全数字控制可控硅调光LED驱动器设计

根据高亮LED特点,结合可控硅的斩波原理,提出一种运用FLYBACK和DC-DC相结合的两级拓扑结构、采用MCU进行全数字控制的调光驱动方案,解决了应用可控硅调光器对LED进行调光以及驱动器对可控硅调光器的兼容性问题.实验表明,所设计的驱动器能很好地实现调光功能,具有良好的应用前景.     

SanDisk推出全球首项高效能4-BITS-PER-CELL（X4）闪存科技

2月17日,恩智浦半导体宣布推出世界首款集成可调光市电LED驱动器——SSL2101。恩智浦SSL2101是一款小尺寸开关模式电源（SMPS）控制器IC,专为驱动LED设备而设计,并且提供可调光能力,以进一步改善LED照明的能效。     

一种基于DALI总线的智能LED照明系统的设计

为了提高智能照明系统的性价比,提出了一种基于DALI总线的智能LED照明设计方案,关键技术包括DALI控制模块和可调光驱动电源的设计。系统通过应用微控制器（MCU）、通用的模拟和数字电路来代替昂贵的DALI专用芯片,实现了DALI控制的功能;LED驱动电源应用软开关技术,具有DALI接口和多种传感器接口,并具有应急照明的功能;系统可实现对LED灯的PWM调光和智能化控制。制作了样机并进行了相关实验,验证了方案的可行性。     

一款基于通用IC的低成本汽车日行灯HB LED驱动电路的设计

设计了一款基于通用IC LM5022的低成本汽车日行灯HB LED驱动电路,实现了HB LED的恒流驱动和PWM调光,并能满足日行灯的有关驱动要求。详细介绍了调光控制线路的设计,并对调光信号的时序和调光比影响因素等进行了分析,给出了主要实验参数和实验结果,输入电压6～19 V,输出电压40～57 V,PWM调光占空比可调5%～100%,输出LED电流200 mA,有关实验验证了本设计的可行性。     

光学仪器照明用的大功率LED驱动电源设计

据光学仪器照明系统的要求并结合大功率LED的特性,设计了一种可调光的大功率LED恒流驱动电路.既可对LED进行PWM调光,又能有效解决大功率LED的散热问题.与卤素灯等传统光源的驱动电路相比,它还具有体积小,低成本等优势,故可广泛应用于光学仪器的照明系统中.     

投影仪的LED光源驱动器的设计

介绍了在采用LED做光源的投影仪中,如何设计LED光源的驱动电路.分析了负压型Buck电路的设计及PWM调光电路、短路保护、过压保护、环路测试等问题.     

HB-LED医用手术头灯控制系统的设计与实现

研制了以高亮度LED为光源的医用手术头灯控制系统。该系统由电源路径管理电路、充电管理电路、LED驱动电路和调光电路组成。采用外部电源或者电池双电源供电,可驱动5W的大功率白光LED,同时具备LED亮度连续调节和电池充电管理等功能。LED亮度调节实验和锂电池充电实验表明该控制电路很好地符合了预期的设计要求,LED控制电路具有很强的通用性,体积小、价格低廉,适合于便携式电子产品的设计应用。     

无线遥控LED调光调色灯的设计与实现

针对传统照明光源不能调色或调光深度不足的现象,选用功率为1 W的三基色发光二极管(RGB LED)为灯体,基于无线遥控和智能控制技术,通过PWM技术实现了LED灯白光的亮度调节、魔幻变色的自由切换及单色光输出的功能。系统由电源电路、一体化红外遥控接收头、CPU和三路LED驱动组成。采用低成本的STC15W201-SOP8单片机作为主控器件,用定时器作为三路的PWM发生器,驱动低开启电压的NMOS管以实现调光与调色。通过程序的巧妙设计实现了在0~360。过渡时无明显颜色跳变的现象。该可调光调色LED灯经长时间使用,调光调色效果理想且稳定可靠,可供该产品设计以参考。     

基于单片机控制的高效率LED驱动电源的设计

针对两级式结构驱动电源效率偏低的问题,设计了一款基于单片机控制的高效率LED驱动电源.我们首先设计了LED驱动电源的硬件电路,包括PFC升压电路及DC/DC降压变换电路.在此基础上,对DC/DC降压变换电路的参数进行了选择.进一步将硬件电路与单片机控制程序结合来提高LED电源效率.最后设计了一台功率为50W的LED样机,实验结果验证了用单片机控制LED驱动电源能有效的将LED电源效率提高到93％以上.     

基于C51单片机的LED驱动电源设计研究

单片机是LED驱动电源系统的核心部件,它控制着LED驱动电源的脉冲信号,能够提高电源输出的效率,同时提高设备能效.本文对基于C51单片机的LED驱动电源的设计方案进行研究,首先论述了LED驱动方式以及驱动器,进而探究了LED驱动电源设计的整体方案、控制电路设计及软件设计,最后以某测试项目探讨了基于C51单片机的LED驱...     

