本文介绍了一种基于医用数字红外传感器MLX90615的红外耳温计设计。基于红外测温原理,耳温计主要由数字红外传感器、低功耗CPU、液晶显示屏和其他外围电路组成。CPU通过I2C总线读取MLX90615采集的红外辐射信号,将其转换为对应的耳腔温度值并显示在液晶屏上。实验表明,该耳温计分辨率达到了0.02℃,准确度达到了0.1℃,实现了耳温的准确、快速测量。红外耳温计的优点传统体温测量是使用水银温度计进行接触式测量,具有性能稳定、误差小等优点,但存在测量时间长、交叉传染风险大、玻璃破碎易引起汞中毒等缺点。
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动力电池将新能源汽车的动力电池驱动压缩机需要几个步骤,首先要将直流电转化为交流电(逆变),然后调整交流电频率使其能稳定驱动压缩机中的电机,该部分的功能部件在车辆中以空调驱动单元存在。说到高压、逆变、变频、电机这些名词时,想必工程师们会立刻想到一个名词:干扰。新能源车空调系统干扰的*终结果就是空调控制器与中控单元之间错误帧增多、通信不畅甚至直接损坏控制板上的CAN收发器。因此相比于燃油车,新能源车的空调系统特殊性使其不可避免的要进行CAN总线通信隔离。
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因此对位同步的要求非常高,要满足这样的要求只能使用的石英晶振(石英晶振的误差通常小于0.1%.)。图1位定时段(位速率和总线长度乘积为值)的规格图1所示为位定时段(位速率和总线长度乘积为值)的规格。这样的要求主要应用于工业自动化系统。如果对位速率和总线长度的要求不高,那么位速率和总线长度的乘积也因此降低,而用于重新同步的时间缓冲段则可延长。这样根据可能的同步跳转宽度,在一次重新同步中可校正|e|=4的相位误差。
