add: 添加声音检测的可视化以及声波demod的准确度 (#1077)

Co-authored-by: yangkaiyue <yangkaiyue1@tenclass.com>
2025-08-14 22:11:56 +08:00 · 2025-08-14 22:11:56 +08:00 · cf4afde88e
commit cf4afde88e
parent d6b1414967
5 changed files with 769 additions and 0 deletions
--- a/scripts/acoustic_check/demod.py
+++ b/scripts/acoustic_check/demod.py
@ -0,0 +1,280 @@
 """
 实时AFSK解调器 - 基于Goertzel算法
 """
 import numpy as np
 from collections import deque
 class TraceGoertzel:
    """实时Goertzel算法实现"""
    def __init__(self, freq: float, n: int):
        """
        初始化Goertzel算法
        Args:
            freq: 归一化频率 (目标频率/采样频率)
            n: 窗口大小
        """
        self.freq = freq
        self.n = n
        # 预计算系数 - 与参考代码一致
        self.k = int(freq * n)
        self.w = 2.0 * np.pi * freq
        self.cw = np.cos(self.w)
        self.sw = np.sin(self.w)
        self.c = 2.0 * self.cw
        # 初始化状态变量 - 使用deque存储最近两个值
        self.zs = deque([0.0, 0.0], maxlen=2)
    def reset(self):
        """重置算法状态"""
        self.zs.clear()
        self.zs.extend([0.0, 0.0])
    def __call__(self, xs):
        """
        处理一组采样点 - 与参考代码一致的接口
        Args:
            xs: 采样点序列
        Returns:
            计算出的振幅
        """
        self.reset()
        for x in xs:
            z1, z2 = self.zs[-1], self.zs[-2]  # Z[-1], Z[-2]
            z0 = x + self.c * z1 - z2  # S[n] = x[n] + C * S[n-1] - S[n-2]
            self.zs.append(float(z0))  # 更新序列
        return self.amp
    @property
    def amp(self) -> float:
        """计算当前振幅 - 与参考代码一致"""
        z1, z2 = self.zs[-1], self.zs[-2]
        ip = self.cw * z1 - z2
        qp = self.sw * z1
        return np.sqrt(ip**2 + qp**2) / (self.n / 2.0)
 class PairGoertzel:
    """双频Goertzel解调器"""
    def __init__(self, f_sample: int, f_space: int, f_mark: int, 
                 bit_rate: int, win_size: int):
        """
        初始化双频解调器
        Args:
            f_sample: 采样频率
            f_space: Space频率 (通常对应0)
            f_mark: Mark频率 (通常对应1)
            bit_rate: 比特率
            win_size: Goertzel窗口大小
        """
        assert f_sample % bit_rate == 0, "采样频率必须是比特率的整数倍"
        self.Fs = f_sample
        self.F0 = f_space
        self.F1 = f_mark
        self.bit_rate = bit_rate
        self.n_per_bit = int(f_sample // bit_rate)  # 每个比特的采样点数
        # 计算归一化频率
        f1 = f_mark / f_sample
        f0 = f_space / f_sample
        # 初始化Goertzel算法
        self.g0 = TraceGoertzel(freq=f0, n=win_size)
        self.g1 = TraceGoertzel(freq=f1, n=win_size)
        # 输入缓冲区
        self.in_buffer = deque(maxlen=win_size)
        self.out_count = 0
        print(f"PairGoertzel initialized: f0={f0:.6f}, f1={f1:.6f}, win_size={win_size}, n_per_bit={self.n_per_bit}")
    def __call__(self, s: float):
        """
        处理单个采样点 - 与参考代码一致的接口
        Args:
            s: 采样点值
        Returns:
            (amp0, amp1, p1_prob) - 空间频率振幅，标记频率振幅，标记概率
        """
        self.in_buffer.append(s)
        self.out_count += 1
        amp0, amp1, p1_prob = 0, 0, None
        # 每个比特周期输出一次结果
        if self.out_count >= self.n_per_bit:
            amp0 = self.g0(self.in_buffer)  # 计算space频率振幅
            amp1 = self.g1(self.in_buffer)  # 计算mark频率振幅
            p1_prob = amp1 / (amp0 + amp1 + 1e-8)  # 计算mark概率
            self.out_count = 0
        return amp0, amp1, p1_prob
 class RealTimeAFSKDecoder:
    """实时AFSK解码器 - 基于起始帧触发"""
    def __init__(self, f_sample: int = 16000, mark_freq: int = 1800, 
