A high power buck-boost switch-mode LED driver delivering a constant 350 mA with a power efficient current sensing scheme is presented in this paper. The LED current is extracted by differentiating the output capacito...A high power buck-boost switch-mode LED driver delivering a constant 350 mA with a power efficient current sensing scheme is presented in this paper. The LED current is extracted by differentiating the output capacitor voltage and maintained by a feedback. The circuit has been fabricated in a standard 0.35 μm AMS CMOS process. Measurement results demonstrated a power-conversion efficiency over 90% with a line regulation of 8%/V for input voltage of 3.3 V and current output between 200 mA and 350 mA.展开更多
在含非线性负载的光伏并网系统中,光伏发电单元、非线性负载、电网三者之间的相互作用可能导致系统出现振荡,因此提出一种改进的电容电流反馈有源阻尼(capacitor current feedback active damping, CCFAD)控制方法。首先,采用谐波线性...在含非线性负载的光伏并网系统中,光伏发电单元、非线性负载、电网三者之间的相互作用可能导致系统出现振荡,因此提出一种改进的电容电流反馈有源阻尼(capacitor current feedback active damping, CCFAD)控制方法。首先,采用谐波线性化方法建立含非线性负载的光伏并网系统序阻抗模型,并基于阻抗模型和对数频率稳定判据揭示含非线性负载的光伏并网系统振荡特性。随后,基于负电阻理论定义阻抗相对灵敏度指标,评价不同参数变化对系统阻抗特性的影响程度,获取影响系统稳定性的关键参数。基于不同参数的阻抗相对灵敏度分析,提出一种改进的CCFAD方法。该方法拓展了传统CCFAD的正阻尼区域,有效地改善了系统输出阻抗的相位裕度,提高了系统稳定性。最后,在Matlab/Simulink中搭建仿真模型,验证了分析方法的正确性和所提控制策略的有效性。展开更多
文摘A high power buck-boost switch-mode LED driver delivering a constant 350 mA with a power efficient current sensing scheme is presented in this paper. The LED current is extracted by differentiating the output capacitor voltage and maintained by a feedback. The circuit has been fabricated in a standard 0.35 μm AMS CMOS process. Measurement results demonstrated a power-conversion efficiency over 90% with a line regulation of 8%/V for input voltage of 3.3 V and current output between 200 mA and 350 mA.
文摘在含非线性负载的光伏并网系统中,光伏发电单元、非线性负载、电网三者之间的相互作用可能导致系统出现振荡,因此提出一种改进的电容电流反馈有源阻尼(capacitor current feedback active damping, CCFAD)控制方法。首先,采用谐波线性化方法建立含非线性负载的光伏并网系统序阻抗模型,并基于阻抗模型和对数频率稳定判据揭示含非线性负载的光伏并网系统振荡特性。随后,基于负电阻理论定义阻抗相对灵敏度指标,评价不同参数变化对系统阻抗特性的影响程度,获取影响系统稳定性的关键参数。基于不同参数的阻抗相对灵敏度分析,提出一种改进的CCFAD方法。该方法拓展了传统CCFAD的正阻尼区域,有效地改善了系统输出阻抗的相位裕度,提高了系统稳定性。最后,在Matlab/Simulink中搭建仿真模型,验证了分析方法的正确性和所提控制策略的有效性。