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backend/planner/plan_output/原镜频测试用例参考_plan_20260204_171618.md
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backend/planner/plan_output/原镜频测试用例参考_plan_20260204_171618.md
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# 📘 自动化测试任务规划
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**来源文档:** `原镜频测试用例参考`
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**生成时间:** 2026-02-04 17:16:18
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---
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## 📝 测试规划内容
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## 自动化测试方案 - 上电镜频测试 (补充完善版)
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### 一、测试需求分析
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1. 核心器件连接验证:
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- 28V/6A直流电源供电路径完整性
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- 3种信号源控制协议(TCP/IP/SCPI)
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- 镜频计算符合Hittinger公式:f_image = f_cen + (f_cen - f_sig)(需验证修正方式)
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2. 镜频测试维度:
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- **SC波段**:2.7GHz(信号源基准) → 3.88GHz(对应镜像频率)
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- **X波段**:8GHz(信号源基准) → 9.44GHz(原始要求) 与 11GHz(用户需求矛盾点)
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- 需确认测试规程:当SC信号源频率f=2.7GHz时,默认镜像应为3.84GHz(根据原知识库),但用户文档显示3.88GHz(可能为录入错误)
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### 二、补充完整测试内容
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#### 2.1 测试流程拓扑
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```
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系统准备 → 频段切换 → RF参数配置 → 频谱仪测量 → 数据处理 → 异常处理 → 系统恢复
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```
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#### 2.2 测试步骤详细化
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**2.2.1 上电标准化配置**
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1. 电源初始化检查
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```python
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assert power_supply.ovenPower("OCP 30V", "OVP 35V") # 28-30V安全范围
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assert power_supply.getVoltage() == 28.0
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assert abs(power_supply.getCurrent() - 2.9) < 0.2
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```
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2. 信号源时序控制强化
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- 增加"pulse_modulation_on()"状态检查
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- 添加"avoid_impulse()"函数防止脉冲串(周期1ms≠脉宽2us)
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**2.2.2 镜频测试执行矩阵**
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| 测试组 | 信号源频段 | 信号源设置 | 频谱仪测量点 | 预期规范 | 异常阈值 |
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|--------|------------|------------|--------------|----------|----------|
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| SC-1 | 2.7GHz | power=-25dBm | 2.7GHz/3.88GHz | ΔP>7dB | <60dBc |
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| SC-2 | 6.2GHz | power=-25dBm | 6.2GHz/5.88GHz | ΔP>7dB | <60dBc |
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| X-1 | 8GHz | power=-40dBm | 8GHz/9.44GHz | ΔP>20dB | <61dBc |
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| X-2 | 12GHz | power=-40dBm | 12GHz/10.54GHz | ΔP>20dB | <61dBc |
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**说明**:
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- X波段测试存在指标断层:用户要求8GHz和12GHz均>20dB,但原知识库未明确
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- 需补充X波段8GHz的镜像频率计算:Span=500MHz情境下,镜像约=8GHz + (8GHz-8GHz)=8GHz(此数据可能需重新校验)
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**2.2.3 测试用例参数化设计**
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```python
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maxH_keep_time = 3 # 构建trace需要足够采样时间
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test_cases = [
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{
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"band": "SC",
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"test_points": [
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{"tx_freq": XStartFreq, "power": -25, "meas_freqs": [XStartFreq, imageSpectrumFreqSC[0]]},
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{"tx_freq": SCStopFreq, "power": -25, "meas_freqs": [SCStopFreq, imageSpectrumFreqSC[1]]}
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],
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"power_margin": 0.5 # 补充±5%容差处理
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},
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{
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"band": "X",
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"test_points": [
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{"tx_freq": XStartFreq, "power": -40, "meas_freqs": [XStartFreq, 9.44]}, # 原有变量
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{"tx_freq": XStopFreq, "power": -40, "meas_freqs": [XStopFreq, imageSpectrumFreqX[1]]} # 变量化处理
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],
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"power_margin": 1.2
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}
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]
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```
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#### 2.3 测试执行规范完善
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1. 三阶段消噪机制:
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```python
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while freq_spectrum == signal_freq:
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freq_spectrum = cal.image_freq(signal_freq) # 重计算真实镜像点
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spec_analyzer.clearTrace(wait=0.5)
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spec_analyzer.setIgnorePoint(freq_spectrum) # 屏蔽信号主频段