                 space_freq: int = 1500, bitrate: int = 100, 
                 s_goertzel: int = 9, threshold: float = 0.5):
        """
        初始化实时AFSK解码器
        Args:
            f_sample: 采样频率
            mark_freq: Mark频率
            space_freq: Space频率 
            bitrate: 比特率
            s_goertzel: Goertzel窗口大小系数 (win_size = f_sample // mark_freq * s_goertzel)
            threshold: 判决门限
        """
        self.f_sample = f_sample
        self.mark_freq = mark_freq
        self.space_freq = space_freq
        self.bitrate = bitrate
        self.threshold = threshold
        # 计算窗口大小 - 与参考代码一致
        win_size = int(f_sample / mark_freq * s_goertzel)
        # 初始化解调器
        self.demodulator = PairGoertzel(f_sample, space_freq, mark_freq, 
                                       bitrate, win_size)
        # 帧定义 - 与参考代码一致
        self.start_bytes = b'\x01\x02'
        self.end_bytes = b'\x03\x04'
        self.start_bits = "".join(format(int(x), '08b') for x in self.start_bytes)
        self.end_bits = "".join(format(int(x), '08b') for x in self.end_bytes)
        # 状态机
        self.state = "idle" # idle / entering
        # 存储解调结果
        self.buffer_prelude:deque = deque(maxlen=len(self.start_bits)) # 判断是否启动
        self.indicators = []  # 存储概率序列
        self.signal_bits = ""  # 存储比特序列
        self.text_cache = ""
        # 解码结果
        self.decoded_messages = []
        self.total_bits_received = 0
        print(f"Decoder initialized: win_size={win_size}")
        print(f"Start frame: {self.start_bits} (from {self.start_bytes.hex()})")
        print(f"End frame: {self.end_bits} (from {self.end_bytes.hex()})")
    def process_audio(self, samples: np.array) -> str:
        """
        处理音频数据并返回解码文本
        Args:
            audio_data: 音频字节数据 (16-bit PCM)
        Returns:
            新解码的文本
        """       
        new_text = "" 
        # 逐个处理采样点
        for sample in samples:
            amp0, amp1, p1_prob = self.demodulator(sample)
            # 如果有概率输出，记录并判决
            if p1_prob is not None:
                bit = '1' if p1_prob > self.threshold else '0'
                match self.state:
                    case "idle":
                        self.buffer_prelude.append(bit)
                        pass
                    case "entering":
                        self.buffer_prelude.append(bit)
                        self.signal_bits += bit
                        self.total_bits_received += 1
                    case _:
                        pass
                self.indicators.append(p1_prob)
                # 检查状态机
                if self.state == "idle" and "".join(self.buffer_prelude) == self.start_bits:
                    self.state = "entering"
                    self.text_cache = ""
                    self.signal_bits = ""  # 清空比特序列
                    self.buffer_prelude.clear()
                elif self.state == "entering" and ("".join(self.buffer_prelude) == self.end_bits or len(self.signal_bits) >= 256):
                    self.state = "idle"
                    self.buffer_prelude.clear()
                # 每收集一定数量的比特后尝试解码
                if len(self.signal_bits) >= 8:
                    text = self._decode_bits_to_text(self.signal_bits)
                    if len(text) > len(self.text_cache):
                        new_text = text[len(self.text_cache) - len(text):]
                        self.text_cache = text
        return new_text
    def _decode_bits_to_text(self, bits: str) -> str:
