AMS117

1A Adjustable/Fixed Low Dropout Linear Regulator

- Low dropout voltage

- Load regulation: 0.2% typical - Optimized for Low V oltage - On-chip thermal limiting

- Standard SOT-223 and TO-252 packages

- Three-terminal adjustable or fixed low dropout 1.2V ,1.5V ,1.8V , 2.5V , 2.85V , 3.3V , 5V . Regulators

- Active SCSI terminators

- High efficiency linear regulators

- Post regulators for switching supplies - Battery chargers

- 12V to 5V linear regulators - M otherboard clock supplies

The AMS 1117-ADJ and AMS 1117-1.2,-1.5,-1.8,-2.5,-2.85, -3.3 and-5 are low dropout three-terminal regulators with 1A output current capability. These devices have been optimized for low voltage where transient response and minimum input voltage are critical. The 2.85V version is designed specifically to be used in Active Terminators for SCSI bus.

On-chip thermal limiting provides protection against any combination of overload and ambient temperatures that would create excessive junction temperatures.

Unlike PNP type regulators where up to 10% of the output current is wasted as quiescent current, the quiescent cur-rent of the AMS 1117 flows into the load, increasing effi-ciency.

The AMS 1117 series regulators are available in the indus-try-standard SOT-223 and TO-252 power packages.

Key Features

Applications

General Description

Typical Application

Notice: The distance between V out pin and Capacitor should not exceed 4cm for excellent performance

Figure 1. Typical Applications of AMS 1117

1A Adjustable/Fixed Low Dropout Linear Regulator

Pin Assignments

*With package soldered to 0.5 square inch copper area over backside ground plane or internal power plane, ΘJA can vary from 30°C/W to more than 50°C/W. Other mounting techniques may provide better thermal resistance than 30°C/W.

Absolute Maximum Ratings

Figure 2. Pin Assignments of AMS 1117

Parameter

Min.

Max.

Unit

V IN 18 V

(V IN – V OUT ) * I OUT

See Figure 3

Operating Junction Temperature Range -20 125

°C Storage Temperature Range

-65

150

°C Lead Temperature (Soldering, 10 sec.) 300

°C

1A Adjustable/Fixed Low Dropout Linear Regulator

Typicals and limits appearing in normal type apply for T J =25℃.Limits appearing in Boldface type apply over the entire junction temperature for operation, -20℃to 125℃.

Electrical Characteristic

Block Diagram

Thermal Limit

Current Limit

V OUT

V IN

Substrate

GND (fixed output) ADJ. (adjustable output)

Figure 3. Block Diagram of AMS 1117

Symbol

Parameter

Conditions

Min (Note 2) Typ (Note 1) Max

(Note 2)

Units

V REF

Reference Voltage

AMS 1117

1.5V<=(V IN -V OUT )<=7V,10mA<=I OUT <=1A

1.225 1.250 1.275 V

V OUT Output

Voltage 10mA<=

I OUT <=1A

I OUT = 10mA, V IN = 3.2V AMS 1117-1.2 ,2.7V<= V IN <=8.2V 1.176 1.152 1.200 1.200 1.224 1.248 V AMS 1117-1.5 ,3.0V<= V IN <=8.5V

1.470

1.500

1.530

V

AMS 1117-1.8 ,3.3V<= V IN <=

8.8V 1.764 1.800 1.836 V

AMS 1117-2.5 ,4V<= V IN <= 9.5V 2.450 2.500 2.550 V AMS 1117-2.85 , 4.35V <= V IN <= 9.85V 2.793 2.850 2.907 V AMS 1117-3.3 , 4.8V<= V IN <=10.3V 3.234 3.300 3.366 V AMS 1117-5.0,6.5V<=V IN <= 12V

4.900

5.000

5.100

V

1A Adjustable/Fixed Low Dropout Linear Regulator

Typicals and limits appearing in normal type apply for T J =25℃.Limits appearing in Boldface type apply over the entire junction temperature for operation, -20℃ to 125℃.

