Current Feedforward Phase Compensation Technique for an Integrator and Its Application to an Auto-Compensation System(Special Section on Papers Selected from ITC-CSCC 2001)
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概要
- 論文の詳細を見る
The transfer characteristic of an integrator is affected by excess-phase shift caused by the parasitic capacitance. The phase compensation is obtained by introducing zeros to generate phase lead. This paper proposes a phase compensation technique for the differential signal input integrator. The proposed technique is employing feedforward signal current source. The fifth-order leapfrog Chebyshev low-pass filter with 0.5dB passband ripple is designed using the integrator with the proposed phase compensation. Further, an autotuning phase compensation system using the proposed technique is realized by applying a PLL system. The effectiveness of the proposed technique is confirmed by PSPICE simulation. The simulation results of the integrator with the proposed phase compensation shows that excess-phase cancellation is obtained at various unity gain frequencies. The accurate filter characteristic of the fifth-order leapfrog filter is obtained by using the autotuning phase compensation system. The passband of the filter is improved over wide range of frequencies. The proposed technique is suitable for low voltage application.
- 2002-06-01
著者
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MATSUMOTO Fujihiko
Department of Applied Physics, National Defense Academy
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NOGUCHI Yasuaki
Department of Applied Physics, National Defense Academy
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Noguchi Y
The Department Of Applied Physics National Defense Academy
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Noguchi Yasuaki
Department Of Applied Electronics Tokyo Institute Of Technology
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WASAKI Hiroki
National Defense Academy
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WASAKI Hiroki
Department of Applied Physics, National Defense Academy
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Matsumoto F
The Department Of Applied Physics National Defense Academy
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Matsumoto Fujihiko
Department Of Applied Physics National Defense Academy
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