        """
        将比特串解码为文本
        Args:
            bits: 比特串
        Returns:
            解码出的文本
        """
        if len(bits) < 8:
            return ""
        decoded_text = ""
        byte_count = len(bits) // 8
        for i in range(byte_count):
            # 提取8位
            byte_bits = bits[i*8:(i+1)*8]
            # 位转字节
            byte_val = int(byte_bits, 2)
            # 尝试解码为ASCII字符
            if 32 <= byte_val <= 126:  # 可打印ASCII字符
                decoded_text += chr(byte_val)
            elif byte_val == 0:  # NULL字符，忽略
                continue
            else:
                # 非可打印字符pass，以十六进制显示
                pass
                # decoded_text += f"\\x{byte_val:02X}"
        return decoded_text
    def clear(self):
        """清空解码状态"""
        self.indicators = []
        self.signal_bits = ""
        self.decoded_messages = []
        self.total_bits_received = 0
        print("解码器状态已清空")
    def get_stats(self) -> dict:
        """获取解码统计信息"""
        return {
            'prelude_bits': "".join(self.buffer_prelude),
            "state": self.state,
            'total_chars': sum(len(msg) for msg in self.text_cache),
            'buffer_bits': len(self.signal_bits),
            'mark_freq': self.mark_freq,
            'space_freq': self.space_freq,
            'bitrate': self.bitrate,
            'threshold': self.threshold,
        }
--- a/scripts/acoustic_check/graphic.py
+++ b/scripts/acoustic_check/graphic.py
@ -0,0 +1,444 @@
 import sys
 import numpy as np
 import asyncio
 import wave
 from collections import deque
 import qasync
 import matplotlib
 matplotlib.use('qtagg')  
 from matplotlib.backends.backend_qtagg import FigureCanvasQTAgg as FigureCanvas
 from matplotlib.backends.backend_qtagg import NavigationToolbar2QT as NavigationToolbar  # noqa: F401
 from matplotlib.figure import Figure
 from PyQt6.QtWidgets import (QApplication, QMainWindow, QVBoxLayout, QWidget, 
                             QHBoxLayout, QLineEdit, QPushButton, QLabel, QTextEdit)
 from PyQt6.QtCore import QTimer
 # 导入解码器
 from demod import RealTimeAFSKDecoder
 class UDPServerProtocol(asyncio.DatagramProtocol):
    """UDP服务器协议类"""
    def __init__(self, data_queue):
        self.client_address = None
        self.data_queue: deque = data_queue
    def connection_made(self, transport):
        self.transport = transport
    def datagram_received(self, data, addr):
        # 如果还没有客户端地址，记录第一个连接的客户端
        if self.client_address is None:
            self.client_address = addr
            print(f"接受来自 {addr} 的连接")
        # 只处理来自已记录客户端的数据
        if addr == self.client_address:
            # 将接收到的音频数据添加到队列
            self.data_queue.extend(data)
        else:
            print(f"忽略来自未知地址 {addr} 的数据")
 class MatplotlibWidget(QWidget):
    def __init__(self, parent=None):
        super().__init__(parent)
        # 创建 Matplotlib 的 Figure 对象
        self.figure = Figure()
        # 创建 FigureCanvas 对象，它是 Figure 的 QWidget 容器
        self.canvas = FigureCanvas(self.figure)
        # 创建 Matplotlib 的导航工具栏
        # self.toolbar = NavigationToolbar(self.canvas, self)
        self.toolbar = None
        # 创建布局
        layout = QVBoxLayout()
        layout.addWidget(self.toolbar)
        layout.addWidget(self.canvas)
        self.setLayout(layout)
        # 初始化音频数据参数
        self.freq = 16000  # 采样频率
        self.time_window = 20  # 显示时间窗口
        self.wave_data = deque(maxlen=self.freq * self.time_window * 2) # 缓冲队列, 用于分发计算/绘图
