() return etat #fonction qui génére l'état de la météo de maniére aléatoire def HotOrColdMeteo(TemperatureMoyenneMeteo): etat = random.choice((True, False)) return etat try: while True: #Obtention de toutes les données nécessaires Telemetry = getTemperatures() #si le chuffage de la piéce est en mode auto on génére l'état de la résistance grace à la fonction prédéfinie if PieceAutoState: print('mode auto') grovepi.digitalWrite( chauffe_piece, HotOrColdPiece(Telemetry['TemperaturePiece'])) #Si le chauffage de la météo est en mode auto on génére l'état des résistances et des ventilateurs en fonction de lma fonction prédéfinie if MeteoAutoState: if HotOrColdMeteo(Telemetry['TemperatureMoyenneMeteo']): grovepi.digitalWrite(chauffe_meteo, True) grovepi.digitalWrite(ventilateur, False) else: grovepi.digitalWrite(chauffe_meteo, False) grovepi.digitalWrite(ventilateur, True) log.info(Telemetry) #On envoie les données de telpératures à Thingsboard client.send_telemetry(Telemetry).get() #On crée la nouvelle ligne qui sera insérée dans le CSV ligne = [0, 0, 0, 0, 0, 0, 0, 0] ligne[0] = str(datetime.datetime.now()) ligne[1] = str(Telemetry['TemperatureMeteo1']) ligne[2] = str(Telemetry['TemperatureMeteo2']) ligne[3] = str(Telemetry['TemperatureMeteo3']) ligne[4] = str(Telemetry['TemperatureMeteo4']) ligne[5] = str(Telemetry['TemperatureMoyenneMeteo']) ligne[6] = str(Telemetry['TemperaturePiece']) ligne[7] = str(Telemetry['TemperatureExte']) f = open( '/home/pi/Desktop/DataTemperatures/' + datetime.datetime.now().strftime('%d:%m:%y') + '-dataTemp.csv', 'a') writer = csv.writer(f) writer.writerow(ligne) log.info('written in csv') f.close() #condition sécuritaire si la température dépasse les 60 on quitte la boucle et va directeent au finally ou les actionneurs sont arretes if Telemetry["TemperatureMoyenneMeteo"] >= 60 or Telemetry[ "TemperaturePiece"] >= 60: break #Ici on décide tous les combien de temps la prise de température doit être faite ainsi que l'actvation ou non des chauffages time.sleep(2) except Exception as e: raise e log.warning(e) finally: log.info("client disconnect") client.disconnect() grovepi.digitalWrite(chauffe_piece, False) grovepi.digitalWrite(chauffe_meteo, False) grovepi.digitalWrite(ventilateur, True)
def main(): client = TBDeviceMqttClient("127.0.0.1", "A2_TEST_TOKEN") client.connect() client.request_attributes(["atr1", "atr2"], callback=on_attributes_change) while not client.stopped: time.sleep(1)
def main(): # Particulate Matter PLANTOWER = plantower.Plantower(port=USB_DEVICE_1) print("Making sure it's correctly setup for active mode. Please wait") #make sure it's in the correct mode if it's been used for passive beforehand #Not needed if freshly plugged in PLANTOWER.mode_change( plantower.PMS_ACTIVE_MODE) #change back into active mode PLANTOWER.set_to_wakeup() #ensure fan is spinning # Renology Wanderer 10A Charge Controller rover = RenogyRover(USB_DEVICE_2, 1) # BME 280 Temp, Humidity, Pressure port = 1 address = 0x77 # Adafruit BME280 address. Other BME280s may be different bus = smbus2.SMBus(port) bme280.load_calibration_params(bus, address) # delay 30 seconds to warmup devices print('30 second warmup....') time.sleep(30) print('30 second warmup done....') telemetry = { "pm_10": 'not set', "pm_2_5": 'not set', "pm_1_0": 'not set', "ambient_humidity": 'not set', "ambient_pressure": 'not set', "ambient_temperature": 'not set', "wind_speed": 'not set', "wind_gust": 'not set', "wind_direction": 'not set', "rainfall": 'not set', "battery_percentage": 'not set', "battery_type": 'not set', "battery_capacity": 'not set', "battery_voltage": 'not set', "battery_temperature": 'not set', "controller_model": 'not set', "controller_charging_status": 'not set', "controller_temperature": 'not set', "load_voltage": 'not set', "load_current": 'not set', "load_power": 'not set', "solar_voltage": 'not set', "solar_current": 'not set', "solar_power": 'not set', "power_generation_today": 'not set', "charging_amp_hours_today": 