ADP150：超低噪声、150mA CMOS线性调节器 中文数据手册

ＰＡ１５０－Ｄ微机综合保护测控装置　１　基本功能　１．１　基本保护配置　1）差动速断；2）比率差动保护（CT断线告警并闭锁差动保护和可选二次谐波闭锁）；3）磁平衡差动；４）非电量保护；　５）断路器控制回路断线监测；６）装置故障告警。

１．２　主要测控功能　１）　１６路开入信号量的采集（其中１２路开入量为有源接点，需外接电源；另外四路开入量ＭＣ１－ＭＣ４为装置内部１２Ｖ供电，请勿接入外接电源），除部分有特殊定义外，其余开入量可由用户定义。

　２）　机端电流（IA、IB、IC）、机端零序电流（I0H）、机端平衡电流（IAP、IBP、ICP）、中性点侧电流（Ia、Ib、Ic）、中性点零序电流（I0L）、差动电流（Icd1、Icd2、Icd3）、制动电流（Izd1、Izd2、Izd3）、谐波电流（Ixb1、Ixb2、Ixb3）等模拟量的测量显示功能；　３）　４路信号量的输出、１路装置失电故障信号输出。

　４）　事件顺序记录功能。

　５）故障录波功能。

　６）两路跳闸出口。

　１．３　通讯功能　采用ＲＳ４８５／ＲＳ４２２通讯接口，各功能单元可与主控计算机（或通信管理机）进行通讯，从而实现信息的远方传送和交换。

通过主控计算机（或通信管理机）还可实现对保护装置定值的远方查询、整定功能。

　２ 技术数据　２．１　电源　类型　电压　波形　频率　功耗　纹波　波形失真　直流　100V~250V 直流　———　＜２０Ｗ　＜５％　———　交流　85V~265V 交流　５０±５Ｈｚ　＜２０Ｗ　———　＜５％　２．２　实时性　内容　开关动作分辨率　数据采集　通讯　画面刷新　调画面时间　接口报警时间　上位机到下位机命令　参数　＜２ｍｓ　模拟量　≤１ｓ　波特率　１２００～９０００　（默认４８００）　≤１ｓ　≤１ｓ　≤１ｓ　≤１ｓ　２．３保护性能参数　内容　参数　内容　参数　差动速断动作值误差　＜±３％　差动保护动作值误差　＜±３％　磁平衡差动动作值误差　＜±３％　２．４定值整定（在“３．３　定值显示整定”子菜单中整定）　序号　名称　单位　符号　整定值范围　分辨率　00 差动速断电流 A Icdsd （0.2～10）×In ０．００１　01 差动启动电流 A Icdqd （0.2～10）×In ０．００１　02 最小制动电流 A Ilzd （0.2～10）×In ０．００１　03 基波制动斜率 / Kjzd 20%～80% ０．００１　04 平衡系数 / Kph 0～3 ０．００１　05 ＣＴ断线定值 A Ict 1～12A ０．００１　06 谐波制动系数 / Kxzd 10%～30% ０．００１　07 磁平衡差动定值 A Icphcd （0.2～10）×In０．００１　08 非电量告警时间 ｓ　ＴＩＮ１　０．１～１００ｓ　０．０１　09非电量跳闸时间ｓ　ＴＩＮ２　０．１～１００ｓ　０．０１　３ 主要保护功能原理　３．１　差动速断及二次谐波、CT 断线闭锁差动保护： 1）保护原理及动作条件：电动机在自启动过程中，机端和中性点两侧将有很大的不平衡差流，这种不平衡电流中有十分显著的二次谐波成分，而且二次谐波电流与基波电流之比并不随暂态不平衡电流的衰减而减小。