        self.signals = deque(maxlen=self.freq * self.time_window)  # 双端队列存储信号数据
        # 创建包含两个子图的画布
        self.ax1 = self.figure.add_subplot(2, 1, 1)
        self.ax2 = self.figure.add_subplot(2, 1, 2)
        # 时域子图
        self.ax1.set_title('Real-time Audio Waveform')
        self.ax1.set_xlabel('Sample Index')
        self.ax1.set_ylabel('Amplitude')
        self.line_time, = self.ax1.plot([], [])
        self.ax1.grid(True, alpha=0.3)
        # 频域子图
        self.ax2.set_title('Real-time Frequency Spectrum')
        self.ax2.set_xlabel('Frequency (Hz)')
        self.ax2.set_ylabel('Magnitude')
        self.line_freq, = self.ax2.plot([], [])
        self.ax2.grid(True, alpha=0.3)
        self.figure.tight_layout()
        # 定时器用于更新图表
        self.timer = QTimer(self)
        self.timer.setInterval(100)  # 100毫秒更新一次
        self.timer.timeout.connect(self.update_plot)
        # 初始化AFSK解码器
        self.decoder = RealTimeAFSKDecoder(
            f_sample=self.freq,
            mark_freq=1800,
            space_freq=1500,
            bitrate=100,
            s_goertzel=9,
            threshold=0.5
        )
        # 解码结果回调
        self.decode_callback = None
    def start_plotting(self):
        """开始绘图"""
        self.timer.start()
    def stop_plotting(self):
        """停止绘图"""
        self.timer.stop()
    def update_plot(self):
        """更新绘图数据"""
        if len(self.wave_data) >= 2:
            # 进行实时解码
            # 获取最新的音频数据进行解码
            even = len(self.wave_data) // 2 * 2
            print(f"length of wave_data: {len(self.wave_data)}")
            drained = [self.wave_data.popleft() for _ in range(even)]
            signal = np.frombuffer(bytearray(drained), dtype='<i2') / 32768
            decoded_text_new = self.decoder.process_audio(signal) # 处理新增信号, 返回全量解码文本
            if decoded_text_new and self.decode_callback:
                self.decode_callback(decoded_text_new)
            self.signals.extend(signal.tolist())  # 将波形数据添加到绘图数据
        if len(self.signals) > 0:
            # 只显示最近的一段数据，避免图表过于密集
            signal = np.array(self.signals)
            max_samples = min(len(signal), self.freq * self.time_window)
            if len(signal) > max_samples:
                signal = signal[-max_samples:]
            # 更新时域图
            x = np.arange(len(signal))
            self.line_time.set_data(x, signal)
            # 自动调整时域坐标轴范围
            if len(signal) > 0:
                self.ax1.set_xlim(0, len(signal))
                y_min, y_max = np.min(signal), np.max(signal)
                if y_min != y_max:
                    margin = (y_max - y_min) * 0.1
                    self.ax1.set_ylim(y_min - margin, y_max + margin)
                else:
                    self.ax1.set_ylim(-1, 1)
            # 计算频谱（短时离散傅立叶变换）
            if len(signal) > 1:
                # 计算FFT
                fft_signal = np.abs(np.fft.fft(signal))
                frequencies = np.fft.fftfreq(len(signal), 1/self.freq)
                # 只取正频率部分
                positive_freq_idx = frequencies >= 0
                freq_positive = frequencies[positive_freq_idx]
                fft_positive = fft_signal[positive_freq_idx]
                # 更新频域图
                self.line_freq.set_data(freq_positive, fft_positive)
                # 自动调整频域坐标轴范围
                if len(fft_positive) > 0:
                    # 限制频率显示范围到0-4000Hz，避免过于密集
                    max_freq_show = min(4000, self.freq // 2)