'not set', "discharging_amp_hours_today": 'not set' } #MQTT ~~~~ config = configparser.ConfigParser() config.read("config.ini") THINGSBOARD_HOST = config.get("thingsboard", "host") ACCESS_TOKEN = config.get("thingsboard", "token") #SSL Cert locations CA_CERTS = '' CERT_FILE = '' KEY_FILE = '' # Set access token client = TBDeviceMqttClient(THINGSBOARD_HOST, ACCESS_TOKEN) # Connect to ThingsBoard client.connect() # Data capture and upload interval in seconds. Less interval will eventually hang the DHT22. INTERVAL = 1 AVG_INTERVAL = 60 next_reading = time.time() # Lists for averages pm_1_0_list = [] pm_2_5_list = [] pm_10_list = [] try: while True: # Every second do this... try: pm = PLANTOWER.read() except Exception as e: print("PMS7003: exception: " + str(e)) # print(pm) pm_1_0_list.append(pm.pm10_std) pm_2_5_list.append(pm.pm25_std) pm_10_list.append(pm.pm100_std) # wind wind.store_speeds.append(wind.calculate_speed(INTERVAL)) wind_d = wind_direction_byo.get_value() if wind_d is not None: wind.store_directions.append(wind_d) wind.reset_wind() # Every 60 seconds do this... if len(pm_1_0_list) == AVG_INTERVAL and len( pm_2_5_list) == AVG_INTERVAL and len( pm_10_list) == AVG_INTERVAL: # average wind wind_average = wind_direction_byo.get_average( wind.store_directions) wind_gust = max(wind.store_speeds) wind_speed = statistics.mean(wind.store_speeds) telemetry["wind_speed"] = str(wind_speed * 0.621371) # convert to mph telemetry["wind_gust"] = str(wind_gust * 0.621371) # convert to mph telemetry["wind_direction"] = str(wind_average) # at end of interval average value and add to telemetry pm_1_0_avg = statistics.mean(pm_1_0_list) pm_2_5_avg = statistics.mean(pm_2_5_list) pm_10_avg = statistics.mean(pm_10_list) telemetry["pm_1_0"] = str(pm_1_0_avg) telemetry["pm_2_5"] = str(pm_2_5_avg) telemetry["pm_10"] = str(pm_10_avg) # rain rain = rainfall.get_value() telemetry["rainfall"] = str(rain) rainfall.reset_rainfall() # BME280 bme280_data = bme280.sample(bus, address) humidity = bme280_data.humidity pressure = bme280_data.pressure temperature = (bme280_data.temperature * 1.8) + 32 # convert to Farenheit # print(pressure, humidity, ambient_temperature) telemetry["ambient_pressure"] = str(pressure) telemetry["ambient_humidity"] = str(humidity) telemetry["ambient_temperature"] = str(temperature) # Controller Battery telemetry telemetry["battery_percentage"] = rover.battery_percentage() telemetry["battery_type"] = rover.battery_type() telemetry["battery_capacity"] = rover.battery_capacity() telemetry["battery_voltage"] = rover.battery_voltage() telemetry["battery_temperature"] = rover.battery_temperature() # Controller telemetry telemetry["controller_model"] = rover.model() telemetry[ "controller_temperature"] = rover.controller_temperature() telemetry[ "controller_charging_status"] = rover.charging_status_label( ) # Load Telemetry telemetry["load_voltage"] = rover.load_voltage() telemetry["load_current"] = rover.load_current() telemetry["load_power"] = rover.load_power() # Solar Telemetry telemetry["solar_voltage"] = rover.solar_voltage() telemetry["solar_current"] = rover.solar_current() telemetry["solar_power"] = rover.solar_power() # Controller Stats Telemetry telemetry[ "power_generation_today"] = rover.power_generation_today() telemetry[ "charging_amp_hours_today"] = rover.charging_amp_hours_today( ) telemetry[ "discharging_amp_hours_today"] = rover.discharging_amp_hours_today( ) # Sending telemetry and checking the delivery status (QoS = 1 by default) result = client.send_telemetry(telemetry) result.get() print("Telemetry update sent: " + str(result.rc() == TBPublishInfo.TB_ERR_SUCCESS)) print("Telemetry: " + str(telemetry)) # reset list pm_1_0_list.clear() pm_2_5_list.clear() pm_10_list.clear() wind.store_speeds.clear() wind.store_directions.clear() next_reading += INTERVAL sleep_time = next_reading - time.time() if sleep_time > 0: time.sleep(sleep_time) except KeyboardInterrupt: pass client.disconnect()