ADP151AUJZ-1.2-R7ADP151ACBZ-3.3-R7 .ADP151ACPZ-3.3-R7 .ADP151AUJZ-1.8-R7 .ADP151AUJZ-2.5-R7 .Ultralow Noise, 200 mA,CMOS Linear Regulator Enhanced Product ADP151-EPRev. 0Information furnished by Analog Devices is believed to be accurate and reliable. However, noresponsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. T rademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 Fax: 781.461.3113 ©2012 Analog Devices, Inc. All rights reserved.FEATURESUltralow noise: 9 µV rmsInput voltage range: 2.2 V to 5.5 VLow quiescent currentIGND= 10 µA with 0 loadIGND= 265 μA with 200 mA loadLow shutdown current: <1 µALow dropout voltage: 150 mV at 200 mA loadAccuracy over line, load, and temperature: −2.5%/+3% PSRR performance of 70 dB at 10 kHzCurrent-limit and thermal overload protectionInternal pull-down resistor on EN input5-lead TSOT packageEnhanced processing (EP) for −55°C to +125°C operation APPLICATIONSRF, VCO, and PLL power suppliesPortable and battery-powered equipmentPost dc-to-dc regulationPortable medical devicesAeronautic and military operating temperature environmentTYPICAL APPLICATION CIRCUITNC = NO CONNECT. DO NOT CONNECT TO THIS PIN.10681-1 Figure 1. TSOT ADP151-EP with Fixed Output Voltage, 3.3 VGENERAL DESCRIPTIONThe ADP151-EP is an ultralow noise, low dropout linear regulator that operates from 2.2 V to 5.5 V and provides up to 200 mA of output current. The low 150 mV dropout voltage at 200 mA load improves efficiency and allows operation over a wide input voltage range.Using an innovative circuit topology, the ADP151-EP achieves ultralow noise performance without the necessity of a bypass capacitor, making it ideal for noise-sensitive analog and RF applications. The ADP151-EP also achieves ultralow noise performance without compromising PSRR or transient line and load performance. The low 265 μA of quiescent current at 200 mA load makes the ADP151-EP suitable for battery-operated portable equipment.The ADP151-EP also includes an internal pull-down resistor on the EN input. The ADP151-EP is specifically designed for stable operation with tiny 1 µF, ±30% ceramic input and output capacitors to meet the requirements of high performance, space constrained applications.The ADP151-EP is capable of 16 fixed output voltage options, ranging from 1.1 V to 3.3 V.Short-circuit and thermal overload protection circuits prevent damage in adverse conditions. The ADP151-EP is available in a tiny 5-lead TSOT package.Additional application and technical information can be found in the ADP151 data sheet.ADP151-EPEnhanced ProductRev. 0 | Page 2 of 16TABLE OF CONTENTSFeatures .............................................................................................. 1 Applications ....................................................................................... 1 Typical Application Circuit ............................................................. 1 General Description ......................................................................... 1 Revision History ............................................................................... 2 Specifications ..................................................................................... 3 Input and Output Capacitor, Recommended Specifications .. 4 Absolute Maximum Ratings ............................................................ 5 Thermal Data .. (5)Thermal Resistance .......................................................................5 ESD Caution...................................................................................5 Pin Configurations and Function Descriptions ............................6 Typical Performance Characteristics ..............................................7 Applications Information .............................................................. 11 Thermal Considerations ............................................................ 11 Printed Circuit Board Layout Considerations ............................ 13 Outline Dimensions ....................................................................... 14 Ordering Guide .. (14)REVISION HISTORY7/12—Revision 0: Initial VersionEnhanced ProductADP151-EPRev. 0 | Page 3 of 16SPECIFICATIONSV IN = (V OUT + 0.4 V) or 2.2 V , whichever is greater; EN = V IN , I OUT = 10 mA, C IN = C OUT = 1 µF, T A = 25°C, unless otherwise noted. Table 1.ParameterSymbol ConditionsMin Typ Max Unit INPUT VOLTAGE RANGEV IN T J = −55°C to +125°C 2.2 5.5 V OPERATING SUPPLY CURRENT I GND I OUT = 0 µA10 µA I OUT = 0 µA, T J = −55°C to +125°C 20 µA I OUT = 100 µA20 µA I OUT = 100 µA, T J = −55°C to +125°C 40 µA I OUT = 10 mA60 µA I OUT = 10 mA, T J = −55°C to +125°C 90 µA I OUT = 200 mA265 μAI OUT = 200 mA, T J = −55°C to +125°C 350 μA SHUTDOWN CURRENT I GND-SD EN = GND0.2 µAEN = GND, T J = −55°C to +125°C 1.0 µA OUTPUT VOLTAGE ACCURACYV OUT I OUT = 10 mA−1 +1 % V OUT T J = −55°C to +125°C V OUT < 1.8 V100 µA < I OUT < 200 mA, V IN = (V OUT + 0.4 V) to 5.5 V −3 +3 % V OUT ≥ 1.8 V100 µA < I OUT < 200 mA, V IN = (V OUT + 0.4 V) to 5.5 V −2.5 +3 % REGULATIONLine Regulation ∆V OUT /∆V IN V IN = (V OUT + 0.4 V) to 5.5 V, T J = −55°C to +125°C −0.05 +0.05 %/V Load Regulation 1 ∆V OUT /∆I OUT V OUT < 1.8 V%/mA I OUT = 100 µA to 200 mA0.006%/mA I OUT = 100 µA to 200 mA, T J = −55°C to +125°C 0.012 %/mA V OUT ≥ 1.8 VI OUT = 100 µA to 200 mA0.003%/mAI OUT = 100 µA to 200 mA, T J = −55°C to +125°C 0.008 %/mA DROPOUT VOLTAGE 2 V DROPOUT I OUT = 10 mA10 mV I OUT = 10 mA, T J = −55°C to +125°C 30 mV I OUT = 200 mA150 mVI OUT = 200 mA, T J = −55°C to +125°C 230 mV START-UP TIME 3t START-UP VOUT = 3.3 V180 µs CURRENT-LIMIT THRESHOLD 4 I LIMIT T J = 0°C to +125°C 220 300 400 mA UNDERVOLTAGE LOCKOUTT J = −55°C to +125°C Input Voltage Rising UVLO RISE 1.96 V Input Voltage Falling UVLO FALL 1.28 V HysteresisUVLO HYS 120 mV THERMAL SHUTDOWNThermal Shutdown Threshold TS SD T J rising 150 °C Thermal Shutdown Hysteresis TS SD-HYS15 °C EN INPUTEN Input Logic High V IH 2.2 V ≤ V IN ≤ 5.5 V 1.2 V EN Input Logic LowV IL 2.2 V ≤ V IN ≤ 5.5 V 0.4 V EN Input Pull-Down Resistance R ENV IN = V EN = 5.5 V2.6 MΩ OUTPUT NOISE OUT NOISE 10 Hz to 100 kHz, V IN = 5 V, V OUT =3.3 V 9 µV rms 10 Hz to 100 kHz, V IN = 5 V, V OUT = 2.5 V 9 µV rms10 Hz to 100 kHz, V IN = 5 V, V OUT = 1.1 V9µV rmsADP151-EPEnhanced ProductRev. 0 | Page 4 of 16ParameterSymbol Conditions Min Typ Max Unit POWER SUPPLY REJECTION RATIO PSRRV IN = V OUT + 0.5 V 10 kHz, V IN = 3.8 V, V OUT = 3.3 V, I OUT = 10 mA 70 dB100 kHz, V IN = 3.8 V, V OUT = 3.3 V, I OUT = 10 mA 55 dB V IN = V OUT + 1 V 10 kHz, V IN = 4.3 V, V OUT = 3.3 V, I OUT = 10 mA 70 dB 100 kHz, V IN = 4.3 V, V OUT = 3.3 V, I OUT = 10 mA 55 dB 10 kHz, V IN = 2.2 V, V OUT = 1.1 V, I OUT = 10 mA 70 dB100 kHz, V IN = 2.2 V, V OUT = 1.1 V, I OUT = 10 mA55dB1 Based on an end-point calculation using 0.1 mA and 200 mA loads. See Figure 4 for typical load regulation performance for loads less than 1 mA.2Dropout voltage is defined as the input-to-output voltage differential when the input voltage is set to the nominal output voltage. This applies only for output voltages above 2.2 V. 3Start-up time is defined as the time between the rising edge of EN and V OUT being at 90% of its nominal value. 4Current-limit threshold is defined as the current at which the output voltage drops to 90% of the specified typical value. For example, the current limit for a 3.0 V output voltage is defined as the current that causes the output voltage to drop to 90% of 3.0 V (that is, 2.7 V).INPUT AND OUTPUT CAPACITOR, RECOMMENDED SPECIFICATIONSTable 2.ParameterSymbol ConditionsMin Typ Max Unit Minimum Input and Output Capacitance 1 C MIN T A = −55°C to +125°C 0.7 µF Capacitor ESRR ESR T A = −55°C to +125°C0.001 0.2 Ω1The minimum input and output capacitance should be greater than 0.7 μF over the full range of operating conditions. The full range of operating conditions in the application must be considered during device selection to ensure that the minimum capacitance specification is met. X7R and X5R type capacitors are recommended; Y5V and Z5U capacitors are not recommended for use with any LDO.Enhanced ProductADP151-EPRev. 0 | Page 5 of 16ABSOLUTE MAXIMUM RATINGSTable 3.Parameter RatingVIN to GND −0.3 V to +6.5 V VOUT to GND −0.3 V to VIN EN to GND−0.3 V to +6.5 V Storage Temperature Range−65°C to +150°C Operating Junction Temperature Range −55°C to +125°C Operating Ambient Temperature Range −55°C to +125°C Soldering ConditionsJEDEC J-STD-020Stresses above those listed under absolute maximum ratings may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.THERMAL DATAAbsolute maximum ratings apply individually only, not in combination. The ADP151-EP can be damaged when the junction temperature limits are exceeded. Monitoring ambient temperature does not guarantee that T J is within the specified temperature limits. In applications with high power dissipation and poor thermal resistance, the maximum ambient temperature may have to be derated.In applications with moderate power dissipation and low PCB thermal resistance, the maximum ambient temperature can exceed the maximum limit as long as the junction temperature is within specification limits. The junction temperature (T J ) of the device is dependent on the ambient temperature (T A ), the power dissipation of the device (P D ), and the junction-to-ambient thermal resistance of the package (θJA ).The maximum junction temperature (T J ) is calculated from the ambient temperature (T A ) and power dissipation (P D ) using the formulaT J = T A + (P D × θJA )The junction-to-ambient thermal resistance (θJA ) of the package is based on modeling and calculation using a 4-layer board. The junction-to-ambient thermal resistance is highly dependent on the application and board layout. In applications where high maximum power dissipation exists, close attention to thermal board design is required. The value of θJA may vary, depending on PCB material, layout, and environmental conditions. The specified values of θJA are based on a 4-layer, 4 in. × 3 in. circuit board. See JESD51-7 for detailed information on the board construction.ΨJB is the junction-to-board thermal characterization parameter with units of °C/W . ΨJB of the package is based on modeling and calculation using a 4-layer board. The JESD51-12, Guidelines for Reporting and Using Electronic Package Thermal Information , states that thermal characterization parameters are not the same as thermal resistances. ΨJB measures the component power flowing through multiple thermal paths rather than a single path as in thermal resistance, θJB . Therefore, ΨJB thermal paths include convection from the top of the package as well as radiation from the package, factors that make ΨJB more useful in real-world applications. Maximum junction temperature (T J ) is calculated from the board temperature (T B ) and power dissipation (P D ) using the formulaT J = T B + (P D × ΨJB )See JESD51-8 and JESD51-12 for more detailed information about ΨJB .THERMAL RESISTANCEθJA and ΨJB are specified for the worst-case conditions, that is, a device soldered in a circuit board for surface-mount packages. Table 4. Thermal ResistancePackage Type θJA ΨJB Unit 5-Lead TSOT 17443°C/WESD CAUTIONADP151-EPEnhanced ProductRev. 0 | Page 6 of 16PIN CONFIGURATIONS AND FUNCTION DESCRIPTIONSTOP VIEW (Not to Scale)ADP151-EPVIN GND EN VOUTNC12345NC = NO CONNECT. DO NOT CONNECT TO THIS PIN.10681-002Figure 2. 5-Lead TSOT Pin ConfigurationTable 5. Pin Function DescriptionsPin Number Mnemonic Description1 VIN Regulator Input Supply. Bypass VIN to GND with a 1 µF or greater capacitor.2 GND Ground.3 EN Enable Input. Drive EN high to turn on the regulator; drive EN low to turn off the regulator. For automatic startup, connect EN to VIN.4 NC No Connect. Not connected internally.5VOUTRegulated Output Voltage. Bypass VOUT to GND with a 1 µF or greater capacitor.Enhanced ProductADP151-EPRev. 0 | Page 7 of 16TYPICAL PERFORMANCE CHARACTERISTICSV IN = 5 V , V OUT = 3.3 V , I OUT = 1 mA, C IN = C OUT = 1 µF, T A = 25°C, unless otherwise noted.3.353.253.273.293.313.33–40–60–20200406080120100V O U T (V )JUNCTION TEMPERATURE (°C)10681-003Figure 3. Output Voltage vs. Junction Temperature 3.253.273.293.313.333.350.010.11101001000V O U T (V )I LOAD (mA)10681-004Figure 4. Output Voltage vs. Load Current3.253.273.293.313.333.353.63.84.0 4.2 4.4 4.6 4.85.0 5.2 5.4V O U T (V )V IN (V)10681-005Figure 5. Output Voltage vs. Input Voltage I G ND (µA )JUNCTION TEMPERATURE (°C)100010010110681-006Figure 6. Ground Current vs. Junction Temperature1010010000.010.11101001000I G N D (µA )I LOAD (mA)10681-007Figure 7. Ground Current vs. Load Current101001000I G N D (µA )V IN (V)10681-008Figure 8. Ground Current vs. Input VoltageADP151-EPEnhanced ProductRev. 0 | Page 8 of 1600.050.100.150.200.250.300.350.400.45S H U T D O W N C U R R E N T (µA )TEMPERATURE (°C)10681-009Figure 9. Shutdown Current vs. Temperature at Various Input Voltages204060801001201101001000D R O P O U T V O L T A GE (m V )I LOAD (mA)10681-01Figure 10. Dropout Voltage vs. Load Current3.003.053.103.153.203.253.303.353.13.2 3.33.4 3.5 3.6V O U T (V )V IN (V)10681-011Figure 11. Output Voltage vs. Input Voltage (in Dropout)0100200300400500600700800I G N D (µA )V IN (V)10681-012Figure 12. Ground Current vs. Input Voltage (in Dropout)0–10–20–30–40–50–60–70–80–90–100101001k 10k 100k 1M 10MFREQUENCY (Hz)10681-013P S R R (d B )Figure 13. Power Supply Rejection Ratio vs. Frequency, V OUT = 1.2 V, V IN= 2.2 V0–10–20–30–40–50–60–70–80–90–100101001k 10k 100k 1M 10MP S R R (d B )FREQUENCY (Hz)10681-014Figure 14. Power Supply Rejection Ratio vs. Frequency, V OUT = 2.8 V, V IN = 3.3 VEnhanced ProductADP151-EPRev. 0 | Page 9 of 160–10–20–30–40–50–60–70–80–90–100101001k10k100k1M10MP S R R (d B )FREQUENCY (Hz)10681-015Figure 15. Power Supply Rejection Ratio vs. Frequency, V OUT = 3.3 V, V IN = 3.8 V0–10–20–30–40–50–60–70–80–90–100101001k10k100k1M10MP S R R (d B )FREQUENCY (Hz)10681-016Figure 16. Power Supply Rejection Ratio vs. Frequency at Various Output Voltages and Load Currents, V OUT − V IN = 0.5 V, except for V OUT = 1.1 V, V IN = 2.2 V 0–10–20–30–40–50–60–70–80–90–100101001k 10k 100k 1M 10MP S R R(d B )FREQUENCY (Hz)10681-017Figure 17. Power Supply Rejection Ratio vs. Frequency at Various Voltagesand Load Currents, V OUT = 2.8 V140123456789101112130.0010.010.11101001kNO I S E (µV r m s )LOAD CURRENT (mA)10681-018Figure 18. Output Noise vs. Load Current and Output Voltage,V IN = 5 V, C OUT = 1 μF10001010010100k10k 1k100N O I S E S P EC T R A LDE N S I T Y (n /H z )FREQUENCY (Hz)10681-019Figure 19. Output Noise Spectral Density vs. Frequency,V IN = 5 V, I LOAD = 10 mA, C OUT = 1 μFCH1 200mA CH2 50mVM20µs A CH1 64.0mAT 10.00%10681-020Figure 20. Load Transient Response, C IN , C OUT = 1 μF, I LOAD = 1 mA to 200 mAADP151-EPEnhanced ProductRev. 0 | Page 10 of 16CH1 1V CH2 2mVM10µs A CH1 4.56V T 10.80%10681-021Figure 21. Line Transient Response, C IN , C OUT = 1 μF, I LOAD = 200 mACH1 1V CH2 2mVM10µs A CH1 4.56VT 10.80%10681-022Figure 22. Line Transient Response, C IN , C OUT = 1 μF, I LOAD = 1 mAEnhanced ProductADP151-EPRev. 0 | Page 11 of 16APPLICATIONS INFORMATIONTHERMAL CONSIDERATIONSIn most applications, the ADP151-EP does not dissipate much heat due to its high efficiency. However, in applications with a high ambient temperature and a high supply voltage to output voltage differential, the heat dissipated in the package can cause the junction temperature of the die to exceed the maximum junction temperature of 125°C.When the junction temperature exceeds 150°C, the converter enters thermal shutdown. It recovers only after the junction temperature has decreased below 135°C to prevent any permanent damage. Therefore, thermal analysis for the chosen application is very important to guarantee reliable performance over all conditions. The junction temperature of the die is the sum of the ambient temperature of the environment and the tempera-ture rise of the package due to the power dissipation, as shown in Equation 1.To guarantee reliable operation, the junction temperature of the ADP151-EP must not exceed 125°C. To ensure that the junction temperature stays below this maximum value, the user must be aware of the parameters that contribute to junction temperature changes. These parameters include ambienttemperature, power dissipation in the power device, and thermal resistances between the junction and ambient air (θJA ). The θJA number is dependent on the package assembly compounds that are used and the amount of copper used to solder the package GND pins to the PCB.Table 6 shows typical θJA values of the 5-lead TSOT for various PCB copper sizes. Table 7 shows the typical ΨJB values of the 5-lead TSOT.Table 6. Typical θJA ValuesCopper Size (mm 2) θJA (°C/W) 01 174 50 156 100 150 300 138 5001351Device soldered to minimum size pin traces.Table 7. Typical ΨJB ValuesModel ΨJB (°C/W) TSOT43The junction temperature of the ADP151-EP can be calculated from the following equation:T J = T A + (P D × θJA )(1)where:T A is the ambient temperature.P D is the power dissipation in the die, given byP D = [(V IN − V OUT ) × I LOAD ] + (V IN × I GND )(2)where:I LOAD is the load current. I GND is the ground current.V IN and V OUT are input and output voltages, respectively. Power dissipation due to ground current is quite small and can be ignored. Therefore, the junction temperature equation simplifies to the following:T J = T A + {[(V IN − V OUT ) × I LOAD ] × θJA }(3)As shown in Equation 3, for a given ambient temperature, input-to-output voltage differential and continuous load current, there exists a minimum copper size requirement for the PCB to ensure that the junction temperature does not rise above 125°C. Figure 23 through Figure 28 shows junction temperature calculations for various ambient temperatures, load currents, V IN -to-V OUT differentials, and areas of PCB copper.020406080100120140J U N C T I O N T E M P E R A T U R E , T J (°C )V IN – V OUT (V)10681-023Figure 23. TSOT 500 mm 2of PCB Copper, T A = 25°CADP151-EPEnhanced ProductRev. 0 | Page 12 of 160204060801001201400.30.8 1.3 1.8 2.3 2.8 3.3 3.8 4.3 4.8J U N C T I O N T E M P E R A T U R E , T J (°C )V IN – V OUT (V)10681-024Figure 24. TSOT 100 mm 2 of PCB Copper, T A = 25°C0204060801001201400.30.8 1.3 1.8 2.3 2.8 3.3 3.8 4.3 4.8J U N C T I O N T E M P E R A T U R E , T J (°C )V IN – V OUT (V)10681-025Figure 25. TSOT 50 mm 2of PCB Copper, T A = 25°C020406080100120140J U N C T I O N T E M P E R A T U R E , T J (°C )V IN – V OUT (V)10681-026Figure 26. TSOT 500 mm 2 of PCB Copper, T A = 50°C020406080100120140J U N C T I O N T E M P E R A T U R E , T J (°C )V IN – V OUT (V)10681-027Figure 27. TSOT 100 mm 2of PCB Copper, T A = 50°C020406080100120140J U N C T I O N T E M P E R A T U R E , T J (°C )V IN – V OUT (V)10681-028Figure 28. TSOT 50 mm 2of PCB Copper, T A = 50°CIn the case where the board temperature is known, use the thermal characterization parameter, ΨJB , to estimate thejunction temperature rise (see Figure 29). Maximum junction temperature (T J ) is calculated from the board temperature (T B ) and power dissipation (P D ) using the following formula:T J = T B + (P D × ΨJB )(4)The typical value of ΨJB is 43°C/W for the 5-lead TSOT package.020406080100120140J U N C T I O N T E M P E R A T U R E , T J (°C )V IN – V OUT (V)10681-029Figure 29. TSOT, T A = 85°CEnhanced ProductADP151-EPRev. 0 | Page 13 of 16PRINTED CIRCUIT BOARD LAYOUT CONSIDERATIONSHeat dissipation from the package can be improved by increasing the amount of copper attached to the pins of the ADP151-EP . However, as listed in Table 6, a point of diminishing returns is eventually reached, beyond which an increase in the copper size does not yield significant heat dissipation benefits. Place the input capacitor as close as possible to the VIN and GND pins. Place the output capacitor as close as possible to the VOUT and GND pins. Use of 0402 or 0603 size capacitors and resistors achieves the smallest possible footprint solution on boards where area is limited.10681-030Figure 30. Example TSOT PCB LayoutADP151-EPEnhanced ProductRev. 0 | Page 14 of 16OUTLINE DIMENSIONS100708-A*COMPLIANT TO JEDEC STANDARDS MO-193-AB WITH THE EXCEPTION OF PACKAGE HEIGHT AND THICKNESS.0.450.30*0.90 MAX 0.70 MINFigure 31. 5-Lead Thin Small Outline Transistor Package [TSOT](UJ-5)Dimensions show in millimetersORDERING GUIDEModel 1Temperature Range Output Voltage (V)2 Package Description Package Option Branding ADP151TUJZ3.3-EPR2–55°C to +125°C 3.3 5-Lead TSOT UJ-5 LJ21 Z = RoHS Compliant Part.2For additional voltage options for the ADP151TUJZ package option, contact a local Analog Devices, Inc., sales or distribution representative.Enhanced Product ADP151-EP NOTESRev. 0 | Page 15 of 16ADP151-EPEnhanced ProductRev. 0 | Page 16 of 16NOTES©2012 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners.D10681-0-7/12(0)ADP151AUJZ-3.3-R7 .ADP151ACBZ-1.8-R7 .ADP151AUJZ-1.5-R7ADP151ACBZ-3.0-R7ADP151AUJZ-1.2-R7.ADP151ACPZ-1.8-R7ADP151AUJZ-1.8-R7.ADP151AUJZ-3.0-R7ADP151ACBZ-2.8-R7ADP151AUJZ-2.8-R7ADP151AUJZ-1.2-R7ADP151ACBZ-3.3-R7 .ADP151ACPZ-3.3-R7 .ADP151AUJZ-1.8-R7 .ADP151AUJZ-2.5-R7 .。