                    freq_mask = freq_positive <= max_freq_show
                    if np.any(freq_mask):
                        self.ax2.set_xlim(0, max_freq_show)
                        fft_masked = fft_positive[freq_mask]
                        if len(fft_masked) > 0:
                            fft_max = np.max(fft_masked)
                            if fft_max > 0:
                                self.ax2.set_ylim(0, fft_max * 1.1)
                            else:
                                self.ax2.set_ylim(0, 1)
            self.canvas.draw()
 class MainWindow(QMainWindow):
    def __init__(self):
        super().__init__()
        self.setWindowTitle("Acoustic Check")
        self.setGeometry(100, 100, 1000, 800)
        # 主窗口部件
        main_widget = QWidget()
        self.setCentralWidget(main_widget)
        # 主布局
        main_layout = QVBoxLayout(main_widget)
        # 绘图区域
        self.matplotlib_widget = MatplotlibWidget()
        main_layout.addWidget(self.matplotlib_widget)
        # 控制面板
        control_panel = QWidget()
        control_layout = QHBoxLayout(control_panel)
        # 监听地址和端口输入
        control_layout.addWidget(QLabel("监听地址:"))
        self.address_input = QLineEdit("0.0.0.0")
        self.address_input.setFixedWidth(120)
        control_layout.addWidget(self.address_input)
        control_layout.addWidget(QLabel("端口:"))
        self.port_input = QLineEdit("8000")
        self.port_input.setFixedWidth(80)
        control_layout.addWidget(self.port_input)
        # 监听按钮
        self.listen_button = QPushButton("开始监听")
        self.listen_button.clicked.connect(self.toggle_listening)
        control_layout.addWidget(self.listen_button)
        # 状态标签
        self.status_label = QLabel("状态: 未连接")
        control_layout.addWidget(self.status_label)
        # 数据统计标签
        self.data_label = QLabel("接收数据: 0 bytes")
        control_layout.addWidget(self.data_label)
        # 保存按钮
        self.save_button = QPushButton("保存音频")
        self.save_button.clicked.connect(self.save_audio)
        self.save_button.setEnabled(False)
        control_layout.addWidget(self.save_button)
        control_layout.addStretch()  # 添加弹性空间
        main_layout.addWidget(control_panel)
        # 解码显示区域
        decode_panel = QWidget()
        decode_layout = QVBoxLayout(decode_panel)
        # 解码标题
        decode_title = QLabel("实时AFSK解码结果:")
        decode_title.setStyleSheet("font-weight: bold; font-size: 14px;")
        decode_layout.addWidget(decode_title)
        # 解码文本显示
        self.decode_text = QTextEdit()
        self.decode_text.setMaximumHeight(150)
        self.decode_text.setReadOnly(True)
        self.decode_text.setStyleSheet("font-family: 'Courier New', monospace; font-size: 12px;")
        decode_layout.addWidget(self.decode_text)
        # 解码控制按钮
        decode_control_layout = QHBoxLayout()
        # 清空按钮
        self.clear_decode_button = QPushButton("清空解码")
        self.clear_decode_button.clicked.connect(self.clear_decode_text)
        decode_control_layout.addWidget(self.clear_decode_button)
        # 解码统计标签
        self.decode_stats_label = QLabel("解码统计: 0 bits, 0 chars")
        decode_control_layout.addWidget(self.decode_stats_label)
        decode_control_layout.addStretch()
        decode_layout.addLayout(decode_control_layout)
        main_layout.addWidget(decode_panel)
        # 设置解码回调
        self.matplotlib_widget.decode_callback = self.on_decode_text
        # UDP相关属性
