這項工提出並演示了基於簡單壓電能量收集模型與升壓轉換器相結合的 IC 設計。製作了壓電能量收集模型，為了響應各個方位的振動，以及IC生產的尺寸限制，製作了小於4mm*4mm的壓電能量收集矩陣。此外，還使用 CoventorWare和MEMS+進行了壓電能量收集矩陣模型分析。Cadence構建並分析了適用於壓電能量收集矩陣模型的能量轉換電路。壓電能量收集矩陣模型和能量轉換電路是用MEMS+和Cadence合作實現的。在Cadence上分析和生產集成IC。實驗結果表明，通過上述軟件的配合，可以更容易地實現集成能量收集和能量轉換於一體的集成電路。設計和製造的成本和勞動力大大減少。

This work proposes and demonstrates an IC design based on a simple piezoelectric energy harvesting model combined with a boost converter. A piezoelectric energy harvesting model was made, and to respond to each azimuth's vibration, and the size limitation of IC production, a piezoelectric energy harvesting matrix smaller than 4mm*4mm was made. Moreover, analyzed using CoventorWare and MEMS+. Cadence constructed and analyzed an energy conversion circuit suitable for the piezoelectric energy harvesting matrix model. The piezoelectric energy harvesting matrix model and the energy conversion circuit are implemented in cooperation with MEMS+ and Cadence. Analyze and produce integrated IC on Cadence. Experimental results show that an integrated circuit integrating energy harvesting and energy conversion can be realized more easily through the above software's cooperation. The cost and workforce of design and manufacture are greatly reduced.

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