Choose your hardwareKey specificationsBandwidth 1 µHz - 120MHz (250 sine)Waveforms Noise, adjustable crest factor, sine, pulse, square, vamp, arbitrary waveform Channels1 or 2, differential outputsOutput Amplitude Amplifier High voltage: 50mV to +10V High bandwidth: 50mV to +5V Modulation types:AM, FM, PM, FSK, PWM external and internal Transition Times›2.5nsOutput Impedance 50 Ω/5 Ω selectable Sample rate 14-bit, 2G/s arbitrary waveform MemoryArbitrary: 512k points per channel Pattern: 16Mbit per channel Noise repetition rate 26 days Display Color, brightProgramming interfaces:LAN, SCPI 1992, IEEE 488.2 (GPIB), USB Supported driversAgilent VEE, IVI-COM, NI Labview, Matlab ®Standard, complete connectivity!LXI Class C compliantCouple/uncouple channels/channel addUSB 2.0AChannel 2: trigger out; Strobe out; Differential output Channel 1: trigger out; Strobe out; Differential outputTrigger mode Waveform ModeAdvanced mode (Modulation/Sweep/Bust)Keypad1.2.3.4.5.6.7.8.A 3-in-1 device for accelerated and accurate insight into your device• Create pulse, sine, square, ramp, noise and arbitrary waveforms to test your device - not the source • A 2 Channel version can be used either as 2 independent generators or as time synchronized coupled or added • Integrated in one instrument, which increases signal performance, minimizes cabling, space and test time• Glitch free change of timing parameters (delay, frequency, transition time, width, delay cycle). • Programming language compatible with Agilent 81101A, 81104A and 81110ATechnical data and pricing subject to change without notice. © Agilent Technologies, Inc. 2009, Printed in USA,May 5, 2009Pulse Pattern Generator Selection GuideLXI is the LAN-based successor to GPIB, providing faster, more efficient connectivity. Agilent is a founding member of the LXI consortium. Model Bandwidth Channels Voltage Price8114A 15MHz 1-ch 100V/2A Call 81101A 50MHz 1-ch 100mV - 10V Call 81104A + 81105A 80MHz 1 or 2 ch 100mV - 10V Call 81110A + 81111A 165MHz 1 or 2 ch 100mV - 10V Call 81110A + 81112A 330MHz 1 or 2 ch 100mV - 3,8V Call 81130A + 81131A 400MHz 1 or 2 ch 100mV - 3,8V Call 81130A + 81132A660MHz1 or2 ch100mV - 2,5VCallComplementary productsModelDescriptionDSO/MSO 6000, 7000InfiniiVision 7000 Series Oscilloscopes up to 1GHz bandwidthDSO/MSO 8604A Infiniium DSO/MSO Oscilloscope with 800MHz bandwidthDSO/MSO 5000InfiniiVision 5000 Series Oscilloscopes up to 500MHz bandwidthDSO 3000Economy DSO 3000 Series up to 200MHz bandwidth 32210A, 33220A, 33250AFunction generators with 10, 20 and 80MHz, 1 channelTypical ApplicationsFlexRay/CAN Physical Layer Receiver Test (Flyer: 5990-3160EN)Sensor Simulation Clock Signal Generation Radar Distance Testing Disc Drive TestsNoise and Jitter Source with Selectable Crest Factor Signal Source with Modulation Pulsed IV Measurements System Trigger SourceCapture & Reproduce Live SignalsRelated LiteraturePub Number Name5989-6433EN 81150A Pulse Function Arbitrary Noise Generator Data Sheet5980-0489E Pulse Pattern and Data Generators For Digital and Analog Testing5989-7860EN Agilent 81150A Pulse Function Arbitrary Noise Generator Applications5990-3233ENPCI Express® Revision 2.0 Receiver Testing with J-BERT N4903A and 81150A Pulse Function Arbitrary Noise Generator5989-9826ENAgilent 15431A Filter Set for 81150A 5989-9364ENAgilent 81150A Precision Digital NoiseCharacteristics on a Pulse Pattern ShapeAll parameters can be selected and edited with the Agilent Pulse Pattern GeneratorsDelay -timeWidthLo Hi Amp 0MATLAB is a U.S. registered trademark of the Math Works, Inc.PCI Express is a registered trademark of PCI-SIG.。

ADPS Adjustable Differential Pressure Switch overpressure, vacuum, and differential pressure applications. The scaled adjustment knob allows changes to the switching pressure to be made without a pressure gage. The ADPS is available with settings from 0.08 in w.c. (20 Pa) to 20 in w.c. (5000 Pa). The silicone diaphragm and PA 6.6 body make the Series ADPS perfect for use with air and other noncombustible gases. The Series ADPS can be used in monitoring air filters, ventilators, and industrial cooling-air circuits along with controlling air and fire-protection flaps and many other applications.Use only with mediums such as air, or other noncombustible or non-aggressive gases. Otherwise operating faults or accidents may occur.horizontally. In this case, however, the switching values are approximately 0.08 in w.c.(20 Pa) higher as indicated on the scale. In the horizontal position, the pressure switch should be mounted ‘lying down’ only (that is to say with the electrical connections pointing upwards). Do not mount the pressure switch in a hanging position (that is to say, not ‘overhead’ with the electrical connections pointing downwards). Otherwise the device will function inaccurately.a) Mounting with screws or brackets1. To mount the pressure switch, L-shaped A-288 and S-shaped A-289mounting brackets can be ordered separately. To secure the device on therear side of the housing, only use the sheet metal screws (3.5 x 8 mm)which are supplied together with the mounting brackets. Under nocircumstances must you use longer screws. Otherwise, the base of thehousing could be punctured resulting in the pressure switch leaking.2. You can also mount the pressure switch directly on a wall. To do this usescrews with a maximum diameter of 0.315˝ (8.0 mm), if you use the outermounting lugs to screw the device in place. Do not tighten the screws somuch that the base of the device is deformed. Otherwise, the pressureswitch can be shifted out of position, or leak.Installing HosesImportant: Pressure tubing cannot be kinked. Pay particular attention to this point if you run hoses over an edge. It is better to form a loop. If the hoses are kinked, the device cannot function accurately.a) For connection to the pressure switch two fittings inherent in the housing areprovided for hoses with an internal diameter of 1/4˝ (6.0 mm).1. Connect a hose with the higher pressure to socket P1 which is located on the lower section of the housing.2. Connect a hose with the lower pressure to socket P2 which is located on the middle section of the housing.After you have installed the hoses, it is absolutely essential to check them for tightness of fit at the connection points and to make sure that they run without any kinks.Printed in U.S.A. 4/20FR# 443602-00 Rev. 3©Copyright 2020 Dwyer Instruments, Inc.Electrical ConnectionWork on electrical installations must only be carried out by electricians who are specifically trained for this purpose.For cable gland models, the seal in the screw cable connection is designed for cables with alternative sheath diameters of 0.275˝ (7 mm) or 0.393˝ (10 mm). Only use these sizes – otherwise the screw cable connection cannot seal adequately.1. If using a 0.275˝ (7 mm) connecting cable, you can line up the press nut, the plain washer and the sealing ring directly on the cable.2. If using a 0.393˝ (10 mm) connecting cable, you must first break the inner rubber ring out of the sealing ring directly on the cable. Then line up the press nut, the plain washer and the sealing ring on the cable.WiringThe switching device in this pressure switch is designed as a change-over contact as can be seen from the wiring diagram (Figure 1). The rest position is shown in Figure 1 (pressure below the activation switch point on dial).1. In the instance where pole 3 (COM) closes to Pole 2, the pressure is increasing (NO).2. In the instance where pole 3 (COM) closes to Pole 1, the pressure is decreasing (NC).Protect the feed line (to pole 3) by fuse, either in control system or along the line, and do so with:1. Max 1.5 A / 250 VAC, if you are loading the contact with an resistive load.2. Max 0.4 A / 250 VAC, if you are loading the contact with an inductive load (such as relay).3. Max 0.1 A / 24 VDC, if you are using the pressure switch in the weak current version with gold-plated contacts.The connections are intended for crimp-type sockets, 0.25 in (6.3 mm).1. Make sure the crimp connection is perfect, and that the cable lugs fit properly on to the connections.2. If you do not have any crimp-type sockets available, you can also use the cable lugs which are supplied with mounted screw terminals. However, these are only intended for rigid copper wire.3. On flex, it is either necessary to crimp on strand end sleeves – and then you can also screw the strands on – or to crimp cable lugs on directly as previously described.Setting the Pressure RangeMake absolutely certain that there is no voltage on the electrical connections before you carry out any setting on the pressure switch. Otherwise, it could be fatal if you accidentally touch the electrical connections or the metal adjusting screw while you are performing the settings.a) Use the adjustment dial to set the pressure which should trip the switch on an increase of pressure.1. The indications on the dial are only correct for the vertical mounting position.2. When the pressure falls, the switch returns to its resting position as soon as the pressure falls below the dead band.Attaching Covera) Insert the screw cable connection into the recess provided for this purpose on the housing.b) Then place the housing cover in position and screw it down evenly on to the pressure switch.Testing the SettingDo not operate the system until the housing is closed. Otherwise there is the possibility of an electric shock if you accidentally touch live parts.Check the trip and reset pressures by slowly increasing the pressure and then allowing it to fall again.Important: Observe the maximum permissible operating pressure of 40 in w.c. (10 kPa) which is indicated in the data sheet. Otherwise the pressure switch may be damaged.MAINTENANCEUpon final installation of the Series ADPS Adjustable Differential Pressure Switch, no routine maintenance is required. A periodic check of system operation is recommended. The Series ADPS is not field serviceable and should be returned if repair is needed (field repair should not be attempted and may void warranty). Be sure to include a brief description of the problem plus any relevant application notes. Contact customer service to receive a return goods authorization number before shipping.Figure 11. Break contact2. Operating contact3. Power supply lineFirst make sure that there is no voltage on the connecting cable while you are working on the electrical connections. Otherwise, apossible electric shock may result and the connected equipment may be damaged. The connecting cable can be run to the pressure switch from three sides, according to choice. The screw cable connection has a plug-in design for this purpose. Rotate protective cover accordingly.1233 COM。

MAX15301是一个全功能，高效，数字化的点负载（POL）操纵器与先进的电源治理和遥测功能与PID 为基础的数字电源稳压器，MAX15301采纳Maxim拥有专利的Intune的™自动补偿，状态空间操纵算法。

Intune 的操纵律是有效的小信号和大信号响应，占占空比饱和度的阻碍。

这排除需要用户以确信和设置的阈值从线性转换到非线性模式。

这些能力在快速环路的瞬态响应，并减少输出电容器的数量相较，竞争的模拟和数字操纵器。

MAX15301包括多种功能，以优化效率。

内部开关BabyBuck的稳压器可产生栅极驱动器和内部偏置电源，低功耗的操纵器。

一种先进的，高效率的MOSFET的栅极驱动器，具有自适应非重叠按时，而持续调整的高侧和低侧的按时和驱动电压的全范围内的电压，电流和温度，以尽可能减少开关损耗。

MAX15301设计最终客户的设计环境的初衷。

上的PMBus™兼容的串行总线接口进行通信的监控器监控和故障治理。

全套的电源治理功能，无需复杂和昂贵的测序和监控IC。

大体的DC-DC转换操作，可设置通过引脚搭接，并非需要用户配置固件。

这使得电源子系统的快速进展前完成板级系统的工程。

Maxim提供支持的硬件和软件配置MAX15301 ，MAX15301可在32引线，5mm×5mm TQFN封装，工作在-40°C至+85°C的温度范围内。

特点：的自动补偿功能能够确保稳固，同时优化瞬态性能2.在快速瞬态响应减少输出电容的非线性补偿结果3.差分远端电压传感许诺±1％V OUT精度在整个温度范围内（-40°C至+85°C）接口用于配置，操纵和监测5.支持电压定位6.提高效率（自适应非重叠时序驱动器）至14V的宽输入电压范围8.高效片上BabyBuck稳压器的自偏置9.输出电压范围从到10.进入预偏置输出启动11.可配置的软启动和软停止时刻12.固定工作频率同步（300kHz至1MHz）13.灵活的排序和故障治理14.引脚手动跳线配置（输出电压，从机地址，开关频率，电流限制）15.能够快速原型图表典型工作电路引脚名字功能1SYNC外部开关频率同步输入端。