        self.udp_transport = None
        self.is_listening = False
        # 数据统计定时器
        self.stats_timer = QTimer(self)
        self.stats_timer.setInterval(1000)  # 每秒更新一次统计
        self.stats_timer.timeout.connect(self.update_stats)
    def on_decode_text(self, new_text: str):
        """解码文本回调"""
        if new_text:
            # 添加新解码的文本
            current_text = self.decode_text.toPlainText()
            updated_text = current_text + new_text
            # 限制文本长度，保留最新的1000个字符
            if len(updated_text) > 1000:
                updated_text = updated_text[-1000:]
            self.decode_text.setPlainText(updated_text)
            # 滚动到底部
            cursor = self.decode_text.textCursor()
            cursor.movePosition(cursor.MoveOperation.End)
            self.decode_text.setTextCursor(cursor)
    def clear_decode_text(self):
        """清空解码文本"""
        self.decode_text.clear()
        if hasattr(self.matplotlib_widget, 'decoder'):
            self.matplotlib_widget.decoder.clear()
        self.decode_stats_label.setText("解码统计: 0 bits, 0 chars")
    def update_decode_stats(self):
        """更新解码统计"""
        if hasattr(self.matplotlib_widget, 'decoder'):
            stats = self.matplotlib_widget.decoder.get_stats()
            stats_text = (
                f"前置: {stats['prelude_bits']} , 已接收{stats['total_chars']} chars, "
                f"缓冲: {stats['buffer_bits']} bits, 状态: {stats['state']}"
            )
            self.decode_stats_label.setText(stats_text)
    def toggle_listening(self):
        """切换监听状态"""
        if not self.is_listening:
            self.start_listening()
        else:
            self.stop_listening()
    async def start_listening_async(self):
        """异步启动UDP监听"""
        try:
            address = self.address_input.text().strip()
            port = int(self.port_input.text().strip())
            loop = asyncio.get_running_loop()
            self.udp_transport, protocol = await loop.create_datagram_endpoint(
                lambda: UDPServerProtocol(self.matplotlib_widget.wave_data),
                local_addr=(address, port)
            )
            self.status_label.setText(f"状态: 监听中 ({address}:{port})")
            print(f"UDP服务器启动, 监听 {address}:{port}")
        except Exception as e:
            self.status_label.setText(f"状态: 启动失败 - {str(e)}")
            print(f"UDP服务器启动失败: {e}")
            self.is_listening = False
            self.listen_button.setText("开始监听")
            self.address_input.setEnabled(True)
            self.port_input.setEnabled(True)
    def start_listening(self):
        """开始监听"""
        try:
            int(self.port_input.text().strip())  # 验证端口号格式
        except ValueError:
            self.status_label.setText("状态: 端口号必须是数字")
            return
        self.is_listening = True
        self.listen_button.setText("停止监听")
        self.address_input.setEnabled(False)
        self.port_input.setEnabled(False)
        self.save_button.setEnabled(True)
        # 清空数据队列
        self.matplotlib_widget.wave_data.clear()
        # 启动绘图和统计更新
        self.matplotlib_widget.start_plotting()
        self.stats_timer.start()
        # 异步启动UDP服务器
        loop = asyncio.get_event_loop()
        loop.create_task(self.start_listening_async())
    def stop_listening(self):
        """停止监听"""
        self.is_listening = False
        self.listen_button.setText("开始监听")
        self.address_input.setEnabled(True)
        self.port_input.setEnabled(True)
