import json import os import threading import time import serial import paho.mqtt.client as mqtt from api import add from db.models.lot_data_model import LOT_DATA from device import device_name def t(): temp_send = '06 03 01 F4 00 02 85 B2 ' # 温湿度查询指令 co2_send = '06 03 01 F7 00 02 75 B2 ' # 二氧化碳查询指令 pressure_send = '06 03 01 F9 00 02 14 71 ' # 气压查询指令 sun_send = '06 03 01 FA 00 02 E4 71 ' # 光照查询指令 soil_send = '02 03 00 00 00 04 44 3A' # 土壤查询指令 danlinjia_send = '02 03 00 04 00 03 44 39' # 氮磷钾查询指令 rainfall_send = '03 03 00 00 00 01 85 E8' # 雨量查询指令 windspeed_send = '04 03 00 00 00 02 C4 5E' # 风速查询指令 winddirection_send = '05 03 00 00 00 02 C5 8F' # 风向查询指令 # 发送的数据转为2进制b'\x01\x03\x00\x00\x00\x02\xc4\x0b' temp_send = bytes.fromhex(temp_send) co2_send = bytes.fromhex(co2_send) pressure_send = bytes.fromhex(pressure_send) sun_send = bytes.fromhex(sun_send) soil_send = bytes.fromhex(soil_send) danlinjia_send = bytes.fromhex(danlinjia_send) rainfall_send = bytes.fromhex(rainfall_send) windspeed_send = bytes.fromhex(windspeed_send) winddirection_send = bytes.fromhex(winddirection_send) while True: try: ser = serial.Serial("/dev/ttyS2", 9600) # if ser.is_open: ser.write(temp_send) time.sleep(1) # 获取返回的缓冲data,获取的是buffer_data的长度 9 tempbuffer_data = ser.in_waiting if tempbuffer_data: # 返回的数据为2进制:b'\x01\x03\x04\x01\x08\x022\xfa\xb8' return_data = ser.read(tempbuffer_data) # 二进制转换为16进制:010304010802307b79 return_data_hex = str(return_data.hex()) # 对返回的数据进行解析,获取温度和湿度数据 airtemp_data = int(return_data_hex[6:10], 16) / 10 airhumi_data = int(return_data_hex[10:14], 16) / 10 time.sleep(5) ser.write(co2_send) time.sleep(1) # 获取返回的缓冲data,获取的是buffer_data的长度 9 co2buffer_data = ser.in_waiting if co2buffer_data: return_data = ser.read(co2buffer_data) # 二进制转换为16进制:010304010802307b79 return_data_hex = str(return_data.hex()) # 对返回的数据进行解析,获取温度和湿度数据 co2_data = int(return_data_hex[6:10], 16) time.sleep(5) ser.write(pressure_send) time.sleep(1) # 获取返回的缓冲data,获取的是buffer_data的长度 9 pressurebuffer_data = ser.in_waiting if pressurebuffer_data: # 返回的数据为2进制:b'\x01\x03\x04\x01\x08\x022\xfa\xb8' return_data = ser.read(pressurebuffer_data) # 二进制转换为16进制:010304010802307b79 return_data_hex = str(return_data.hex()) # 对返回的数据进行解析,获取温度和湿度数据 pressure_data = int(return_data_hex[6:10], 16) / 10 time.sleep(5) ser.write(sun_send) time.sleep(1) # 获取返回的缓冲data,获取的是buffer_data的长度 9 sunbuffer_data = ser.in_waiting if sunbuffer_data: # 返回的数据为2进制:b'\x01\x03\x04\x01\x08\x022\xfa\xb8' return_data = ser.read(sunbuffer_data) # 二进制转换为16进制:010304010802307b79 return_data_hex = str(return_data.hex()) sun_data = int(return_data_hex[6:14], 16) time.sleep(5) # print('send soil directives') ser.write(soil_send) time.sleep(1) # 获取返回的缓冲data,获取的是buffer_data的长度 9 soilbuffer_data = ser.in_waiting # print(buffer_data, 'buffer_data') if soilbuffer_data: # 返回的数据为2进制:b'\x01\x03\x04\x01\x08\x022\xfa\xb8' return_data = ser.read(soilbuffer_data) # 二进制转换为16进制:010304010802307b79 return_data_hex = str(return_data.hex()) # 对返回的数据进行解析,获取温度和湿度数据 humidity_data = int(return_data_hex[6:10], 16) / 10 temperature_data = int(return_data_hex[10:14], 16) / 10 electrical_data = int(return_data_hex[14:18], 16) / 10 PH_data = int(return_data_hex[18:22], 16) / 10 time.sleep(5) # print('send danlinjia directives') ser.write(danlinjia_send) time.sleep(1) # 获取返回的缓冲data,获取的是buffer_data的长度 9 danlinjiabuffer_data = ser.in_waiting # print(buffer_data, 'buffer_data') if danlinjiabuffer_data: # 返回的数据为2进制:b'\x01\x03\x04\x01\x08\x022\xfa\xb8' return_data = ser.read(danlinjiabuffer_data) # print('返回的数据2进制:', return_data) # 二进制转换为16进制:010304010802307b79 return_data_hex = str(return_data.hex()) # # 对返回的数据进行解析,获取温度和湿度数据 dan_data = int(return_data_hex[6:10], 16) / 10 