Soft Recovery Ultrafast Plastic RectifierFEATURES•Glass passivated pellet chip junction •Ultrafast reverse recovery time •Low forward voltage drop•Low switching losses, high efficiency •High forward surge capability•Solder dip 275 °C max. 10 s, per JESD 22-B106•Material categorization: for definitions of compliance please see /doc?99912TYPICAL APPLICATIONSFor use in high frequency rectification and freewheeling application in switching mode converters and inverters for consumer, computer and telecommunication.MECHANICAL DATACase: DO-201ADMolding compound meets UL 94 V-0 flammability rating Base P/N-E3 - RoHS-compliant, commercial gradeTerminals: Matte tin plated leads, solderable per J-STD-002 and JESD 22-B102E3 suffix meets JESD 201 class 1A whisker test Polarity: Color band denotes cathode endPRIMARY CHARACTERISTICSI F(AV) 3.0 AV RRM 50 V, 100 V, 200 V, 300 V, 400 V, 500 V, 600 V, 800 V, 1000 VI FSM 150 A t rr 50 ns, 75 ns V F 1.0 V, 1.7 V T J max.150 °C Package DO-201ADDiode variationsSingle dieDO-201ADMAXIMUM RATINGS (T A = 25 °C unless otherwise noted)PARAMETERSYMBOL UF5400UF5401UF5402UF5403UF5404UF5405UF5406UF5407UF5408UNIT Maximum repetitive peak reverse voltage V RRM 501002003004005006008001000V Maximum RMS voltage V RMS 3570140210280350420560700V Maximum DC blocking voltage V DC 501002003004005006008001000V Maximum average forwardrectified current, 0.375" (9.5 mm) lead length at T A = 55 °C I F(AV)3.0APeak forward surge current 8.3 ms single half sine-wave superimposed on rated load I FSM 150AOperating junction and storage temperature rangeT J , T STG-55 to +150°CNote(1)Pulse test: 300 μs pulse width, 1 % duty cycleNote(1)Thermal resistance from junction to lead and from junction to ambient with 0.375" (9.5 mm) lead length, both leads attached to heatsinkRATINGS AND CHARACTERISTICS CURVES (T A = 25 °C unless otherwise noted)Fig. 1 - Maximum Forward Current Derating Curve Fig. 2 - Forward Power Loss CharacteristicsELECTRICAL CHARACTERISTICS (T A = 25 °C unless otherwise noted)PARAMETER TEST CONDITIONS SYMBOL UF5400UF5401UF5402UF5403UF5404UF5405UF5406UF5407UF5408UNITMaximum instantaneous forward voltage 3.0 AV F (1)1.01.7VMaximum DC reverse current at rated DCblocking voltage T A = 25 °CI R10μAT A = 100 °C 75200Maximumreverse recovery timeI F = 0.5 A, I R = 1.0 A, I rr = 0.25 AT J = 25 °Ct rr 5075nsTypical junction capacitance4.0 V, 1 MHz C J 4536pFTHERMAL CHARACTERISTICS (T A = 25 °C unless otherwise noted)PARAMETERSYMBOL UF5400UF5401 UF5402 UF5403 UF5404 UF5405 UF5406 UF5407 UF5408 UNIT Typical thermal resistanceR θJA (1)20°C/WR θJL (1)8.5ORDERING INFORMATION (Example)PREFERRED P/N UNIT WEIGHT (g)PREFERRED PACKAGE CODEBASE QUANTITYDELIVERY MODEUF5406-E3/54 1.17254140013" diameter paper tape and reelUF5406-E3/731.172731000Ammo pack packagingFig. 3 - Maximum Non-Repetitive Peak Forward Surge Current Fig. 4 - Typical Instantaneous Forward Characteristics Fig. 5 - Typical Reverse Leakage CharacteristicsFig. 6 - Typical Junction CapacitancePACKAGE OUTLINE DIMENSIONS in inches (millimeters)Legal Disclaimer Notice VishayDisclaimerALL PRODUCT, PRODUCT SPECIFICAT IONS AND DAT A ARE SUBJECT T O CHANGE WIT HOUT NOT ICE T O IMPROVE RELIABILITY, FUNCTION OR DESIGN OR OTHERWISE.Vishay Intertechnology, Inc., its affiliates, agents, and employees, and all persons acting on its or their behalf (collectively, “Vishay”), disclaim any and all liability for any errors, inaccuracies or incompleteness contained in any datasheet or in any other disclosure relating to any product.Vishay makes no warranty, representation or guarantee regarding the suitability of the products for any particular purpose or the continuing production of any product. To the maximum extent permitted by applicable law, Vishay disclaims (i) any and all liability arising out of the application or use of any product, (ii) any and all liability, including without limitation special, consequential or incidental damages, and (iii) any and all implied warranties, including warranties of fitness for particular purpose, non-infringement and merchantability.Statements regarding the suitability of products for certain types of applications are based on Vishay’s knowledge of typical requirements that are often placed on Vishay products in generic applications. Such statements are not binding statements about the suitability of products for a particular application. It is the customer’s responsibility to validate that a particular product with the properties described in the product specification is suitable for use in a particular application. Parameters provided in datasheets and / or specifications may vary in different applications and performance may vary over time. All operating parameters, including typical parameters, must be validated for each customer application by the customer’s technical experts. Product specifications do not expand or otherwise modify Vishay’s terms and conditions of purchase, including but not limited to the warranty expressed therein.Except as expressly indicated in writing, Vishay products are not designed for use in medical, life-saving, or life-sustaining applications or for any other application in which the failure of the Vishay product could result in personal injury or death. Customers using or selling Vishay products not expressly indicated for use in such applications do so at their own risk. Please contact authorized Vishay personnel to obtain written terms and conditions regarding products designed for such applications.No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document or by any conduct of Vishay. Product names and markings noted herein may be trademarks of their respective owners.© 2017 VISHAY INTERTECHNOLOGY, INC. ALL RIGHTS RESERVED。

4-1462039-2Axicom IM, Signal Relays, 250VAC Contact Voltage Rating, 220VDC Contact Voltage Rating, 100mW Signal Relay Coil Power Rating (DC)Relays, Contactors & Switches > Relays >Signal RelaysInsertion Loss (HF Parameter):-.03dB @ 100MHz, -.33dB @ 900MHzIsolation (HF Parameter):-18.8dB @ 900MHz, -37dB @ 100MHzSignal Relay Coil Power Rating (DC):100 mWContact Voltage Rating:220 VDCFeaturesProduct Type Features Relay Type IM Relay Product TypeRelayElectrical Characteristics Coil Power Rating Class 50 – 300 mW Actuating SystemDC Insulation Initial Dielectric Between Open Contacts 1000 Vrms Contact Limiting Short-Time Current2 A Insulation Initial Dielectric Between Contacts and Coil 1800 Vrms Insulation Initial Dielectric Between Coil/Contact Class 1500 V – 2500 VAVoltage Standing Wave Ration (HF Parameter) 1.06 @ 100MHz, 1.49 @ 900Mhz Insulation Initial Dielectric Between Adjacent Contacts 1800 Vrms Insulation Initial Resistance 1000000 MΩContact Limiting Making Current 2 A Coil Resistance90 ΩContact Limiting Continuous Current 2 A 4-1462039-2 ACTIVEAxicom TE Internal #:4-1462039-2Axicom IM, Signal Relays, 250VAC Contact Voltage Rating, 220VDC Contact Voltage Rating, 100mW Signal Relay Coil Power Rating (DC)View on >Axicom IM|Coil Type BistableContact Limiting Breaking Current 2 AContact Switching Load (Min).1mA @ .0001VContact Voltage Rating220 VDCSignal Relay Coil Power Rating (DC)100 mWSignal Relay Coil Voltage Rating 3 VDCSignal Relay Contact Switching Voltage (Max)220 VDCSignal Relay Coil Magnetic System Bistable, 1 CoilSignal CharacteristicsIsolation (HF Parameter)-18.8dB @ 900MHz, -37dB @ 100MHz Insertion Loss (HF Parameter)-.03dB @ 100MHz, -.33dB @ 900MHz Body FeaturesInsulation Special Features2500V Initial Surge Withstand Voltagebetween Contacts & CoilWeight.75 g[.026 oz]Contact FeaturesContact Plating Material GoldContact Current Class0 – 2 AContact Special Features Bifurcated/Twin ContactsSignal Relay Terminal Type PCB-SMTSignal Relay Contact Current Rating 2 ASignal Relay Contact Arrangement 2 Form C (2 CO)Contact Material PdRu+AuContact Number of Poles2Termination FeaturesTermination Type Surface MountMechanical AttachmentSignal Relay Mounting Type Printed Circuit BoardDimensionsWidth Class (Mechanical)0 – 6 mmWidth 6 mm[.236 in]Height 5.65 mm[.222 in]Length Class (Mechanical)0 – 10 mmLength10 mm[.393 in]Height Class (Mechanical)0 – 6 mmDimensions (L x W x H) (Approximate)10 x 6 x 5.65 mm[.393 x .236 x .222 in] Usage ConditionsEnvironmental Ambient Temperature (Max)85 °C[185 °F]Environmental Ambient Temperature Class70 – 85°CEnvironmental Category of Protection RTVOperating Temperature Range-40 – 85 °C, -40 – 85 °COperation/ApplicationPerformance Type High DielectricPackaging FeaturesPackaging Method ReelOtherAdditional Features Gull WingProduct ComplianceFor compliance documentation, visit the product page on >EU RoHS Directive 2011/65/EU CompliantEU ELV Directive 2000/53/EC CompliantChina RoHS 2 Directive MIIT Order No 32, 2016No Restricted Materials Above ThresholdEU REACH Regulation (EC) No. 1907/2006Current ECHA Candidate List: JUN 2020(209)Candidate List Declared Against: JUL 2019(201)Does not contain REACH SVHCHalogen Content Low Bromine/Chlorine - Br and Cl < 900ppm per homogenous material. Also BFR/CFR/PVC FreeSolder Process Capability Reflow solder capable to 260°CProduct Compliance DisclaimerThis information is provided based on reasonable inquiry of our suppliers and represents our current actual knowledgebased on the information they provided. This information is subject to change. The part numbers that TE has identified asEU RoHS compliant have a maximum concentration of 0.1% by weight in homogenous materials for lead, hexavalentchromium, mercury, PBB, PBDE, DBP, BBP, DEHP, DIBP, and 0.01% for cadmium, or qualify for an exemption to theselimits as defined in the Annexes of Directive 2011/65/EU (RoHS2). Finished electrical and electronic equipment productswill be CE marked as required by Directive 2011/65/EU. Components may not be CE marked. Additionally, the partnumbers that TE has identified as EU ELV compliant have a maximum concentration of 0.1% by weight in homogenous materials for lead, hexavalent chromium, and mercury, and 0.01% for cadmium, or qualify for an exemption to these limits as defined in the Annexes of Directive 2000/53/EC (ELV). Regarding the REACH Regulation, the information TE provides on SVHC in articles for this part number is based on the latest European Chemicals Agency (ECHA) ‘Guidance on requirements for substances in articles’ posted at this URL: https://echa.europa.eu/guidance-documents/guidance-on-reachTE Model / Part #YDTS20Z15-19SAV001RECP ASSYTE Model / Part #1-825433-1MOD 2 PINHDR 1X11P.TE Model / Part #160088-1RING TONGUE 20-16 AWG 0.198 X .700 BRTE Model / Part #1-1415537-7RTD1L005TE Model / Part #1586963-104P UMNL PIN HDR ASSY, GWTE Model / Part #10213286-00DIGITAL THERMOPILE SENSORTE Model / Part #1-1546927-212P .325 TRI-BARRIER W/COVERTE Model / Part #1-1415017-1SR6C4012 - V23050-A1012-A551Signal Relays(122)RJ45 Connectors(2) TE Model / Part #6-1462039-8IM41DGR=IM RELAY 100 MW 3 V BisTE Model / Part #CAT-AX41-IM11B IM STANDARD (2 FORM C, 2CO CONTACTS)Compatible PartsAlso in the Series Axicom IMCustomers Also BoughtTE Model / Part #YDTS20Z25-35PNV001RECP ASSYTE Model / Part #YDTS20Z21-35PNV001RECP ASSYDocumentsProduct DrawingsIM41CGR=IM-RELAY 100MW 3V BISEnglishIM41CGR=IM-RELAY 100MW 3V BISEnglishDatasheets & Catalog PagesAxicom Signal and High Frequency Relays (RF Switches) APPLICATION NOTE #2EnglishIM Relay DatasheetEnglishIndustrial Relays Quick Reference GuideEnglishProduct SpecificationsDefinitions RelaysEnglish。

- 4 -- 1 -IMPORTANT: It is of vital importance, before attempting to operate your OCA-150 to read through this instruction manual.BRUSHLESS MOTOR ESCFOR HELICOPTERS/AIRPLANESINSTRUCTION MANUALThe OCA-150 is ECS installed with the latest FET for brushless motors. By using an optional extra ESC Programmer OCP-1, settings of ESC can be programmed quickly and securely to meet model’s specific requirements. Before operating OCA-150M i s u s e o r a b u s e o f L i P o b a t t e r i e s i s v e r y dangerous. Be sure to follow the instruction manual supplied with the batteries.Be sure to install the connectors which match the batteries, securely soldering to the battery connecting wires of the ESC. Never use the ESC with the connectors temporarily connected.B a t t e r i e s c a n b e u s e d : L i P o 2~6 c e l l s (7.4~22.2V), NiCd/NiMH 6~18 cells (7.2~21.6V)OCA-150 is equipped with BEC output as power output for receiver. Do not connect the battery for receiver when connecting the OCA-150. If both the ESC and the receiver battery are connected to a receiver, receiver, ESC and batterieswill be failed.Solder the corresponding battery connector to the battery connection wires of the ESC. Also, use a heat-shrink tube to isolate the connection. Solder the corresponding connectors (female) to the motor connection wires of the ESC. Also, use a heat-shrink tube to isolate the connection.PREPARATION Connect to the OCP-1 when the settings are made with the OCP-1.Connect to the brushless motor.The average RPM during the last flight is indicated.RPM to indicate is calculated by motor pole number and gear ratio. Default is testvalue when the ESC leaves the factory. It changes when the motor is run.Beep once every second continues until the process is completed. If you want to quit in the middle, press DEC(-).This is to store the set date in the programmer’s memory. Press INC(+) to start the process.Cool Power FET: Latest generation power FETESC Programmer OPC-1: By connecting to OCA-150, detailed setting can be done easily.Start protection: Stops involuntary starting of the motor.Low voltage cut-off: Stops the motor before the voltage reaches the level where control is lost and potential over-discharge damage to the cells occurs.No signal cut-off: Switches the ESC OFF when signal from the transmitter is not received.Overheat protection: When the temperature rises extraordinary due to overload, restrict output to protect the ESC.Battery cell number auto recognition: Function to recognize automatically cell number of the battery to connect.BEC output: Power to receiver is supplied from the ESC.SPECIFICATIONS- 2 -- 3 -Set the high point and the slowest point as follows. (In case of model type AIR/HELI)As explained before, connect the ESC, receiver and motor. Do not connect power battery atthis time.PreparationPreparationSet the throw angle of the throttle channel on the transmitter 100%. In case of Futaba, set the reverse function of the throttle channel to the reverse.When the LED on the ESC flashes, reverse the throttle channel using the servo reverse function on the transmitter. Disconnect the power battery and repeat the procedure from the beginning.In case of model type CAR or BOAT and reverse function ON, step should be replaced with the following.Set the throttle stick neutral (a short beep)→reverse(a short beep)→(a double beep)→disconnect power battery to set high point, neutral point and reverse point.Five parameters can be set without using the programmer in the following manner.How to select parameter type (number).Select the parameter type (number) with the following procedure.As explained before, connect the ESC, receiver and motor. Do not connect power battery at this time.PreparationHow to change parameter.After selecting the parameter No. as explained above, change the parameter with the following procedure.The following example explains how to set initial setting to use governor (in case of HELI) or air brake (in case of AIR).WARNINGSBe sure to set the parameters according to the throttle positions and using conditions before using the OCA-150.When normal operation is ready, check the direction of motor rotation. If the rotation is reverse, correct it by re-setting of the parameter or changing connection of the motor.Wrong setting may cause sudden rotation of the motor or out of model control which is very dangerous.If the power battery is connected with the throttle stick not at the slowest position, LED flashes. In this case, move the throttle stick to the slowest position and a set of very short and short beep is emitted to confirm ready to operate.If the power battery is connected with the throttle stick at high and entered into the setting mode, disconnect the power battery and repeat from the beginning.By using an optional extra ESC Programmer OCP-1, settings of ESC can be programmed quickly and securely to meet model’s specific requirements.LCDEditing ButtonsConnection of the programmerConnect the OCP-1, power battery and motor to OCA-150 as explained before.Operation of editing buttonsSetting itemsItems can be programmed with the OCP-1 are listed below.How to setWhen the OCP-1 and power battery are connected to the ESC, current settings of the ESC are automatically stored in the OCP-1.Select the item to change with the arrow buttons (↓ or ↑) and change the setting with INC(+) and DEC(-) buttons.When the parameter setting of the ESC with the OCP-1 is completed,write the set data to the ESC with “ Down load the set data to the ESC” function. Set data cannot be written to the ESC with only parameter setting.Selection of battery typeSetting range: LiPo, NiCd Default: LiPoSelect power battery type to use with INC(+) and DEC(-) buttons.When the battery type is changed, “CUT OFF VOLTAGE” and “CUT OFF TYPE”parameters are changed.Setting range: Slow/Normal/Fast or Value 5~100%Default: NormalSlow FastWith model type AIR, adjust the air brake effect. Select to stop the motor gradually or suddenly with INC(+) and DEC(-) buttons.With 100% motor stops suddenly.。

