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- import json
- import uhd
- import numpy as np
- import threading
- from dto.response_dto import ResponseDTO
- from model.surveillance_radar import SurveillanceRadar
- from model.jammer_radar import JammerRadar
- # 定义一组通道常量
- CHANNEL_1 = 0
- CHANNEL_2 = 1
- CHANNEL_3 = 2
- CHANNEL_4 = 3
- # 定义干扰策略集合,确保集合中的元素为合法的字符串常量
- JAMMING_POLICY = {
- "噪声调频", "噪声调幅", "噪声直放", "速度多假目标", "距离多假目标"
- }
- ANTI_JAMMING_POLICY = {
- "频率捷变", "波形捷变", "自适应极化滤波"
- }
- class Service:
- usrp = None # 静态类变量
- status = 0 # 静态类变量,用于存储设备状态,初始化为0
- _rlock = threading.RLock() # 可重入锁,用于线程锁
- @staticmethod
- def initialize_usrp():
- with Service._rlock:
- Service.get_sdr_status()
- if Service.status == 1:
- print('USRP设备已经初始化')
- return ResponseDTO.SUCCESS({"status": Service.status}).to_json()
- try:
- Service.usrp = uhd.usrp.MultiUSRP()
- print('------SDR Devices initialize success!------')
- Service.status = 1 # 初始化成功,状态置为1
- return ResponseDTO.SUCCESS({"status": Service.status}).to_json()
- except Exception as e:
- print('SDR设备异常', e)
- Service.status = 0 # 初始化失败,状态置为0
- return ResponseDTO.ERROR_MS_DATA('SDR设备异常', {"status": Service.status, "Error": str(e)}).to_json()
- @staticmethod
- def get_sdr_status():
- with Service._rlock:
- if Service.status == 0:
- return ResponseDTO.ERROR_MS_DATA('SDR设备异常',{"status": Service.status, "Error": "SDR设备未初始化"}).to_json()
- try:
- samples = Service.usrp.recv_num_samps(1, 100e6, 1e6, [0], 50)
- if samples is None:
- Service.status = 0 # 获取状态失败,状态置为0
- else:
- Service.status = 1
- return ResponseDTO.SUCCESS({"status": Service.status}).to_json()
- except Exception as e:
- print('SDR设备异常', e)
- Service.status = 0 # 获取状态失败,状态置为0
- Service.usrp = None # 重置USRP对象
- return ResponseDTO.ERROR_MS_DATA('SDR设备异常', {"status": Service.status, "Error": str(e)}).to_json()
- @staticmethod
- def data(payload):
- jamming_policy = payload['jamming_policy']
- anti_jamming_policy = payload['anti_jamming_policy']
- # 判断策略是否合法
- if jamming_policy not in JAMMING_POLICY or anti_jamming_policy not in ANTI_JAMMING_POLICY:
- return ResponseDTO.ERROR_MS_DATA('策略不合法', {"status": Service.status, "Error": "策略不合法"}).to_json()
- # 打印对应策略
- print(' jamming_policy:', jamming_policy)
- print(' anti_jamming_policy:', anti_jamming_policy)
- Service.send()
- # 生成两个长度为一百的浮点数组,代表侦察信号和返回的信号,数组元素随机
- surveillance_signal = np.random.randn(100)
- surveillance_signal_back = np.random.randn(100)
- # 返回结果
- return ResponseDTO.SUCCESS({"jamming_signal": surveillance_signal.tolist(),
- "anti_jamming_signal": surveillance_signal_back.tolist(),
- "status": Service.status}).to_json()
- @staticmethod
- def send():
- try:
- # 设置中心频率、采样率和增益
- center_freq = 100e6 # 2.4 GHz
- sample_rate = 1e6 # 1 MS/s
- duration = 10 # 以秒为单位
- gain = 20 # [dB] 建议一开始设置小一点,按照实际情况调整
- # 生成发送信号
- num_samples = 100
- tx_signal = np.random.randn(num_samples) + 0.1j * np.random.randn(num_samples) # 修复部分
- # 发送信号
- Service.usrp.send_waveform(tx_signal, duration, center_freq, sample_rate, [0], gain)
- # 接收信号
- rx_signal = Service.usrp.recv_num_samps(num_samples, center_freq, sample_rate)
- print('信号已发送:')
- print(rx_signal)
- print('信号已接收')
- except Exception as e:
- print('发送或接收信号异常', e)
- Service.status = 0 # 发送或接收信号失败,状态置为0
- Service.usrp = None # 重置USRP对象
- @staticmethod
- def demo():
- surveillance_radar = SurveillanceRadar(Service.usrp, rx=CHANNEL_1, tx=CHANNEL_1)
- # main方法
- if __name__ == '__main__':
- Service.initialize_usrp()
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