lin_data = int(return_data_hex[10:14], 16) / 10 jia_data = int(return_data_hex[14:18], 16) / 10 time.sleep(5) # print('send rainfall directives') ser.write(rainfall_send) time.sleep(1) # 获取返回的缓冲data,获取的是buffer_data的长度 9 rainfallbuffer_data = ser.in_waiting # print(buffer_data, 'buffer_data') if rainfallbuffer_data: # 返回的数据为2进制:b'\x01\x03\x04\x01\x08\x022\xfa\xb8' return_data = ser.read(rainfallbuffer_data) # print('返回的数据2进制:', return_data) # 二进制转换为16进制:010304010802307b79 return_data_hex = str(return_data.hex()) # print('返回的数据转换为16进制:', return_data_hex) # # 对返回的数据进行解析,获取温度和湿度数据 # print("当前雨量值为:", int(return_data_hex[6:10], 16)/10)#单位mm rainfall_data = int(return_data_hex[6:10], 16) / 10 time.sleep(5) ser.write(windspeed_send) time.sleep(1) # 获取返回的缓冲data,获取的是buffer_data的长度 9 windspeedbuffer_data = ser.in_waiting # print(buffer_data, 'buffer_data') if windspeedbuffer_data: # 返回的数据为2进制:b'\x01\x03\x04\x01\x08\x022\xfa\xb8' return_data = ser.read(windspeedbuffer_data) # print('返回的数据2进制:', return_data) # 二进制转换为16进制:010304010802307b79 return_data_hex = str(return_data.hex()) # print('返回的数据转换为16进制:', return_data_hex) # print("当前风速为:", int(return_data_hex[6:10], 16)/10)#单位mm speedwind_data = int(return_data_hex[6:10], 16) / 10 time.sleep(5) # print('send winddirection directives') ser.write(winddirection_send) time.sleep(1) # 获取返回的缓冲data,获取的是buffer_data的长度 9 winddirectionbuffer_data = ser.in_waiting # print(buffer_data, 'buffer_data') if winddirectionbuffer_data: # 返回的数据为2进制:b'\x01\x03\x04\x01\x08\x022\xfa\xb8' return_data = ser.read(winddirectionbuffer_data) # print('返回的数据2进制:', return_data) # 二进制转换为16进制:010304010802307b79 return_data_hex = str(return_data.hex()) # print('返回的数据转换为16进制:', return_data_hex) # print("当前风向为:", int(return_data_hex[10:14], 16))#单位mm winddirection_data = int(return_data_hex[10:14], 16) time.sleep(5) # print('{"name":"%d","name1":"%d"}', 123,456) # data = [{'ngvhgv': airtemp_data}, {'nvjgvjvj':airhumi_data}] data = {'ambient_temperature': airtemp_data, 'ambient_humidity': airhumi_data, 'carbon_dioxide': co2_data, 'ambient_air_pressure': pressure_data, 'ambient_lighting': sun_data, 'soil_moisture': humidity_data, 'soil_temperature': temperature_data, 'soil_conductivity': electrical_data, 'soil_PH': PH_data, 'soil_potassium_phosphate_nitrogen': dan_data, 'soil_potassium_phosphate_phosphorus': lin_data, 'soil_potassium_phosphate_potassium': jia_data, 'rainfall': rainfall_data, 'wind_speed': speedwind_data, 'wind_direction': winddirection_data, 'create_time': int(time.time()), 'device_name': os.getenv('device_name') } t2 = LOT_DATA(**data) client.publish('demo', payload=json.dumps(data, ensure_ascii=False), qos=0) add(t2) except Exception as e: print(e) pass def test(): while True: data = {'ambient_temperature': 1, 'ambient_humidity': 1, 'carbon_dioxide': 1, 'ambient_air_pressure': 1, 'ambient_lighting': 1, 'soil_moisture': 1, 'soil_temperature': 1, 'soil_conductivity': 1, 'soil_PH': 1, 'soil_potassium_phosphate_nitrogen': 1, 'soil_potassium_phosphate_phosphorus': 1, 'soil_potassium_phosphate_potassium': 1, 'rainfall': 1, 'wind_speed': 1, 'wind_direction': 1, 'create_time': int(time.time()), 'device_name': os.getenv('device_name') } t2 = LOT_DATA(**data) client.publish('demo', payload=json.dumps(data, ensure_ascii=False), qos=0) add(t2) time.sleep(1) def on_connect(client, userdata, flags, rc): threading.Thread(target=test).start() if __name__ == '__main__': client = mqtt.Client(client_id=device_name) client.username_pw_set("demo", "123456") # Specify callback function client.on_connect = on_connect # Establish a connection # ceshi-mqtt.lihaink.cn client.connect('ceshi-mqtt.lihaink.cn', 1883) # Publish a message client.loop_forever()