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```
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2. 交叉验证逻辑:
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- 当X.SCBonus测量值出现异常时,自动触发比对测量:
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```diff
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if (P1 - P2) < min_rejection_threshold:
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spec_analyzer.setIgnorePoint(10.54) # 增加15GHz误差捕获
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retry 3:
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P1, P2 = measure_differential()
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```
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3. 多轮测试稳态判断:
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```python
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for i in range(5): # 5轮测试窗口
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test_result.append(software_calculate(P1_i - P2_i))
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pass_condition = all(x > valid_low_limiter for x in test_result)
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```
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#### 2.4 异常处理扩展
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1. 线性衰减补偿:
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- 通过"cal.linear_attenuation"模型对信号源衰减值进行预补偿
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- 示例:当发现P1-P2>80dB时,自动检查attenuator校准状态
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2. 波导连接状态监控:
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```python
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while signal_power_adj(INPUT_PWELLING) != Xpower:
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wait_for_stabil()
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if wait_timeout():
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log_matrix.error("SwitchMatrix lock failed", channel, timestamp)
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```
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3. RF泄露防护:
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- 频谱仪在测量异常频点时自动增加50dB衰减插件
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- 在X.SCBonus切换时增加"purge"指令消除残余信号
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#### 2.5 测试报告改进
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**镜频差值矩阵** | **刘韶频测试报告块状**
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```markdown
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{
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"channel": "SC",
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"system_config": {
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"power": 28V,
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"current": 2.9A,
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"signal_pw": -25dBm
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},
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"measurements": [
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{
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"test_freq": 2.7GHz,
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"image_freq": 3.88GHz,
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"P1": 25dBm,
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"P2": 12dBm,
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"ΔP": 13dB,
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"pass": true # 推导过程补充
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},
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{...}
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]
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}
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```
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**表格增强建议**:
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| 当名 | 通道 | 电源状态(Wat) | 信号源设置 | 测点次数 | 镜频差平均值 | 饱和点存档 |
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|------|------|--------------|------------|----------|--------------|------------|
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### 三、风险防控点
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1. **Two-tone测试干扰监测**:建议在测试中增加两个信号同时发射的场景
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2. **相位噪声校正**:SC波段需要特别处理相位噪声引起的10%偏移量误差
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3. **开关矩阵记忆效应回避**:通道切换后需3秒完全恢复时间
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### 四、测试序列验证
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建议采用HierarchicalState验证模板:
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```python
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@bellychesttestingSC
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def automated_loop(channel_list):
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init仪器状态()
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for channel in channel_list:
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run_on_band(channel) # Rework上层抽象逻辑
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close仪器()
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def run_on_band(band_choice):
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while<6C> is adjustable:
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on_point(band_choice.test_points[i])
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```
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### 五、实施重点
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- 在开关矩阵状态转换时补充_hystersis_time逻辑
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- 对X波段8GHz测试点实施Dual LO监测机制
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#### [验证结论]
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当前需注意X波段测试点1的镜像频率值存在差异(9.44 vs 11GHz),建议根据仪器实测结果确认最终镜像点设置,并在SwitchMatrix配置时增加该冲突点的仲裁处理。SC波段的镜像验证窗口建议增加LowNoiseAMP开关状态的监测参数。
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---
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## 📌 说明
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本规划由智能体自动生成,内容遵循自然语言任务规划格式,可直接用于后续自动化测试代码生成。
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