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Internet of Things(ITT)的团队承诺的高分辨率数据,可以analyzed能源监测。在一次能源计量是largely约束两个接口之间的电力公用设施和客户的组织,是寻找更详细的个人信息从机器设备和部件。
设计的激光能量测量子可以是一个重大的挑战,因为他们需要认真注意的模拟信号链和复杂的computaTIonal的能力。在的情况下的三相计量应用ADI的受害者,一个单芯片解决方案,ade9078,这dramaTIcally simplifies实施方案的效用米和电力监控应用。
这将为你的第三个核心要求相能源监测信号链、技术链,已经产生,然后在ade9078住宅和如何实施它。
The energy monitoring signal chain
Engineers have in the past relied on discrete devices and analog-to-digital converters (ADCs) to build energy meters. The emergence of analog front-end (AFE) ICs allowed engineers to replace complex signal acquisiTIon circuits with a single device that integrated ADCs, amplifiers, and filters into an opTImized signal chain. Instead of dealing with the device matching and circuit tuning required by discrete solutions, engineers could rely on the integrated AFE to deliver a properly conditioned signal to an MCU or DSP for calculation of power characteristics.
The integration of MCU or DSP cores into specialized metrology AFEs provided developers with an even more effective solution. Using these devices, engineers could rapidly develop residential energy meters for common single-phase power lines.
For more complex three-phase energy measurement, developers found few effective options aside from once again building custom signal chains using high-performance multi-channel ADCs and amplifiers. Using this approach, however, developers were left to deal with the challenge of not only building tuned signal chains, but also ensuring synchronization of measurements across each phase. Engineers typically opted instead for polyphase meter designs using a separate AFE for each phase as shown in Figure 1.