Electrical Characteristic

(Continued)

Symbol

Parameter Conditions

Min (Note 2)

Typ (Note 1) Max (Note 2) Units △V OUT

Line Regultion (Note 3)

I OUT =10mA ,(V OUT +1.5V)<=V IN <=12V 0.035 0.2 % Load Regultion (Note 3) V IN -V OUT =2V,10mA<= I OUT <=1A,

0.2 0.7 % AMS 1117-1.2

V IN -V OUT =2V,10mA<= I OUT <=1A,

0.2 1 % V IN -V OUT

Dropout Volage I OUT =1A,△V REF =1% 1.100 1.250 V I Limit

Current Limit V IN -V OUT = 2V, T J =25℃

1.1 1.5

A Minimum Load Current (Note 4) AMS 1117-ADJ

1.5V<=(V IN -V OUT )<=10V

10

mA Quiescent Curent

V IN =V OUT +1.25V 5 13 mA Thermal Regulation T A = 25°C, 30ms pulse 0.01 0.1 %/W Ripple

Rejection f=120Hz,V IN -V OUT =3V, V Ripple =1V PP

60 72 dB Adjust Pin Current

50

120

μA

Adjust Pin Current

Change 1.5V<=V IN -V OUT <=7V, 10mA<=I OUT <=1A

0.2 5 μA

Temperature Stability

0.5 % Long Term Stability

T A = 125°C, 1000hrs.

0.3

%

1A Adjustable/Fixed Low Dropout Linear Regulator

Note 1: Typical Values represent the most likely parametric norm. Note 2: All limits are guaranteed by testing or statistical analysis.

Note 3: Load and line regulation are measured at constant junction room temperature. Note 4: The minimum output current required to maintain regulation.

Typical Performance Characteristics

Typicals and limits appearing in normal type apply for T J =25℃.Limits appearing in Boldface type apply over the entire junction temperature for operation, -20℃to 125℃.

Electrical Characteristic

(Continued)

Symbol Parameter

Conditions

Min (Note 2) Typ (Note 1) Max (Note 2)

Units

I Limit

RMS Output Noise(% of

V OUT )

T A = 25°C, 10Hz<= f <=10kHz

0.003 % Thermal Resistance, Junction

to Case

SOT-223 15 ℃/W TO-252 3 ℃/W Thermal Shutdown Junction Temperature

155 ℃ Thermal Shutdown Hysteresis

25

℃

Output Current ( A )

0 0.2 0.4 0.6 0.8 1.0

1.5 1.4 1.3 1.2 1.0 0.9 0.8 0.7 0.6 0.5 0

D r o p o u t V o l t a g e ( V )

Figure 4. Dropout Voltage VS. Output Current

1A Adjustable/Fixed Low Dropout Linear Regulator

Typical Performance Characteristics

(Continued)

Figure 6. Output Voltage VS. Temperature

O u t p u t V o l t a g e ( V )

3.70 3.65 3.60

3.55

3.50 3.45 3.40 3.35 3.30 3.25

3.20

Junction Temperature ( ℃ )

-75 –50 –25 0 25 50 75 100 125 150 175

Figure 5. Reference Voltage VS. Temperature

R e f e r e n c e V o l t a g e ( V )

0.260 1.255 1.250 1.245 1.240 1.235 1.225 1.220 1.215 1.210

Junction Temperature ( ℃ )

-75 –50 –25 0 25 50 75 100 125 150 175

Figure 7. Minimum Load Current VS. Temperature

M i n i m u m L o a d C u r r e n t ( m A )

5 4 3 2 1

Junction Temperature ( ℃ ) -75 –50 –25 0 25 50 75 100 125 150 175

Figure 8. ADJ Pin Current VS. Temperature

A D J P i n C u r r e n t ( μA ) 100 90 80

70

60 50 40 30 20 10 0

Junction Temperature ( ℃ ) -75 –50 –25 0 25 50 75 100 125 150 175

Note:

AMS 1117 Only

AMS1117

1A

Adjustable/Fixed Low Dropout Linear Regulator

Mechanical Dimensions

4-Lead SOT-223 Package

Symbol

Inches Millimeters Notes

Min.

Max.

Min. Max.

A ? .071 ? 1.80 A1 ? .181 ? 4.80

B .025 .033 .064 .840 c ? 0.90 ? 2.29 D .248 .264 6.30 6.71 E .130 .148 3.30 3.71 e .115 .124 2.95 3.15 F .033 .041 .840 1.04 H .264 .287 6.71 7.29 I .0121 ? .310 ? J ? 10° ? 10° K 10° 16° 10° 16° L

.0008 .0040 .0203 .1018 M 10° 16° 10° 16° N

.010

.014

.250

.360

Figure 9. 4-Lead SOT-223 Package

1A Adjustable/Fixed Low Dropout Linear Regulator

Mechanical Dimensions

(Continued)

3-Lead TO-252 Package

Notes:

1. Dimensions are exclusive of mold flash, metal burrs

or interlead protrusion.