FEATURES●Ultra Low Noise Output●High Output Voltage Accuracy●Guaranteed 150mA Output●Maximum Output Voltage of Adjustable type is 8.5V.●Low Quiescent Current●Low Dropout Voltage●Extremely Tight Load and Line Regulation●Very Low Temperature Coefficient●Current and Thermal Limiting●Reverse-battery Protection●“Zero” off-mode Current●Logic-controlled Enable●Moisture Sensitivity Level 3APPLICATION●Cellular Telephones●Laptop, Notebook, and Palmtop Computers●Battery-powered Equipment●PCMCIA V CC and V PP Regulation/Switching●Consumer/Personal Electronics●SMPS Post-regulator/DC to DC Modules●High-efficiency Linear Power Supplies3.8,4.0,5.0DESCRIPSIONThe TJ5205 is an efficient linear voltage regulator with ultra low-noise output, very low dropout voltage (typically 17mV at light loads and 165mV at 150mA), and very low ground current (600µA at 100mA output).The TJ5205 offers better than 1% initial accuracy. Designed especially for hand-held, battery-powered devices, the TJ5205 includes a CMOS or TTL compatible enable/shutdown control input. When shutdown, power consumption drops nearly to zero.Regulator ground current increases only slightly in dropout, further prolonging battery life.Key TJ5205 features include a reference bypass pin to improve its already excellent low-noise performance, reversed-battery protection, current limiting, and over temperature shutdown.The TJ5205 is available in fixed and adjustable output voltage versions in SOT-23-5 PKG and SOP-8PP PKG. And adjustable type’s maximum output voltage is 8.5V.Absolute Maximum Ratings (Note 1)(Note 2)Ordering InformationOrdering Information (Continued)Package Type Root Name Product CodeOutput Voltage : ADJ / 2.5V / 2.7V / 2.8V / 2.85V / 2.9V / 3.0V / 3.3V / 3.6V / 3.8V / 4.0V / 5.0V SF5 : SOT-23-5L DP : SOP-8PP D : SOP-8PIN CONFIGURATIONVOUT N.C N.C BYP/ADJVIN GND N.C ENSOT-23 5L SOP-8 / SOP-8PPBLOCK DIAGRAM[ Ultra-Low-Noise Fixed LDO Regulator ][ Ultra-Low-Noise Adjustable LDO Regulator ]TYPICAL APPLICATION- Typical Fixed Output ApplicationV OUTV INEN- Typical Adjustable Output ApplicationV INV OUT EN* Note) BYP pin can be left open if low noise operation is not required.V OUT = V REF(1+R2/R1)V REF = 1.242VV OUT(min) = 2.0VELECTRICAL CHARACTERISTICSV IN=V OUT+1V ; I L=100uA ; C L=1.0uF; V EN≥2.0V ; T J=25°C, bold values indicate -40°C ≤T J≤+125°C; unless noted.Enable InputNote 1. Exceeding the absolute maximum rating may damage the device.Note 2. The device is not guaranteed to function outside its operating rating.Note 3. The maximum allowable power dissipation at any T A (ambient temperature) is P D(max)=(T J(max)–T A)+ θJA. Exceeding the maximum allowable power dissipation will result in excessive die temperature, and the regulator will go into thermal shutdown.Note 4. The TJ5205-ADJ has V REF=1.242V±1%, but minimum output voltage for TJ5205-ADJ must be above V OUT min=2.0V.Note 5. Output voltage temperature coefficient is defined as the worst case voltage change divided by the total temperature range.Note 6. Regulation is measured at constant junction temperature using low duty cycle pulse testing. Parts are tested for load regulation in the load range from 0.1mA to 150mA. Changes in output voltage due to heating effects are covered by the thermal regulation specification.Note 7. Dropout Voltage is defined as the input to output differential at which the output voltage drops 2% below its nominal value measured at 1V differential.Note 8. Ground pin current is the regulator quiescent current plus pass transistor base current. The total current drawn from the supply is the sum of the load current plus the ground pin current.Note 9. Thermal regulation is defined as the change in output voltage at a time “t” after a change in power dissipation is applied, excluding load or line regulation effects. Specifications are for a 150mA load pulse at V IN = 16V for t = 10ms.TYPICAL OPERATING CHARACTERISTICSTYPICAL OPERATING CHARACTERISTICS (Continued)REVISION NOTICEThe description in this data s heet can be revised without any notice to describe its electrical characteristics properly.。

150 mA, high input voltage LDO Linear Regulators ME6208 SeriesGeneral Description FeaturesTypical Application Package● Electronic weighbridge ● 3-pin SOT23-3、SOT89-3、TO92 ● SCM● Phones, cordless phones ● Security Products● Water meters, power meters● High output accuracy ：± 2% ● Input voltage ：up to 18 V ● Output voltage ：3.0 V ~ 5.0V● Ultra-low quiescent current (Typ. = 3 µ A) ● Output Current ：Iout = 200mA （When Vin = 7V and Vout =5V ）● Importation good stability ：Typ. 0.05% / V ● Low temperature coefficient ● Ceramic capacitor can be usedTypical Application CircuitSelection GuideME6208X X GEnvironment mark Package:M3--SOT23-3X Function Product Type Product Series MicroneX X Output Voltage P--SOT89-3T--TO92Pin ConfigurationPin AssignmentBlock DiagramAbsolute Maximum RatingsElectrical CharacteristicsONote ：1. V OUT (T) ：Specified Output Voltage2.V OUT (E) ：Effective Output Voltage ( i e. The output voltage when “V OUT (T)+2.0V”is provided at the Vin pin whilemaintaining a certain Iout value.)3.V DIF：V IN1–V OUT(E)’V IN1：The input voltage when V OUT(E)’ appears as input voltage is gradually decreased.V OUT(E)’=A voltage equal to 98% of the output voltage whenever an amply stabilized Iout and {V OUT (T) +2.0V} is input.Precautions●During the test, if AC/DC power supply and the ceramic chip capacitors collocation is used, there may beserious voltage spike phenomenon instantaneously. When the power supply access to 16V, the voltage is rushed to about 30V instantaneously. Because of exceeding the limit voltage of chip, the chip is damaged. If you string a small resistance of 1 ohm in the input end during the test, the peak phenomenon can be avoided.●In the test, there is serious burr phenomenon only when the AC/DC power is used with ceramic chipcapacitors. But electrolytic capacitors and tantalum capacitance won't appear above phenomenon. Please be sure to pay attention to this point when you use AC/DC power.●In normal use, when any type of capacitor is used with battery or the supply of fire power, the abovephenomenon doesn’t occur.Type Characteristics（1）Output CurrentVS.Output Voltage（Ta = 25 °C）ME6208A50（2）Input VoltageVS.Output Voltage（Ta = 25 °C）ME6208A50（3）Output Current VS.Droput Voltage（Ta = 25 °C）ME6208A50（4）Input Voltage VS. Supply Current（Ta = 25 °C）ME6208A50（5）Output Voltage VS. TemperatureME6208A33PGPackaging Information ●Packaging Type: SOT23-3●Packaging Type: SOT89-3●Packaging Type:TO-92ME6208V06 Page 11 of 11● The information described herein is subject to change without notice.● Nanjing Micro One Electronics Inc is not responsible for any problems caused by circuits or diagrams described herein whose related industrial properties, patents, or other rights belong to third parties. The application circuit examples explain typical applications of the products, and do not guarantee the success of any specific mass-production design.● Use of the information described herein for other purposes and/or reproduction or copying without the express permission of Nanjing Micro One Electronics Inc is strictly prohibited.● The products described herein cannot be used as part of any device or equipment affecting the human body, such as exercise equipment, medical equipment, security systems, gas equipment, or any apparatus installed in airplanes and other vehicles, without prior written permission of Nanjing Micro One Electronics Inc.● Although Nanjing Micro One Electronics Inc exerts the greatest possible effort to ensure high quality and reliability, the failure or malfunction of semiconductor products may occur. The user of these products should therefore give thorough consideration to safety design, including redundancy, fire-prevention measures, and malfunction prevention, to prevent any accidents, fires, or community damage that may ensue.。