        # 停止UDP服务器
        if self.udp_transport:
            self.udp_transport.close()
            self.udp_transport = None
        # 停止绘图和统计更新
        self.matplotlib_widget.stop_plotting()
        self.matplotlib_widget.wave_data.clear()
        self.stats_timer.stop()
        self.status_label.setText("状态: 已停止")
    def update_stats(self):
        """更新数据统计"""
        data_size = len(self.matplotlib_widget.signals)
        self.data_label.setText(f"接收数据: {data_size} 采样")
        # 更新解码统计
        self.update_decode_stats()
    def save_audio(self):
        """保存音频数据"""
        if len(self.matplotlib_widget.signals) > 0:
            try:
                signal_data = np.array(self.matplotlib_widget.signals)
                # 保存为WAV文件
                with wave.open("received_audio.wav", "wb") as wf:
                    wf.setnchannels(1)  # 单声道
                    wf.setsampwidth(2)  # 采样宽度为2字节
                    wf.setframerate(self.matplotlib_widget.freq)  # 设置采样率
                    wf.writeframes(signal_data.tobytes())  # 写入数据
                self.status_label.setText("状态: 音频已保存为 received_audio.wav")
                print("音频已保存为 received_audio.wav")
            except Exception as e:
                self.status_label.setText(f"状态: 保存失败 - {str(e)}")
                print(f"保存音频失败: {e}")
        else:
            self.status_label.setText("状态: 没有足够的数据可保存")
 async def main():
    """异步主函数"""
    app = QApplication(sys.argv)
    # 设置异步事件循环
    loop = qasync.QEventLoop(app)
    asyncio.set_event_loop(loop)
    window = MainWindow()
    window.show()
    try:
        with loop:
            await loop.run_forever()
    except KeyboardInterrupt:
        print("程序被用户中断")
    finally:
        # 确保清理资源
        if window.udp_transport:
            window.udp_transport.close()
--- a/scripts/acoustic_check/main.py
+++ b/scripts/acoustic_check/main.py
@ -0,0 +1,18 @@
 #!/usr/bin/env python3
 """
 音频实时监听与绘图系统主程序
 基于Qt GUI + Matplotlib + UDP接收 + AFSK解码字符串
 """
 import sys
 import asyncio
 from graphic import main
 if __name__ == '__main__':
    try:
        asyncio.run(main())
    except KeyboardInterrupt:
        print("程序被用户中断")
    except Exception as e:
        print(f"程序执行出错: {e}")
        sys.exit(1)
--- a/scripts/acoustic_check/readme.md
+++ b/scripts/acoustic_check/readme.md
@ -0,0 +1,23 @@
 # 声波测试
 该gui用于测试接受小智设备通过`udp`回传的`pcm`转时域/频域, 可以保存窗口长度的声音, 用于判断噪音频率分布和测试声波传输ascii的准确度,
 固件测试需要打开`USE_AUDIO_DEBUGGER`, 并设置好`AUDIO_DEBUG_UDP_SERVER`是本机地址.
 声波`demod`可以通过`sonic_wifi_config.html`或者上传至`PinMe`的[小智声波配网](https://iqf7jnhi.pinit.eth.limo)来输出声波测试
 # 声波解码测试记录
 > `✓`代表在I2S DIN接收原始PCM信号时就能成功解码, `△`代表需要降噪或额外操作可稳定解码, `X`代表降噪后效果也不好(可能能解部分但非常不稳定)。
 > 个别ADC需要I2C配置阶段做更精细的降噪调整, 由于设备不通用暂只按照boards内提供的config测试
 | 设备 | ADC | MIC | 效果 | 备注 |
 | ---- | ---- | --- | --- | ---- |
 | bread-compact | INMP441 | 集成MEMEMIC | ✓ |
 | atk-dnesp32s3-box | ES8311 | | ✓ |
 | magiclick-2p5 | ES8311 | | ✓ |
 | lichuang-dev  | ES7210 | | △ | 测试时需要关掉INPUT_REFERENCE
 | kevin-box-2 | ES7210 | | △ | 测试时需要关掉INPUT_REFERENCE
 | m5stack-core-s3 | ES7210 | | △ | 测试时需要关掉INPUT_REFERENCE
 | xmini-c3 | ES8311 | | △ | 需降噪
 | atoms3r-echo-base | ES8311 | | △ | 需降噪
 | atk-dnesp32s3-box0 | ES8311 | | X | 能接收且解码, 但是丢包率很高
 | movecall-moji-esp32s3 | ES8311 | | X | 能接收且解码, 但是丢包率很高
--- a/scripts/acoustic_check/requirements.txt
+++ b/scripts/acoustic_check/requirements.txt
@ -0,0 +1,4 @@
 matplotlib==3.10.5
 numpy==2.3.2
 PyQt6==6.9.1
 qasync==0.27.1