2. Stand off-height is measured from lead tip with ref. to

Datum –B-.

3. Foot length is measured with ref. to Datum –A– with

lead surface. 4. Thermal pad contour optional within dimension b3 and L3.

5. Formed leads to be planar with respect to one another

at seating place –C-.

6. Dimensions and tolerances.

Symbol

Inches

Millimeters

Notes

Min. Max.

Min. Max.

A .086 .094 2.19 2.39 b .025 .035 0.64 0.89 b2 .030 .045 0.76 1.14 b3 .205 .215 5.12 5.46 4 c .018 .024 0.46 0.61 c2 .018 .023 0.46 0.58 D .210 .245 5.33 6.22 1

E .250 .265 6.35 6.73 1

e .090 BSC 2.29 BSC

H .370 .410 9.40 10.41 L .055 .070 1.40 1.78 3 L1 .108 REF 2.74 REF

L3 .035 .080 0.89 2.03 4 L4

.025

.040

0.64

1.02

Figure 10. 3-Lead TO-252 Package

1A Adjustable/Fixed Low Dropout Linear R egulator

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The " " logo is a registered trademark of Advanced Monolithic Systems.

All other company and product names are trademarks of their respective owners

Ordering Information

Package Temperature Range Part Number Output Voltage Packing Marking Transport Media

SOT －223

－２０℃ - +125℃ AMS 1117-1.2 1.2V AMS 1117 1.2 2.5K Tape and Reel －２０℃ - +125℃ AMS 1117-1.5 1.5V AMS 1117 1.5 2.5K Tape and Reel -20℃ - +125℃ AMS 1117-1.8 1.8V AMS 1117 1.8 2.5K Tape and Reel

-20℃ - +125℃ AMS 1117-2.5 2.5V AMS 1117 2.5 2.5K Tape and Reel -20℃ - +125℃ AMS 1117-2.85 2.85V AMS 1117 2.8 2.5K Tape and Reel -20℃ - +125℃ AMS 1117-3.3 3.3V AMS 1117 3.3 2.5K Tape and Reel -20℃ - +125℃ AMS 1117-5 5V AMS 1117 5 2.5K Tape and Reel -20℃ - +125℃ AMS 1117 Adjust AMS 1117 2.5K Tape and Reel TO －252

-20℃ - +125℃ AMS 1117-1.2 1.2V AMS 1117 1.2 2.5K Tape and Reel -20℃ - +125℃ AMS 1117-1.5 1.5V AMS 1117 1.5 2.5K Tape and Reel -20℃ - +125℃ AMS 1117-1.8 1.8V AMS 1117 1.8 2.5K Tape and Reel

-20℃ - +125℃ AMS 1117-2.5 2.5V AMS 1117 2.5 2.5K Tape and Reel -20℃ - +125℃ AMS 1117-2.85 2.85V AMS 1117 2.8 2.5K Tape and Reel -20℃ - +125℃ AMS 1117-3.3 3.3V AMS 1117 3.3 2.5K Tape and Reel -20℃ - +125℃ AMS 1117-5 5.0V AMS 1117 5 2.5K Tape and Reel -20℃ - +125℃ AMS 1117CD Adjust AMS 1117CD 2.5K Tape and Reel

Disclaimer:

? AMS reserves the right to make changes to the information herein for the improvement of the design and performance

without further notice! Customers should obtain the latest relevant information before placing orders and should verify that such information is complete and current.

? All semiconductor products malfunction or fail with some probability under special conditions. When using AMS products

in system design or complete machine manufacturing, it is the responsibility of the buyer to comply with the safety standards strictly and take essential measures to avoid situations in which a malfunction or failure of such AMS products could cause loss of body injury or damage to property.

? AMS will supply the best possible product for customers!