INDEX Numerics15/15XT 515K Air/Oil Spindle Installation 293Install Component Plumbing 297Plumbing Spindle 296Wiring Harness Installation 2952016L 122216 83016 103016L 143020 264020 164020A 184525 2850 Taper Dual Arm Tool Changer 151Alignment 163Arm Installation 161Inserting the Arm Assembly 162Installation 156Installation Notice 157Maintenance 161Sending the Tool Changer Spindle to Home Position 161 Sub-Assemblies 152Tool Changer Specifications 151Troubleshooting 1585020A 206030 226535 308030 24AAir Positive Flow System 287Air Supply 45Alternate Service 50ATC Motor Replacement Procedure 120Pulley Alignment 122Replacing the Slide Motor 121Replacing the Turret Motor on a Geneva Wheel ATC 120Replacing the Turret Motor on a Servo Turret ATC 121Turret Factor Setting 122Attached Optional Devices 325Access from Program Using Macro Statement #DISK 339Macro Statement Format 339Restrictions on File Content and Format 339Restrictions on User Defined Subroutines 340Subprograms and Fixed Subroutines ARE Allowed 340 CNC 88 HS Optional Diskette Drive 336CNC88HS Optional Diskette Drive- Miscellaneous 338Access from Control 338Requirements 338Specifications 338Diskette Drive Error Codes 340Dynamic Tool Load Compensation 332Servo Coolant Assembly 333Servo Coolant Control 334Troubleshooting Checklist 335M-Function Board Use and Setup 3251050-3A M-Function PCBA (PCB-0008) - Two M Functions. 327Fadal M Functions 326Fadal Normally Supplied M-Functions 327Fadal Optional M-Functions 327M-Function Contacts 329M-Function Hook-up 329Miscellaneous Functions (M-Codes) 325Reset Options 328U7 (Dip Switch) 328Remote Manual Pulse Generator 330Installation Procedure 331Auger 80Chip Removal from the Exit Tube 81Chip Removal from the Machine Interior 81Cleaning and Freeing Chips from the Auger Chip Removal System 80 Automatic Tool Changers 107Adjustments 114ATC Slide Belt Replacement & Adjustment 119ATC Turret Slide Adjustment 116Spring Configuration 21 & 30 Tool Changers 116Tool Turret Rotational Adjustment 118Z Axis Cold Start Adjustment 114Operation 107ATC Fault Messages 110ATC Sensors & Switch 110ATC Servo Turret Operation 111Electrical Operation 107Programming 107Servo Turret Controller and Amplifier Boards (PCB-0108) 113Tool Change Sequence 109BBall Pockets Incorrect 279Belt Drive Systems 265Motor Plate Tensioner Cable 269Posi-Drive Belt System 265CChecking Grounding Integrity of Fadal VMCs 48Inspection 49Specification 48Verification 49Chip Removal Devices 447Auger, Chip Removal System 449Daily and Weekly Safety Tests for Door Monitor 452PCB-0197 Auger Control & Door Interlock Monitor Board 1310-0C 449 Chip Conveyor 453Cause of Trouble and Corrective Action 458Chip Conveyor Power and Controls 455Installation Procedure 453Maintenance Schedule Chip Conveyor 459Observance and Inspection 457Pre-Startup Safety Inspection 456Restarting the Chip Conveyor 456Stopping the Chip Conveyor on US and CE Machines 456 HydroSweep 447Maintenance Schedule 447Circuit Breakers 50Clamp-on Ammeter Testing 490Ballscrew Alignment 491ExTech AC/DC Clamp-On Ammeter 490Gib and Gib Strap Verification 490Limit Stop Check 491CNC Controls 3051460-1 Memory Expansion Boards 320DC Power Supply 312Door Interlock Monitor Board 2000-1B (PCB-0196 312Indicators (LEDs) 313Inputs 312Operation 312Outputs 312Power 312Terminals 312Electrostatic Discharge (ESD) 306Emergency Stop Circuit Overview 313Axis Controller 1010-6 319Basic Hardware Operation DescriptionNormal Operation (No Fault) 313Basic Software Operational Description 314Configurations 316Fadal Axis Board Jumper 316Fault Condition 314Troubleshooting Tips 315Fadal’s Block Diagram 305Feedrate Potentiometer (Pot) Adjustment 321Functional Description 306Axis Controller Boards 309Boards in Motherboard or Backplane 306Boards Outside the Motherboard 311J14 310Slot 1 to 4 306Slot 10 308Slot 11 308Slot 12 308Slot 13 308Slot 14 310Slot 15 311Slot 16 311Slot 17 311Slot 5 307Slot 6 308Slot 7 308Slot 8 308Slot 9 308Master Feedrate 320PCBA Compatibility Chart 325Zero Out Memory Procedure 322Zero-out Memory 324Conduit 51Coolant Thru the Spindle 300Coolant-Thru Spindle Seal Kit Instructions 300 Determining the Leak Location 301Electrical 300Hydraulic Actuator Set-up 303Mechanical 300Coolant-Thru Drawbar Cylinder 278DDiagnostic System Commands 483DS - Display Switches 483Diagnostics 483Drawbar Cylinder Bushing 277Drawbar Cylinder Plate 277Drive Control 6 Pin Molex Connector 240Drive Ground 240Dual Arm Tool Changer 124Errors 141Installation & Testing 129Operation 137Scheduled Maintenance 150Sensors 139Set-Up 135Software & Mechanical Test 134Sub-Assemblies 125Sys 101.4 Software Update 139Tool Changer Specifications 124Tool Loading Procedures 137Troubleshooting 140EElectrical Grounding 46Primary Grounding 47Electrical Service 50Alternate Service 50Circuit Breakers 50Conduit 51Preferred Service 50Wiring 50Emergency Error Codes 530Error Numbers From the Axis or Spindle Controller 530 Error Messages 497Exhaust Valve 277Exhaust Valve Nipple 277FFadal Bolt Torque Specifications 32Foundation 41Fuses, Heaters, Parameters 627FORMAT 633GGeneral Information 461Binary Number Groupings 477Binary Numbers 475Number Systems 475 Communications Troubleshooting 463 Cables 466Computer and Computer IO Port 467Environment 463File 463Software 468VMC 464Fadal Machining Centers Serial Numbers 462 Helpful Formulas 461Conversion Factors 461Electrical References 461Expansion Coefficients 461Temperature 461Reading Status Group 477Solving the Thermal Expansion Problem 474 Ambient Sources 475Cooling Systems 475General Considerations 474Radiant Heat 475Sunlight 475Thermal Expansion 470Accuracy and Repeatability 470Ambient Temperature 472Expansion Coefficients 471Fixtures / Sub Plates 473Friction 471Heat Sources 471Machine Assemblies 473Machining Practices 472Material Differences 473Non-Uniform Expansion 473Overview 470Recognizing Thermal Expansion 470 VMC Maintenance 478Cabinet Fans 478Conclusion 481Coolant 479Coolant Through Spindle 480Cooled Ball Screws and Spindle 480Glass Scales 480Lubrication 478Machining Practices 478Monitoring Position Changes 479Probe 480Rough Cut / Cool Down / Finish Cut 479VMC Options 479Warm Up 478HHeidenhain Tester 428Hold Down Clamps 74Hydraulic Actuator Assembly Bolts 278 Hydraulic Brakes 3674th Axis Brake Check-Out 3684th Axis Brake Installation 3674th, 5th Axis Brake Check-Out 3694th, 5th Axis Brake Installation 368 Hydraulic Hi/low System 2707,500 RPM Poly Chain Belt 271Spindle Belt Replacement 271Filling 270HydroSweep 447HydroSweep Only 966-Month Planned Maintenance 97Daily Maintenance 96Each Part Cycle 96Monthly Maintenance 97Weekly Maintenance 97IIllustrations & Data for All VMC Models 1 VMC 15/15XT 5VMC 2016L 12VMC 2216 8VMC 3016 10VMC 3016L 14VMC 3020 26VMC 4020 16VMC 4020A 18VMC 4525 28VMC 5020A 20VMC 6030 22VMC 6535 30VMC 8030 24Input Three Phase Power 240Installation & Hook-Up 53Air Supply 58Moving the VMC-Crane 55Moving the VMC-Fork Lift 54Placing the VMC 56Power Check 58Unlocking Front Doors with CE Door Locks 53Unpacking 53Installation Procedures 53Inverter Wye Delta 6 Pin Molex Connector 241Inverter/Vector Drive Inputs & Outputs 240Drive Control 6 Pin Molex Connector 240Drive Ground 240Input Three Phase Power 240Inverter Wye Delta 6 Pin Molex Connector 241Load Meter Output 241Output Three Phase Power 240Vector Drive Encoder 9 pin Molex Connector 242Vector Drive with Rigid Tapping 243Inverter/Vector Drives 239LLaser Calibration-Renishaw 84Aligning the laser 88Axis Calibration 89Calibration Requirements and Limits 86Definitions 84Documentation 85Download Survey 89Laser Setup 86Laser Shut Down 93Materials and Equipment 84Procedure 84Reference Documentation 84Responsibilities 84Safety and Environmental 84Sample output from a laser measurement system. 91 Scope 84Standard Fadal Cnc88hs 85Leveling 69Box Way VMCs 69For All VMCs 69Linear Way VMCs 70Load Meter Output 241MMachine Maintenance 75Machine Parameters 6323 PHASE NO 5% LOW NO 6385TH AXIS HEAD 644A-AXIS RATIO 635AIR VALVE FEEDBACK 645A-PALLET 644ASPECT 641AT SPEED 645AUTO BRAKE 643AXES X,Y,Z 634AXIS DISPLAY 643BAUD RATE 633B-AXIS RATIO 636BINARY BUFFERS 255 640B-PALLET 644CMD MENU 640CRC MODE 639DEFAULT G0 635DEFAULT G17 636DEFAULT G90 635DEFAULT INCH 638FORMAT 633G0 DETAIL 644GAIN 641HIGH TORQUE 640IMM. FIXED CYCLE 637IPM 642M60/A-AXIS BRAKE 635M62/B-AXIS BRAKE 636M7-FLOOD M8- MIST 638N-WORDS ORDERED 639ORIENTATION FACTOR 638OVERLOAD 642PALLET 641PENDANT 634PU FORMAT 639RAMP 641RPM FACTOR 637SCREW 642SPINDLE AFTER M6 633SPINDLE OFF 640SPINDLE TYPE 637TIMERS 641TOOL CHANGER 636TOOL TABLE 639TRAVEL 634TURRET FACTOR 640VECTOR 643XYZ RAMP 642Z TAP GAIN 643Menu Diagnostics 486Menu Page 1 486Menu Page 2 488Menu Page 3 488Menu Page 4 489Menu Page 5 489Moving the VMC-Crane 55Moving the VMC-Fork Lift 54OOutput Three Phase Power 240Oversized Diameter 278PPallet Changer 431Installation of Light CurtainMirror Alignment 437Installation of Light curtain 436Installation of Pallet Changer 431Maintenance Schedule 444Operation 439Manual Operation 440M-Functions 439Pallets 439Setting the Sensor on the 1840 Board 438Purpose 438Pallet Changer/Hydro Sweep 94Daily Maintenance 94Each Part Cycle 94Monthly Maintenance 95Weekly Maintenance 94PCB-0213 Dual Arm ATC Controller Card 167Currents 169Description and Explanation of Operation of PCB-0213 (1330-0A) 167 Functional Explanations 169Inputs 167LED Indicators 168Outputs 168Phase Converter Rotary 68Positioning 44Preferred Service 50Pre-Installation Procedures 41Primary Grounding 47Probes 371MP-11 Probe 371MP-12 Probe 372TS-27 372Probes & Scales 371RRecommended Mainline Fuses / Circuit Breakers 39Rigid Tapping 260Fadal Rigid Tapping Procedure 260Rigid Tap with AC-0017 Software 262Rotary Tables 3414th Axis 341Adjusting the Cold Start 351Balancing the Amplifier 344Connecting the VH-65 Motor Cable 342Evaluating the Following Error 345FADAL RT-175 360FADAL RT-225 361FADAL RT-275 362FADAL V-300 (V-400) Rotary Table 355FADAL VH-65 & VH-5C 354Horizontal Installation Difference(s) 343Installation 342Installing the Servo Control 343Maintenance 352Pre-installation 341Remove the Rotary Table from the Shipping Crate 342Rotary Set-Up 353Setting Backlash at the Control 345Setting the VH-65 Worm Gear Backlash 346Setting the VMC Parameters 344Setting the Voltage 345Squaring the VH-65 342Technara MD-200R 357Technara MD-300R 358Troyke NC-10 356Tsudakoma RNCV-401 359Verifying Air Brake Engagement 351SScale Box Installation / Side Mount 416Scale Box Installation / Top Mount 421Scales 3731580 Board Setup 414Installing Scales 373Scheduled Maintenance 75Cooling Fans 78Dual Arm Tool Changer 82Cleaning 82Daily Maintenance 83Grease 82Inspection 83Lubricant 82Miscellaneous Maintenance 83Weekly Maintenance 83Fuses, Heaters, & Relays 80Auger 80Fluids 80Lubrication of the Ways 76Flushing a Contaminated Waylube System 77Waylube System 76Maintenance & Lubrication Schedule 75Daily 75Every 4 months 76Weekly 75Pump Filter 78Spindle & Ballscrew Cooling System 78Tank Reservoir 79Pressure 79Source for Dowfrost 79Sequence of Dual Arm-ATC Operation When Used With The Fadal Control 171 DA-ATC Tool Change Cycle Fadal Control 172Feedback 171Part Numbers 171Service Programs 581TA,2 Programs 581O5801-45 Deg Test 581O5802-X Resolver Test 582O5803-Y Resolver Test 582O5804-Z Resolver Test 582O5805-Work Toolchanger 582O5806-Scrape Z Head 584O5807-X Vibration 584O5808-Y Vibration 585O5809-Z Vibration 585O5810-Orientation 586O5811-Balance Inch 595, Metric 700ipm 302 586O5812-X Balance 680 587O5813-Y Balance 680 587O5814-Z Balance 680 588O5815-A or B 680 Balance 588O5817-Spin Fwd Rev 589O5818-Workout 2216 589O5819-Workout 4020 591O5820-Workout 6030 594O5821- X Calib 2216 596O5822 -Y Calib 2216 597O5823-X Calib 4020 597O5824 — Y Calib 4020 598O5825 — X Calib 6030 598O5826-Y Calib 6030 599O5828-Scrape 6030 Table 600O5829 — Mill 6030 Table 601O5830-Scrape 4020 Table 601O5831-Mill 4020 Table 603O5832-Scrape 2216 Table 603O5833-Mill VMC 2216 604O5834-Scrape 20 Table 605O5835-Test Scales 606O5836-Test Cut 607O5837-Probe Cycle Test 609O5838-Spindle Break In 610O5839-Pallet Changer 611O5840-Mill Pallet Table 614O5842-Engrave Pallet A 615O5843 — Center Bearing Assy. 615O5844-Mill VMC 20 616O5845-Mill VMC 15 617O6000-Rigid Tap Cycle 617TA,2 ProgramsO5841-Mill Pallet Slot .687-.689 615 TA,5 Programs 6186001-Ballbar Test 625O5827-Cycle Test 618Tool Offsets for the Service Programs 581 Shipping Dimensions 43Single Phase Input Power 67Specification -Grounding for the Fadal machine48Specifications 1Spindle Belleville Springs Quantity Chart 285Spindle Drawbar and Belleville Spring Replacement 283Drawbar Removal 283Remove Floater (This will rarely be necessary.) 284Replace Belleville Springs 284Spindle Drive Systems 239Adjustments 244Adjusting the AMC Vector Drive 256Adjusting the Baldor Vector Drives 244Adjustments 257Auto Tuning/ Zero Balance 244Baldor Spindle Drive Parameter Usage for Fadal VMC 245LEDs 256Motor Mag Amps for INV-0070 250Non Rigid Tap Machines 259Pot Adjustments 258Pots 257Regenerative Resistors 254Rigid Tap Machines 259Switch Positions 256Switch Settings 258Terms and Procedures245Velocity Monitor Output 256Motors 26310 HP Motor 26315 HP Motor 26320 HP Motor 263WYE / DELTA Motors 264Spindle Drives 239Spindle Duty Cycle 286Spindle Pre-Load 286Measuring the Spindle Pre-Load 286Spindles 28815K Air/Oil Spindle 2887.5K & 10K Grease Packed Spindles 288Adjusting Spindle Tram 293Component Installation 290Control Board Mounting 291Installing Spindle Lubrication Pump 290Pressure Manifold Mounting 291Regulator/ Separation Block Mounting 290Solenoid Modification 291Vacuum Pump Installation 290Spindle Tram 292Spindle/Lube Pump/Control 289Supplemental Grounding 47TTable & T-Slot Dimensions 3315 & 2016L Table 3315, 15XT, 2216, 3016, 2016L & 3016L T-Slots 3415XT & 3016L Table 342216 & 3016 Table 333020, 4525 Table & T-Slots 353020, 4525, 6535 T-Slots 384020 Table 354020, 4020A, 5020A, 6030 & 8030 T-Slots 384020A & 5020A Table 366030 Table 366535 Table 378030 Table 37Tap-Tap Cycle 282Test Cut Procedure 492Tests for CE Safeguards on Fadal Machines 98Daily 99Daily & Weekly Safety Tests for CE Safety Circuits 99Door Interlock Monitor (2000-1A) Weekly Test 100Door Interlock Monitor Daily Test for 2000-1A or 1310-0C 99Door Interlock Monitor on Auger Board (1310-0C) Weekly Test 102 Door Interlock Monitor Weekly Test for 2000-1 B or -1 C 101Dual Arm Tool Changer (1330) Daily Test 99Dual Arm Tool Changer (1330) Weekly Test 103Front Door Lock Daily Test for 2030-OA 99Front Door Lock Weekly Test for 2030-OA 103Pallet Changer (1100-3A) Daily Test 100Pallet Changer (1100-3A) Weekly Test 104Weekly 100Tilting Rotary Tables, 4th & 5th Axis 363A &B Axis Position Loop Gain (1010-5) 365FADAL TR-65 363Tools Sticking in the Spindle During a Change Cycle 2761. Air Supply Pressure 27610. Orientation Bridge "Lifting" 27811. Black Oxide Tool Holders 27812. Dirty Tool Holders 27813. Spring Pilot 27814. Spring Pilot 27915. Drawbar Scored 27916. Damaged Drawbar 27917. Damaged Floater 27918. Testing Procedure 2792. Drawbar Cylinder Hall Effects Switch 2773. Insufficient Air VolumeMAC In-Line Valve 2774. Air Leaks 2775. Air Leaks 2776. Air Leaks 2777. Air Leaks 2778. Air Leaks 2789. Air Leaks 278DRB-0024 Sticking Tools Kit, 10K LDB 281DRB-0025 Sticking Tools Kit, 10K LDB-CT= 281MEASURING DRAWBAR PERFORMANCE 280 Transformer Sensor 68Transformer Tapping 66Troubleshooting 497Troubleshooting Charts 536UUnlocking Front Doors with CE Door Locks 53 Unpacking 53VVector Drive Encoder 9 pin Molex Connector 242Vector Drive with Rigid Tapping 243Verification - Check grounding integrity with Fluke meter 49 VMC Test Cut 494Part 495WWiring 50ZZero-Out Memory Procedure 105Zero-Out Memory Settings 107。

