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MSL2164:16串LED驱动器规划攻略详解

MSL2164和MSL2166器件以高电流精度和LED串匹配来驱动外部MOSFET,这些器件具有爱特梅尔LED驱动器产品系列中最宽的调光分辨率,能够提高对比度,与其它解决方案相比,功耗降低至少20%。

MSL2164和MSL2166器材以高电流精度和LED串匹配来驱动外部MOSFET, 这些器材具有爱特梅尔LED驱动器产品系列中最宽的调光分辨率,可以进步对比度,与其它解决方案比较,功耗下降至少20%。
曩昔,TV OEM厂商有必要核算适宜的参数,以便有效地照亮所要求的显示屏背光区域。LED驱动器将生成算法以设置适宜的LED串相位,优化背光与LCD面板的同步。 OEM厂商有必要常常履行附加算法以调理LED串相位,保证背光在帧改写期间彻底同步。MSL2164和MSL2166具有多种脉宽调制(PWM)形式, 包含正向、逆向、拖尾和中心,因为新器材中集成了守时算法,规划复杂性得以下降,这保证背光在所有LCD像素现已安稳的最佳时间照亮。

The MSL2164 and MSL2166 are highly integrated, flexible,16-string LED drivers that use external MOSFETs to allowhigh LED string currents and/or voltage. They include powersupply control to maximize efficiency and an advancedPWM dimming control circuit for regional dimming and 3DLED backlights. The drivers optionally connect to a videosubsystem to offer a simple architecture for use in LCD TVbacklight applications. Up to eight devices easily connecttogether to drive large numbers of LED strings in a system.

MSL2164引脚图:

MSL2164功用框图

The drivers provide multiple methods of controlling LEDbrightness, through both LED regulation current control andthrough PWM dimming. Set the LED current to control colorand use pulse width control for brightness management andmotion blur reduction. An on-chip EEPROM stores all thedefault control register values, which are applied at start-upand reconfigured through the serial data interface.

MSL2164时序图:

The MSL2164/MSL2166 interface to a microcontroller or FPGA via SPI. The 20MHz bus addressable SPI interfacesupports up to eight devices per Chip Select line. LED PWMdimming is internally generated and synchronized to thevideo VSYNC and HSYNC signals or directly controlled by anexternal PWM drive signal applied to the PWM input. Theyalso feature phase spreading when external PWM dimming,with a progressive 1/16 phase delay per string to reduceLED power supply transient load and reduce power supplyinput capacitor size.

PWM dimming is either synchronized to an external signalapplied to PHI, generated from the internal oscillator forstand-alone applications or set directly by a signal at thePWM input. For video systems, derive the PHI signal fromVSYNC. A 1x to 32x frequency multiplier processes PHIfor PWM dimming at multiples of the video frame rate.

Individually program each string’s “on” time with up to 12-bitresolution when using the integrated PWM generator. Thefinal PWM dimming resolution depends upon the ratio of theprocessed GSC to processed PHI frequencies, because the“on” time is an integer number of GSC clock cycles between0 and 4095, and is scaled by the value of the 12-bit globalintensity register. Phase delay is also an integer number ofprocessed GSC clock cycles, to synchronize timing to thevideo frame. An on-chip frequency multiplier is provided inorder to fully utilize the 12-bit dimming range. The “on” timecount can be further scaled by a 12-bit global intensity value.

The processed GSC signal (the signal after being frequencymultiplied or divided, from either internally or externallygenerated signal at GSC) precisely sets each string’s phasedelay so that it is synchronized to its physical position onthe LCD panel, relative to the beginning, middle or endof the video frame. There are four different types of PWMmodulation modes, each defined by the part of the “on”time or off-time set by the PHDLYn[11:0] register (part of theSTRnSET register). The modes are “forward,” “center,” “reverse,” and “inverse”. All four modes use the PHDLYnregister to set the defined edge, and PWMn[11:0] to setthe “on” time as a number of processed GSC pulses.

Thefour different modes and register definitions are illustratedin the figure below, showing the current waveforms. Thedelay for string 0 is held at 0, and the PWM width is thesame for both strings and all the modes. Datanin thefigure refers to both the dimming data and the phase delaydata presented for thenth frame. For “forward” modePHDLYnspecifies the number of processed GSC cyclesafter the processed PHI edge that the string “on” timebegins and the PWMnregister specifies the “on” time.

In this mode the falling edge varies with the “on” timewidth programmed in the PWMnregister, with the risingedge held constant. In “center” mode, the delay is setfrom the processed PHI edge to the center of the PWM onpulse with width set by the PWMnregister. Both the risingand falling edge vary based on the PWMnwith the centerheld constant within a processed GSC cycle. In “reverse”mode, the PHDLYnsets the delay from the next frame’sprocessed PHI edge to the falling edge of the PWM “on”time and the PWMnregister determines the PWM “on”time. Therefore the rising edge varies with PWMnand thefalling edge is held constant. In “inverse” mode, the delayis set from the next frames PHI edge backwards to thefalling edge of the “on” time. The rising edge varies withthe PWMnregister, while the falling edge is held constant.

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