晶闸管触发驱动电路设计-张晋远要点

宁波广播电视大学 机械设计制造及其自动化专业 《机电接口技术》 课程设计 题目晶闸管触发驱动电路设计 姓名张晋远学号1533101200119 指导教师李亚峰 学校宁波广播电视大学 日期2017 年 4 月20 摘要 晶闸管是一种开关元件，能在高电压、大电流条件下工作，为了控制晶闸管的导通，必须在控制级至阴极之间加上适当的触发信号（电压及电流），完成此任务的就是触发电路。本课题针对晶闸管的触发电路进行设计，其电路的主要组成部分由触发电路，交流电路，同步电路等电路环节组成。有阻容移相桥触发电路、正弦波同步触发电路、单结晶体触发电路、集成

UAA4002、KJ006触发电路。包括电路的工作原理和电路工作过程以及针对相关参数的计算。 关键词：晶闸管；触发电路；脉冲；KJ006； abstract Thyristor is a kind of switch components, can work under high voltage, high current conditions, in order to control thyristor conduction, must be between control level to the cathode with appropriate trigger signal (voltage and current), complete the task is to trigger circuit. This topic in view of the thyristor trigger circuit design, the main part of the circuit by the trigger circuit, communication circuit, synchronous circuit and other circuit link. There is a blocking phase bridge trigger circuit, the sine wave synchronous trigger circuit, the single crystal trigger circuit, the integrated UAA4002, the KJ006 trigger circuit. This includes the working principle of the circuit and the circuit working procedure and the calculation of the relevant parameters. Keywords: thyristor; Trigger circuit; Pulse; KJ006; 目录 第一章绪论 1.1设计背景与意义…………………………………… 1.2 晶闸管的现实应用……………………………………

可控硅-晶闸管的几种典型应用电路

可控硅-晶闸管的几种典型应用电路 描述： ＳＣＲ半波整流稳压电源。如图４电路，是一种输出电压为＋１２Ｖ的稳压电源。该电路的特点是变压器Ｂ将２２０Ｖ的电压变换为低压（１６～２０Ｖ），采用单向可控硅ＳＣＲ半波整流。ＳＣＲ的门极Ｇ从Ｒ１、Ｄ１和Ｄ２的回路中的Ｃ点取出约１３．４Ｖ的电压作为ＳＣＲ门阴间的偏置电压。电容器Ｃ１起滤波和储能作用。在输出ＣＤ端可获得约＋１２Ｖ的稳压。晶闸管，又称可控硅（单向ＳＣＲ、双向ＢＣＲ）是一种４层的（ＰＮＰＮ）三端器件。在电子技术和工业控制中，被派作整流和电子开关等用场。在这里，笔者介绍它们的基本特性和几种典型应用电路。 １．锁存器电路。图１是一种由继电器Ｊ、电源（＋１２Ｖ）、开关Ｋ１和微动开关Ｋ２组成的锁存器电路。当电源开关Ｋ１闭合时，因Ｊ回路中的开关Ｋ２和其触点Ｊ－１是断开的，继电器Ｊ不工作，其触点Ｊ－２也未闭合，所以电珠Ｌ不亮。一旦人工触动一下Ｋ２，Ｊ得电激活，对应的触点Ｊ－１、Ｊ－２闭合，Ｌ点亮。此时微动开关Ｋ２不再起作用（已自锁）。要使电珠Ｌ熄灭，只有断开电源开关Ｋ１使继电器释放，电珠Ｌ才会熄灭。所以该电路具有锁存器（Ｊ－１自锁）的功能。 图２电路是用单向可控硅ＳＣＲ代替图１中的继电器Ｊ，仍可完成图１的锁存器功能，即开关Ｋ１闭合时，电路不工作，电珠Ｌ不亮。当触动一下微动开关Ｋ２时，ＳＣＲ因电源电压通过Ｒ１对门极加电而被触发导通且自锁，Ｌ点亮，此时Ｋ２不再起作用，要使Ｌ熄灭，只有断开Ｋ１。由此可见，图２电路也具有锁存器的功能。图２与图１虽然都具有锁存器功能，但它们的工作条件仍有区别：（１）图１的锁存功能是利用继电器触点的闭合维持其Ｊ线圈和Ｌ的电流，但图２中，是利用ＳＣＲ自身导通完成锁存功能。（２）图１的Ｊ与控制器件Ｌ完全处于隔离状态，但图２中的ＳＣＲ与Ｌ不能隔离。所以在实际应用电路中，常把图１和图２电路混合使用，完成所需的锁存器功能。 ２．单向可控硅ＳＣＲ振荡器。图３电路是利用ＳＣＲ的锁存性制作的低频振荡器电路。图中的扬声器ＬＳ（８Ω／０．５Ｗ）作为振荡器的负载。当电路接上电源时，由于电源通过Ｒ１对Ｃ１充电，初始时，Ｃ１电压很低，Ａ、Ｂ端的电位器Ｗ的分压不能触发ＳＣＲ，ＳＣＲ不导通。当Ｃ１充得电压达到一定值时，Ａ、Ｂ端电压升高，ＳＣＲ被触发而导通。一旦ＳＣＲ导通，电容器Ｃ１通过ＳＣＲ和ＬＳ放电，结果Ａ、Ｂ端的电压又下降，当Ａ、Ｂ端电压下降到很低时，又使ＳＣＲ截止，一旦ＳＣＲ截止，电容器Ｃ１又通过Ｒ１充电，这种充放电过程反复进行形成电路的振荡，此时ＬＳ发出响声。电路中的Ｗ可用来调节ＳＣＲ门极电压的大小，以达到控制振荡器的频率变化。按图中元件数据，Ｃ１取值为０．２２～４μＦ，电路均可正常工作。 ３．ＳＣＲ半波整流稳压电源。如图４电路，是一种输出电压为＋１２Ｖ的稳压电源。该电路的特点是变压器Ｂ将２２０Ｖ的电压变换为低压（１６～２０Ｖ），采用单向可控硅ＳＣＲ半波整流。ＳＣＲ的门极Ｇ从Ｒ１、Ｄ１和Ｄ２的回路中的Ｃ点取出约１３．４Ｖ的电压作为ＳＣＲ门阴间的偏置电压。电容器Ｃ１起滤波和储能作用。在输出ＣＤ端可获得约＋１２Ｖ的稳压。电路工作时，当Ａ点低压交流为正半周时，ＳＣＲ导通对Ｃ１充电。当充电电压接近Ｃ点电压或交流输入负半周时，ＳＣＲ截止，所以Ｃ１上充得电压（即输出端ＣＤ）不会高于Ｃ点的稳压值。只有储能电容Ｃ１输出端对负载放电，其电压低于Ｃ点电压时，在Ａ点的正半周电压才会给Ｃ１即时补充充电，以维持输出电压的稳定。图４电路与电池配合已成功用于某设备作后备电源。该稳压电源，按图中参数其输出电流可达２～３Ａ。