MIC5365/6 Evaluation BoardHigh Performance Single 150mA LDOMLF and Micro LeadFrame are registered trademarks of Amkor Technology, Inc.Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • General Description The MIC5365/6 is an advanced general purpose linear regulator. The MIC5365/6 is capable of sourcing 150mA output current with high PSRR and low output noise. When the MIC5366 is disabled an internal resistive load is automatically applied to the output to discharge the output capacitor. Both the MIC5365 and MIC5366 are available in a 4-pin 1mm x 1mm Thin MLF ®, as well as the SC-70-5 packages. The MIC5365/6 linear regulator is easy to use. A small output capacitance of only 1µF for the output is required. An input capacitor may be required when the power supplyis more than 4-inches away from the device. Theevaluation board includes an input capacitor of 10µF tocompensate for long inductive test leads.RequirementsThe MIC5365/6 evaluation board requires an input powersource that is able to deliver at least 200mA at a voltagewithin the range of 2.5V to 5.5V. The output load can beeither active or passive.PrecautionsThe evaluation board does not have reverse polarity protection. Applying a negative voltage to the V IN terminal may damage the device.The MIC5365/6 evaluation board is tailored for a Li-Ion range input supply voltage. It should not exceed 5.5V on the input.Getting Started 1. Connect an external supply to V IN . Apply the desired input voltage to the V IN (J1) and ground terminal (J2) of the evaluation board, paying careful attention to polarity and supply voltage (2.5V ≤ V IN ≤ 5.5V). An ammeter may be placed between the input supply and the V IN terminal to the evaluation board. Ensure that the supply voltage is monitored at the V IN terminal. Ammeter and/or power lead resistance can reduce thevoltage supplied to the input. 2. Enable/Disable the MIC5365/6. The evaluationboard is set up for “Default Disable” with a 100kpull down resistor on the enable pin (EN) to GND. To enable the output, simply jumper the EN terminal (J5) to the V IN terminal (J1). The enablepin must be either pulled high or low for properoperation. Removing the pull down resistor andleaving the pin floating will cause the regulator tooperate in an indeterminate state . 3. Connect the load to the V OUT terminal (J3) andground terminal (J4). The load can be either a passive (resistor) or active (electronic load). Be sure to monitor the output voltage at the V OUT (J3) terminal.Ordering InformationPart Number DescriptionMIC5365-1.0YMT EV 150mA LDO, Vout=1.0V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-1.2YMT EV 150mA LDO, Vout=1.2V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-1.5YMT EV 150mA LDO, Vout=1.5V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-1.8YMT EV 150mA LDO, Vout=1.8V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-2.6YMT EV 150mA LDO, Vout=2.6V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-2.8YMT EV 150mA LDO, Vout=2.8V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-2.85YMT EV 150mA LDO, Vout=2.85V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-2.9YMT EV 150mA LDO, Vout=2.9V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-3.0YMT EV 150mA LDO, Vout=3.0V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-3.3YMT EV 150mA LDO, Vout=3.3V, 1mmx1mm Thin MLF® Evaluation board.MIC5365-1.0YC5 EV 150mA LDO, Vout=1.0V, SC-70-5 Evaluation board.MIC5365-1.2YC5 EV 150mA LDO, Vout=1.2V, SC-70-5 Evaluation board.MIC5365-1.5YC5 EV 150mA LDO, Vout=1.5V, SC-70-5 Evaluation board.MIC5365-1.8YC5 EV 150mA LDO, Vout=1.8V, SC-70-5 Evaluation board.MIC5365-2.6YC5 EV 150mA LDO, Vout=2.6V, SC-70-5 Evaluation board.MIC5365-2.8YC5 EV 150mA LDO, Vout=2.8V, SC-70-5 Evaluation board.MIC5365-2.85YC5 EV 150mA LDO, Vout=2.85V, SC-70-5 Evaluation board.MIC5365-2.9YC5 EV 150mA LDO, Vout=2.9V, SC-70-5 Evaluation board.MIC5365-3.0YC5 EV 150mA LDO, Vout=3.0V, SC-70-5 Evaluation board.MIC5365-3.3YC5 EV 150mA LDO, Vout=3.3V, SC-70-5 Evaluation board.MIC5366-1.0YMT EV 150mA LDO with auto discharge, Vout=1.0V, 1mmx1mm Thin MLF® Evaluation board.MIC5366-1.2YMT EV 150mA LDO with auto discharge, Vout=1.2V, 1mmx1mm Thin MLF® Evaluation board.MIC5366-1.5YMT EV 150mA LDO with auto discharge, Vout=1.5V, 1mmx1mm Thin MLF® Evaluation board.MIC5366-1.8YMT EV 150mA LDO with auto discharge, Vout=1.8V, 1mmx1mm Thin MLF® Evaluation board.MIC5366-2.6YMT EV 150mA LDO with auto discharge, Vout=2.6V, 1mmx1mm Thin MLF® Evaluation board.MIC5366-2.8YMT EV 150mA LDO with auto discharge, Vout=2.8V, 1mmx1mm Thin MLF® Evaluation board.MIC5366-2.85YMT EV 150mA LDO with auto discharge, Vout=2.85V, 1mmx1mm Thin MLF® Evaluation board. MIC5366-2.9YMT EV 150mA LDO with auto discharge, Vout=2.9V, 1mmx1mm Thin MLF® Evaluation board. MIC5366-3.0YMT EV 150mA LDO with auto discharge, Vout=3.0V, 1mmx1mm Thin MLF® Evaluation board. MIC5366-3.3YMT EV 150mA LDO with auto discharge, Vout=3.3V, 1mmx1mm Thin MLF® Evaluation board. MIC5366-1.0YC5 EV 150mA LDO with auto discharge, Vout=1.0V, SC-70-5 Evaluation board.MIC5366-1.2YC5 EV 150mA LDO with auto discharge, Vout=1.2V, SC-70-5 Evaluation board.MIC5366-1.5YC5 EV 150mA LDO with auto discharge, Vout=1.50V, SC-70-5 Evaluation board.MIC5366-1.8YC5 EV 150mA LDO with auto discharge, Vout=1.80V, SC-70-5 Evaluation board.MIC5366-2.6YC5 EV 150mA LDO with auto discharge, Vout=2.60V, SC-70-5 Evaluation board.MIC5366-2.8YC5 EV 150mA LDO with auto discharge, Vout=2.80V, SC-70-5 Evaluation board.MIC5366-2.85YC5 EV 150mA LDO with auto discharge, Vout=2.85V, SC-70-5 Evaluation board.MIC5366-2.9YC5 EV 150mA LDO with auto discharge, Vout=2.90V, SC-70-5 Evaluation board.MIC5366-3.0YC5 EV 150mA LDO with auto discharge, Vout=3.0V, SC-70-5 Evaluation board.MIC5366-3.3YC5 EV 150mA LDO with auto discharge, Vout=3.3V, SC-70-5 Evaluation board.Evaluation Board SchematicsU1MIC5365/6-xxYMTJ5ENBill of MaterialsItem Part Number Manufacturer Description Qty.C1 C1608X5R0J106Z TDK (1) Capacitor, 10µF Ceramic, 6.3V, X5R, Size 0603 1 C2 GRM155R61A105KE15D Murata (2)Capacitor, 1µF Ceramic, 10V, X5R, Size 0402 1 R1 CRCW0603100KFKEA Vishay (3)Resistor, 100k Ω, 1%, 1/16W, Size 0603 1 U1 MIC5365/6-xxYMT Micrel, Inc.(4)High Performance Single 150mA LDO1Notes:1. TDK: 2. Murata: 3. Vishay: 4. Micrel, Inc.: Bill of MaterialsItem Part Number Manufacturer Description Qty.C1 C1608X5R0J106Z TDK (1) Capacitor, 10µF Ceramic, 6.3V, X5R, Size 0603 1 C2 GRM155R61A105KE15D Murata (2)Capacitor, 1µF Ceramic, 10V, X5R, Size 0402 1 R3 CRCW0603100KFKEA Vishay (3) Resistor, 100k Ω, 1%, 1/16W, Size 06031 U1 MIC5365/6-xxYC5 Micrel, Inc.(4)High Performance Single 150mA LDO1Notes:1. TDK: 2. Murata: 3. Vishay: 4. Micrel, Inc.: U1MIC5365/6-xxYC5J5 ENPCB Layout Recommendations (1mm x 1mm MLF®)Top LayerBottom LayerPCB Layout Recommendations (SC-70-5)Top LayerBottom Layer。

