7805中文资料

7805三端稳压器参数定义1.简介7805三端稳压器是一种常见的线性稳压器，用于将高电压转换成稳定的5V直流电压。

本文将介绍7805三端稳压器的参数定义及其作用。

2.参数定义2.1输入电压（V I N）输入电压指7805稳压器的电源供应电压。

输入电压的范围通常为7V至35V。

如果输入电压低于7V，稳压器将无法正常工作。

2.2输出电压（V O UT）输出电压是7805稳压器通过调整电压差来实现的。

对于7805来说，输出电压被设定为5V，可保持稳定不变。

输出电流的范围为0A至 1.5A。

2.3输出电流（I O UT）输出电流是指从稳压器输出引脚流出的电流。

稳压器必须能够提供所需的输出电流，以满足连接负载的要求。

在使用7805稳压器时，输出电流不应超过1.5A。

2.4输入输出电压差（V D O）输入-输出电压差是指稳压器在工作状态下的电压降。

对于7805来说，输入-输出电压差通常为2V至2.5V。

较大的输入-输出电压差将导致稳压器产生更多的热量。

2.5静态电压调整率（S.V.R）静态电压调整率是指在特定负载条件下，稳压器输出电压随输入电压变化的程度。

对于7805来说，静态电压调整率通常为0.1%至0.5%。

更小的调整率表示稳压器输出电压更稳定，对变动输入电压更不敏感。

2.6温度系数（T C）温度系数是指稳压器输出电压随温度变化的程度。

对于7805来说，温度系数通常为100p p m/℃至200p pm/℃。

更小的温度系数表示稳压器的输出电压对温度变化更不敏感。

3.作用与应用7805三端稳压器在电子电路中具有重要作用。

它能够将高电压转换成稳定的5V直流电压，常被应用在各种电子设备中，如移动电源、嵌入式系统等。

通过控制输入-输出电压差，7805稳压器能够提供稳定的输出电压，保证其他电路元件正常工作。

其输出电流能力较强，能够满足大部分的负载需求。

此外，7805稳压器的静态电压调整率较小，能够在输入电压变化时保持较为稳定的输出电压。

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3.BOARD OPERATION3.1ACF–II Operating ModeAFC–II has four operating modes. Any one of these modes can be selected using the digital code input to MODE 0 and MODE 1 using ROTARY SW. The function of each mode is as follows.(1)Normal fsc ModeThis is the mode for usual Y/C separation. It separates Y/C from the video signal that is input to the A/D converter.The coring parameter of the vertical enhancer can be set up by the digital code that is input to C0 – C3 (block level parameter), C4 – C7 (white level parameter), and D4 – D7 (noise slice level parameter). The clock is a 3.579545 MHz subcarrier input to the CLK connector; the built–in 4x PLL generates 4xfsc clock.(2)Normal 4xfsc ModeThis mode is used for Y/C separation. It separates Y/C from the video signal that is input to the A/D con-verter.The coring parameter of the vertical enhancer can be set up by the digital code that is input to C0 – C3 (block level parameter), C4 – C7 (white level parameter), and D4 – D7 (noise slice level parameter). The clock is 14.31818 MHz which is a 4x subcarrier input to the CLK connector.(3)Digital Input Comb Filter ModeThis mode uses the A/D converter, filter, and D/A converter as two independent blocks. The digital data converted by the A/D converter is output on C0 – C7. Data input on D0 – D7 is processed by the ACF–II. Filtering is performed by the algorithm of ACF–II and the Y/C video is output as analog signals from Y out and C out. These two blocks can operate with input clock signals that have different frequencies or phases and can be operated independently by using the CLK(AD) for the A/D converter, and the CLK input for the D/A converter.The clock is 14.31818 MHz which is a 4x subcarrier input to the CLK connector and the CLK(AD) con-nector.(4)Digital Output Comb Filter ModeIn addition to the normal Y/C analog outputs, the MC141622EVK can provide the Y/C signals as digital luminance and chrominance signals. The digital luminance data is output on C0 – C7 and the digital chrominance data is output on D0 – D7. This digital data can be modified by other digital processing. MC141622EVK MOTOROLA 24.2Clock Generator CompoundingThe clock generator (MC1378P) provides the necessary reference oscillator and phase locks the clock to the color subcarrier by inputting the composite video signal.VC1 adjusts the horizontal VCO to synchronize the output of the burst gate (pin 5 on the MC1378P) with the input video signal. VC2 adjusts the chroma VCO for maximum amplitude output from the clock buffer (pin 1 on the MC14576).VR3 adjusts pull–in of the chroma PLL filter. This is usually fixed to the center position. VR4 selects the dc bias for the clock buffer output and is usually 2.25 V.4.3Video Amplifier AdjustmentOn the video amplifier (MC14577), the gain is adjusted by VR1. This sets the input range (3.0 Vp–p) of the A/D converter in MC141622FU.VR2 is the clamp level adjustment. This adjusts the sync tip clamping of the input video signal to the video amplifier.4.4Outside InterfaceThe outside interface should provide a composite video input signal to BNC1. The MC141622EVK pro-vides Y/C separation and outputs the luminance from BNC2 and the color signal from BNC3. There is an S output connector on this board for easy connection to instruments having an S input connector.BNC4 and BNC5 are for the external input of each CLK and CLK(AD). However, when using these, it is necessary to modify the board pattern; i.e., cut (J5, J6).There is no filter for bandwidth limitations on this board beyond that imposed by the bandwidth limitations of the MC14577 buffer amplifier. To minimize noise resulting from excessive bandwidth, the bandwidth of input video signal should be limited to no more than one half of the clock frequency.MC141622EVK MOTOROLA 4MC141622EVK MOTOROLA66.MC141622EVK PARTS LISTReference Designation Description IC1MC141622FU IC2MC14576CP IC3MC14577CP IC4MC7805CT IC5MC14576CP IC6MC1378P TR12SC2002TR22SC2002TR32SA953R19.1 k ΩR262 k ΩR3, R475 ΩR5 3.6 k ΩR6750 k ΩR7, R8 2.0 k ΩR9510 ΩR10150 ΩR11510 k ΩR12, R13 2.2 k ΩR1447 k Ω x 4R1547 k Ω x 8R1610 k Ω x 8R1747 k Ω x 8R1810 k Ω x 8R19, R2010 k Ω x 4R21200 ΩR22 1.8 k ΩR23680 ΩR24750 k ΩR25 2.2 k ΩR267.5 m ΩR27 1.0 m ΩR28150 ΩR29470 k ΩL1 – L933 µH L10 4.7 µH L1133 µH VR1 1 k ΩVR2 2.2 k ΩVR3 1 k ΩVR4 1 m ΩVC1, VC230 pF SW1, SW2Toggle Switch DIP SW1, DIP SW28 Channel Dip Switch ROTARY SW16 Channel Switch 4 MHz Cer. Res 14.32 MHz CrystalReference Designation Description C10.1 µF C2, C347 µF C4, C5, C60.1 µF C747 µF C80.1 µF C910 µF C100.1 µF C1110 µF C120.33 µF C131.0 µF C14, C150.1 µF C1647 µF C170.1 µF C18 1.0 µF C1947 µF C20, C210.1 µF C2247 µF C230.1 µF C2447 µF C250.1 µF C2647 µF C2710 µF C280.1 µF C29, C3047 µF C310.1 µF C320.022 µF C33, C34 1.0 µF C350.1 µF C360.001 µF C3747 µF C38 – C450.1 µF C461.0 µF C47, C480.1 µF C49 – C51 1.0 µF C520.1 µF C5347 µF C540.047 µF C55 – C570.1 µF。