晶闸管保护电路

晶闸管保护电路 晶闸管的保护电路，大致可以分为两种情况：一种是在适当的地方安装保护器件，例如，R-C阻容吸收回路、限流电感、快速熔断器、压敏电阻或硒堆等。再一种则是采用电子保护电路，检测设备的输出电压或输入电流，当输出电压或输入电流超过允许值时，借助整流触发控制系统使整流桥短时内工作于有源逆变工作状态，从而抑制过电压或过电流的数值。 一.晶闸管的过流保护 晶闸管设备产生过电流的原因可以分为两类:一类是由于整流电路内部原因, 如整流晶闸管损坏, 触发电路或控制系统有故障等; 其中整流桥晶闸管损坏类较为严重, 一般是由于晶闸管因过电压而击穿,造成无正、反向阻断能力，它相当于整流桥臂发生永久性短路，使在另外两桥臂晶闸管导通时，无法正常换流，因而产生线间短路引起过电流.另一类则是整流桥负载外电路发生短路而引起的过电流，这类情况时有发生，因为整流桥的负载实质是逆变桥, 逆变电路换流失败，就相当于整流桥负载短路。另外，如整流变压器中心点接地，当逆变负载回路接触大地时，也会发生整流桥相对地短路。 1.对于第一类过流，即整流桥内部原因引起的过流，以及逆变器负载回路接地时，可以采用第一种保护措施，最常见的就是接入快速熔短器的方式。见图1。快速熔短器的接入方式共有三种，其特点和快速熔短器的额定电流见表1。

方式特点额定电流IRN 备注 A型熔短器与每一个元件串联，能可靠地保护每一个元件IRN<1.57IT IT：晶闸管通态平均电流 B型能在交流、直流和元件短路时起保护作用，可靠性稍有降低 IRN

可控硅应用电路举例

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