A fast transient LED driver with adaptive frequency control according to load variation for large‐sized LCD backlights

A fast transient light‐emitting diode (LED) driver is proposed for large‐sized liquid crystal display TV backlights in attempt to shorten the recovery time and to reduce the voltage fluctuation, while maintaining a high power efficiency. The direct current‐direct current (DC–DC) converter in the proposed LED driver accurately detects the load variation using the dimming data and then adjusts the slew rate and operating frequency according to the detected load variation. Thus, it rapidly controls the turn‐on time of the power switch and then controls the inductor current so that the output of the proposed LED driver can be accurately regulated during the load transient time. To verify the performance of the proposed LED driver, a DC–DC converter and an expandable LED current controller were fabricated using a 0.35‐μm bipolar–complementary metal–oxide–semiconductor (CMOS)–double‐diffused metal–oxide–semiconductor (DMOS) process technology and assembled with 48 LED channels for measurement. The measurement results show that the proposed LED driver improves the recovery time and voltage fluctuation by 45.1% and 45.6%, respectively. In addition, it achieves a maximum power of 115.2 W and a maximum power efficiency of 89.2%. Therefore, the proposed LED driver is suitable for high‐end applications such as large‐sized LED TV backlight modules.     

LED调光控制技术在飞机导光板照明中的应用

描述了LED技术在飞机驾驶舱照明控制系统中的应用情况,针对目前民用飞机驾驶舱导光板照明普遍采用的LED电压调光技术和单纯PWM调光技术的不足,提出了改进的LED调光技术方案。新型方案利用组合调光技术和数字调光技术,弥补了传统LED调光技术的不足,并对不同的LED调光控制方案进行了分析,最后提出了LED调光技术的发展方向。     

无线调控LED照明系统设计

目前家用LED多以功能性照明为主要目的．难以满足用户个性化、艺术化消费需求,为此,采用STC12LE5410AD微控制器、LT3756驱动器和nRF24L01＋．G线收发器,设计一种无线调控的LED照明系统．利用PWM调光和1KGB混色技术产生不同的光强和色温效果,实现家用LED照明的场景化控制。系统配置灵活,操作简便,性价比高,推广前景较好。     

一种用于白光LED的亮度控制电路

针对白光LED的广泛应用,要求其亮度能够方便地被调节,提出一种用于白光LED的亮度控制电路;电路只需一个亮度控制脉冲信号作为激励,就能够循环产生10位的亮度控制信号输出,控制10级亮度变化,并给出了具体应用电路,在应用时,10位输出信号控制开关管,使得流过白光LED的电流发生变化,从而控制其亮度;该电路采用0.6um的BiCMOS工艺设计,利用Hspice进行仿真验证,结果表明,电路滤除宽度小于500ns的脉冲信号,去除噪声和干扰,能够正确地循环产生10位的亮度控制信号,响应延迟为400ns。     

LED PWM dimming linearity investigation

LED PWM dimming application for large scale LED video displays is analyzed. The need for short light pulse duration is outlined. PWM dimming with short driving pulses is investigated experimentally. The LED response time skew introduces the nonlinearity for PWM dimming. For LED response time skew estimation, a method is suggested that has been successfully applied to measure some of today’s market representative LEDs. PWM dimming nonlinearity can be forecasted using the estimated skew. For a particular driving configuration, it is indicated that LED PWM dimming fails to satisfy the required 14 bit output coding together with the image refresh frequency of 400 Hz. A rough investigation demonstrates that the skew is quite stable. Therefore, the nonlinearity correction for the PWM pulse durations shorter than the skew value should be possible.     

High‐performance high‐efficiency LED‐backlight driving system for LCD panels

Abstract— A high‐performance high‐efficiency LED‐backlight driving system for liquid‐crystal‐display panels is presented. The proposed LED‐backlight driving system is composed of a high‐efficiency DC‐DC converter capable of operating over a universal AC input voltage (75–265 V) and a high‐performance LED‐backlight sector‐dimming controller. The high efficiency of the system is achieved by using an asymmetrical half‐bridge DC‐DC converter that utilizes a new voltage‐driven synchronous rectifier and an LED‐backlight sector‐dimming controller. This controller regulates current using lossless power semiconductor switches (MOSFETs). The power semiconductor switches of the proposed DC‐DC converter, including the synchronous rectifier switch, operate with zero voltage, achieving high efficiency and low switch voltage stress using the asymmetrical‐PWM and synchronous rectifier techniques. To achieve high performance, the proposed driving system performs the sector dimming and the current regulation using low‐cost microcontrollers and MOSFET switching, resulting in high contrast and brightness. A100‐W laboratory prototype was built and tested. The experimental results verify the feasibility of the proposed system.