THIS PAGE INTENTIONALLY LEFT BLANKHMC976LP3E400mA LOW NOISE, HIGH PSRRLINEAR VOLTAGE REGULATORv02.1112General DescriptionFeaturesFunctional DiagramThe HMC976LP3E is a BiCMOS ultra low noiselinear voltage regulator. The high Power SupplyRejection Ratio (PSRR) in the 0.1 MHz to 10 MHzrange provides excellent rejection of any precedingswitching regulator or other power supply noise.The voltage output is ideal for frequency generationsubsystems including Hittite’s broad line of PLLs withintegrated VCOs.The output voltage can be adjusted lower than thedefault value by using one external resistor. The outputcan be set to 5V by grounding the HV pin. The regulatorcan be powered down by the TTL-compatible Enableinput. The HMC976LP3E is housed in a 3x3mm QFNSMT package.High Output Current: 400mALow Dropout: 300mV at 400mA Output and VR>3VUltra Low Noise: 3nV/√Hz at 10 kHz, 6nV/√Hz at 1 kHzHigh Power Supply Rejection Ratio (PSRR):<-60 dB at 1 kHz, <-30 dB at 1 MHzAdjustable Voltage Output: VR 1.8 to 5V at 400mADesigned to work with low ESR ceramic capacitorsLow Power-Down Current: <1 µAThermal Protection16 Lead 3x3 mm SMT Package: 9mm²Typical ApplicationsThe HMC976LP3E is ideal for:• Test Instrumentation• Military Radios, Radar and ECM• Basestation Infrastructure• Ultra Low Noise Frequency Generation• Fractional-N Synthesizer Supply• Microwave VCO Supply• Mixed-Signal Circuit Supply• Low Noise Baseband Circuit SupplyTable 1. Electrical Specifications, T A= +25 °C[1] See Absolute Maximum Ratings Table “Absolute Maximum Ratings”P O W E R C O N D I T I O N I N G - S M TLINEAR VOLTAGE REGULATORTable 1. Electrical Specifications(Continued)[1] The regulator does not include short-circuit protection circuitry. The outputs will withstand short-circuit conditions for a duration <10s. The thermal protection is not intended to be used as a short circuit protection[2] HMC976LP3E was designed to work with low ESR ceramic capacitors connected to pin 4 VRX. [3] See HMC976LP3E 5.0V User Application Schematic herein [4] See figures 14,15, and 16LINEAR VOLTAGE REGULATORFigure 1. Vout=5V Output Noise Spectral Density [1]Figure 2. Vout=3.3V Output Noise Spectral Density[2]10-1010-910-810-710-610-5101102103104105106107108N O I S E V O L T A G E (V /r t H z )FREQUENCY (Hz)C3=1uF C2=1uFC3=1uF C2=10uFC3=4.7uF C2 =4.7uF10-1010-910-810-710-610-5101102103104105106107108N O I S E V O L T A G E (V /r t H z )FREQUENCY (Hz)C3=4.7uF C2=4.7uFC3=4.7uF C2=10uF4.9504.9554.9604.9654.9704.9751.1501.1551.1601.1651.1701.175-40-30-20-100102030405060708090V O U T (V )VREF (V)TEMPERATURE (°C)VREFVRVIN-VOUT (V)INPUT VOLTAGE (V)-80-70-60-50-40-30-20102103104105106107108P S R R (d B )FREQUENCY (Hz)VIN-VOUT=0.4VVIN-VOUT=0.6VVIN-VOUT=0.8V-90-80-70-60-50-40-30-20102103104105106107108P S R R (d B )FREQUENCY (Hz)VIN-VOUT=0.25VVIN-VOUT=0.5VVIN-VOUT=0.8VVIN-VOUT=1.0VVIN-VOUT=1.7V[1] VDD=5.5V,400mA Load see “HMC976LP3E 5V User Application Schematic”[2] VDD=5.0V,400mA Load see “HMC976LP3E 3.3V User Application Schematic”[3] VDD=5.5V,400mA Load see “HMC976LP3E 4.8V User Application Schematic”.[4] Temperature is the ambient temperature of the standard HMC976LP3E evaluation board, still air.DROPOUT VOLTAGE VIN-VOUT (V) Figure 3. Vout 4.8V PSRR vs. Vin-Vout [3]Figure 4. Vout=3.3V PSRR vs. Vin-Vout [2]Figure 5. Vout=5V and Vref vs. Temperature [1,4]Figure 6. Vout=5V and Vref vs. [1,4]P O W E R C O N D I T I O N I N G - S M TLINEAR VOLTAGE REGULATOR4.884.924.965.005.045.08100200300400500-551015202530354045O U T P U T (V )CURRENT (mA)TIME (ms)CURRENTVR Output4.884.924.965.005.045.080100200300400500-551015202530354045O U T P U T (V )CURRENT (mA)TIME (ms)CURRENTVR Output 0.000.5001.001.502.002.503.003.504.000.000.5001.001.502.002.503.003.504.00-50050100150200250300350400450O U T P U T (V )ENA (V)TIME (ms)VR OutputENA0.000.5001.001.502.002.503.003.504.000.000.5001.001.502.002.503.003.504.00-0.2000.000.2000.4000.6000.800O U T P U T (V )ENA (V)TIME (s)VR OutputENA10-1010-910-810-710-610-5101102103104105106107108N O I S E V O L T A G E (V /r t H z )FREQUENCY (Hz)Commercial PSU Output Input to regulatorHMC976LP3E Output4.9504.9704.9905.0105.0305.050050100150200250300350400V O U T (V )LOAD CURRENT mA[1] VDD=5.5V, 400mA Load ““HMC976LP3E 5V User Application Schematic”.[2] VDD=5.0V, 400mA Load “HMC976LP3E 3.3V User Application Schematic”Figure 7. Output Load Switched OFF to ON [1]Figure 8. Output Load Switched ON to OFF [1]Figure 9. Supply Turn-On Transient [2]Figure 10. Supply Turn-Off Transient [2]Figure 11. HMC976LP3E Output Noise Spectral Density vs. Commercial PSU [1]Figure 12. Vout vs. Load current [1]LINEAR VOLTAGE REGULATOROutline Drawing[2] Max peak reflow temperature of 260 °C[3] For standard HMC976LP3E evaluation board, no heat sink (HS) and no air flow, see figures 14, 15, and 16Table 2. Absolute Maximum RatingsELECTROSTATIC SENSITIVE DEVICE OBSERVE HANDLING PRECAUTIONSTable 3. Recommended Operating ConditionStresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. The absolute maximum ratings apply individually only, not in combination.NOTES:[1] PACKAGE BODY MATERIAL: LOW STRESS INJECTION MOLDED PLASTICSILICA AND SILICON IMPREGNATED.[2] LEAD AND GROUND PADDLE MATERIAL: COPPER ALLOY.[3] LEAD AND GROUND PADDLE PLATING: 100% MATTE TIN.[4] DIMENSIONS ARE IN INCHES [MILLIMETERS].[5] LEAD SPACING TOLERANCE IS NON-CUMULATIVE.[6] PAD BURR LENG TH SHALL BE 0.15mm MAX. PAD BURR HEIG HT SHALLBE 0.25m MAX.[7] PACKAGE WARP SHALL NOT EXCEED 0.05mm[8] ALL G ROUND LEADS AND G ROUND PADDLE MUST BE SOLDERED TOPCB GROUND.[9] REFER TO HITTITE APPLICATION NOTE FOR SUG G ESTED PCB LANDPATTERN.Table 4. Package InformationP O W E R C O N D I T I O N I N G - S M TLINEAR VOLTAGE REGULATORTable 5. Pin DescriptionsLINEAR VOLTAGE REGULATOREvaluation PCBTable 6. Ordering InformationTable 7. List of Materials for Evaluation PCB 131671P O W E R C O N D I T I O N I N G - S M TLINEAR VOLTAGE REGULATOROperational FeaturesThe recommended configuration is “HMC976LP3E 4.8V User Application Schematic”. This is for the default output voltage of 4.8V nominal. The values shown are those recommended for optimum Noise Spectral density. For users requiring extremely low noise in the 1 MHz to 10 MHz range the largest output capacitor should be used: a 68uF takes the noise between 100 kHz and 1 MHz to below 2.5nV/√Hz.Load Capacitor CharacteristicsThe HMC976LP3E was designed to work with a low ESR ceramic load capacitor on the VRX pin (C21 in the schematic above). Low ESR ceramic capacitors are very small and best for eliminating high frequency noise. Ceramic capacitors can vary as much as 50% versus temperature and 60% versus voltage, dependant on the ceramic type e.g. Z5U, Y5V, X7R or X5R. There are no restrictions on ceramic type or minimum ESR, only that the user must guarantee that the minimum output capacitance over operating conditions is 4.7μF, smaller values can result in noise peaking or lower stability.Figure 13. Evaluation PCB SchematicLINEAR VOLTAGE REGULATOROutput Voltage AdjustmentThe default output voltage is 4.8V this configuration “HMC976LP3E 4.8V User Application Schematic”. The output voltage can be set to 5V by a ground on HV pin 5 “HMC976LP3E 5V User Application Schematic”. The output voltage can be set from 1.8V to <4.8V by a resistor from pin 2 to the output pin 11 shown in “HMC976LP3E 3.3V User Application Schematic”. The value of the resistor is given by the equation below.If the temperature stability performance similar to that shown in the plot “Vout=5V and Vref vs. Temperature” is required, then any external resistor temperature coefficient is a critical parameter and should be better than 50ppm and 1% tolerance. Please note that the temperature coefficient of the internal resistor feedback divider is 270ppm/°C.Layout of PCBThe layout of the PCB should follow these guide lines, the PADDLE should be connected to ground with at least 5 vias directly under the paddle to the bottom side ground plane. To ensure the noise and PSRR specifications are met, the capacitors connecting to Pins 15, 11, 3 (see user application schematics), should be placed as close as possible to the relevant pin and the ground connection should be as short as possible. Trace widths and via sizes should be scaled to match the current drawn. The use of a large ground plane is recommended with a large number of ground vias near the device to carry the ground.Thermal ProtectionThe HMC976LP3E includes an integrated thermal protection circuit. If the junction temperature of the HMC976LP3E reaches the maximum operating junction temperature (115°C max, 130°C typical) then the thermal protection circuit temporarily disables the HMC976LP3E outputs (with ~500uA output current) until the junction temperature cools down by approximately 10°C.A typical reason for the increase of the junction temperature is an unexpected increase in current draw. By disabling the outputs, the HMC976LP3E is in this case protecting the other devices on the PCB that it is supplying with current. The thermal protection circuitry will also indirectly protect against a short circuit at the output. After the overload or the fault condition is removed or changed, the regulator output returns to the nominal operationFor reliable long term operation the “Recommended Operating Condition” must be followed and the maximum junc-tion temperature must not be exceeded. The junction temperature for a given dissipation can be calculated from the equation below:Where Tj=Junction Temperature (°C), Ta=Ambient Temperature (°C), Pd=Dissipated Power (W) =Thermal Resistivity Junction to Ambient (°C/W). Please refer to Table 2 for thermal resistance values.⎟⎠⎞⎜⎝⎛−⎟⎠⎞⎜⎝⎛−⎟⎠⎞⎜⎝⎛−⎟⎠⎞⎜⎝⎛=117.1*32.019.18*117.11Vout Vout R(Kohms)T T P j a d ja=+×θθjaP O W E R C O N D I T I O N I N G - S M TLINEAR VOLTAGE REGULATORThermal dissipation should be taken into account at all times especially with large dropout voltages VDD-VR, i.e. if 1.8V output is required from 5.5V input voltage, then the output current must be restricted to <210mA , or VDD restricted to <3.75V for a 400mA load.The exact maximum operating temperature before the thermal protection circuit activates is largely dependent on the customer PCB design. Below is an example for maximum ambient temperature calculation for the standard HMC976LP3E evaluation PCB with no heat sink and no air flow (fans). Customers should perform this calculation for their PCB layout and operating conditions.VIN=5.5V, Vout=5.0V, Iout=400mA Vdropout=VIN-VOUT=0.5VDissipated power on regulator Pd=0.5Vx0.4A=0.2W =51.5°C/W Junction temperature increase using standard HMC976 board: DTj=Pd x =10.3°C. Thermal shutdown junction temperature of regulator (absolute min) Tsdwn=+115°C. Maximum corresponding ambient temperature Ta_max = Tsdwn - DTj = +104.7°CThe plots below show how the PCB ground copper area affects the HMC976LP3E junction temperature for different HMC976LP3E power dissipation conditions. The following cases are included in the plots:1. 100 mm 2 Copper Area2. 1000 mm 2 Copper Area3. 2580 mm 2 Copper Area HMC976LP3E Evaluation PCB No Heat Sink (HS)4. 2580 mm 2 Copper Area HMC976LP3E Evaluation PCB with Heat Sink (HS)5. JEDEC Board as per JESD51-3The typical corresponding is shown in Table 8:2550751001251500.10.20.30.40.50.60.70.80.91J U N C T I O N T E M P E R A T U R E T j (°C )POWER DISSIPATION (W)TjmaxJEDEC no HS2580mm 2with HS2580mm 2no HS1000mm 2no HS100mm 2no HS115°C WORST CASE THERMAL SHUTDOWN25507510012515000.10.20.30.40.50.60.70.80.91J U N C T I O N T E M P E R A T U R ET j (°C )POWER DISSIPATION (W)100mm 2no HS2580mm 2with HS2580mm 2no HS1000mm 2no HS TjmaxJEDEC no HS115°C WORST CASE THERMAL SHUTDOWNTable 8. Typical for specified PCB Copper Sizes θjaθja θjaFigure 14. HMC976LP3E JUNCTION TEMPERATURE °C vs. TOTAL POWER DISSIPATION 25°C AMBIENTFigure 15. HMC976LP3E JUNCTION TEMPERATURE °C vs. TOTAL POWER DISSIPATION 50°C AMBIENTθjaLINEAR VOLTAGE REGULATOR25507510012515000.10.20.30.40.50.60.70.80.91J U N C T I O N T E M P E R A T U R E T j (°C )POWER DISSIPATION (W)Tjmax1000mm 2no HS2580mm 2no HS2580mm 2with HS100 mm 2no HSJEDEC no HS115°C WORST CASE THERMAL SHUTDOWNFigure 16. HMC976LP3E JUNCTION TEMPERATURE °C vs. TOTAL POWER DISSIPATION 85°C AMBIENTFigure 17. HMC976LP3E 3.3V User Application SchematicP O W E R C O N D I T I O N I N G - S M TLINEAR VOLTAGE REGULATORFigure 18. HMC976LP3E 4.8V User Application SchematicFigure 19. HMC976LP3E 5V User Application Schematic。

Application Note SPICE Modeling ReportFor Automotive 150mA3.3 V / 5.0 V / Adjustable OutputLDO Regulators BD9xxN1-C SeriesGeneral DescriptionIn this report, the characteristics that can be confirmed by the simulation using the SPICE model of the LDO regulators IC BD9xxN1-C Series will be described.Simulation Environment◼Circuit Simulator: PSpice / Cadence Design System, Inc.◼Version Information: 17.4-2019◼OS Information : Windows 10 64-bit EditionFile Information◼Library File Name: BD900N1W.lib / BD933N1W.lib / BD950N1W.lib (with EN port): BD900N1.lib / BD933N1.lib / BD950N1.lib (without EN port)◼Symbol File Name: BD900N1W.olb / BD933N1W.olb / BD950N1W.olb (with EN port): BD900N1.olb / BD933N1.olb / BD950N1.olb (without EN port)◼Subcircuit and Symbol(Note 1) These Subcircuit are the spice macro model for DC and AC, transient simulation.Caution◼These models basically support the temperature characteristics.However, the simulation results with temperature variances may slightly differ from the result with the one done at actual application board (actual measurement).◼The values from the simulation results are not guaranteed. Use these results as a guide for your design.◼Actual measurement was done using a specific sample, thus the measured data is just as a reference.Symbol image and Pin definition, Model parameterSpice Model Symbol imageSpice Model ParameterTable 3 Model Parameter TableModeled Electrical CharacteristicsTable 4 Modeled Electrical CharacteristicsRevision HistoryNoticeROHM Customer Support System/contact/Thank you for your accessing to ROHM product informations.More detail product informations and catalogs are available, please contact us.N o t e sThe information contained herein is subject to change without notice.Before you use our Products, please contact our sales representative and verify the latest specifica-tions :Although ROHM is continuously working to improve product reliability and quality, semicon-ductors can break down and malfunction due to various factors.Therefore, in order to prevent personal injury or fire arising from failure, please take safety measures such as complying with the derating characteristics, implementing redundant and fire prevention designs, and utilizing backups and fail-safe procedures. ROHM shall have no responsibility for any damages arising out of the use of our Poducts beyond the rating specified by ROHM.Examples of application circuits, circuit constants and any other information contained herein areprovided only to illustrate the standard usage and operations of the Products. The peripheral conditions must be taken into account when designing circuits for mass production.The technical information specified herein is intended only to show the typical functions of andexamples of application circuits for the Products. ROHM does not grant you, explicitly or implicitly, any license to use or exercise intellectual property or other rights held by ROHM or any other parties. ROHM shall have no responsibility whatsoever for any dispute arising out of the use of such technical information.The Products specified in this document are not designed to be radiation tolerant.For use of our Products in applications requiring a high degree of reliability (as exemplifiedbelow), please contact and consult with a ROHM representative : transportation equipment (i.e. cars, ships, trains), primary communication equipment, traffic lights, fire/crime prevention, safety equipment, medical systems, servers, solar cells, and power transmission systems.Do not use our Products in applications requiring extremely high reliability, such as aerospaceequipment, nuclear power control systems, and submarine repeaters.ROHM shall have no responsibility for any damages or injury arising from non-compliance withthe recommended usage conditions and specifications contained herein.ROHM has used reasonable care to ensur e the accuracy of the information contained in thisdocument. However, ROHM does not warrants that such information is error-free, and ROHM shall have no responsibility for any damages arising from any inaccuracy or misprint of such information.Please use the Products in accordance with any applicable environmental laws and regulations,such as the RoHS Directive. For more details, including RoHS compatibility, please contact a ROHM sales office. ROHM shall have no responsibility for any damages or losses resulting non-compliance with any applicable laws or regulations.W hen providing our Products and technologies contained in this document to other countries,you must abide by the procedures and provisions stipulated in all applicable export laws and regulations, including without limitation the US Export Administration Regulations and the Foreign Exchange and Foreign Trade Act.This document, in part or in whole, may not be reprinted or reproduced without prior consent ofROHM.1) 2)3)4)5)6)7)8)9)10)11)12)13)。

说明书SpeedMixer DAC 150Z 仪器名称：SpeedMixer 型号：DAC150Z编号：13204目录：安全1.1标准使用1.2危险源1.3用户设置2.1打开SpeedMixer 2.2 运输保护2.3安装SpeedMixer 2.4电源连接仪器描述工作过程建议4.1初始操作4.2混合制备4.2.1设定转数4.2.2设定混合时间4.3设置混合杯4.4基本混合规则清洁和维护6.主要功能技术数据保证条款9.EU整合宣言安全1.1标准使用SpeedMixer 可用于混合糊状物和糊状物，糊状物与粉末，粉末和粉末等。

典型的产品如密封剂和涂层(如硅树脂,聚氨酯和丙烯酸树脂)、油漆、油墨和颜料。

此外,SpeedMixer{很好适合混合的两个或多组分液体和糊状物。

1.2危险源SpeedMixer正常使用时需要有完全的安全保证,使用不当易造成受伤的危险。

仪器工作时候不可打开上盖手动操作。

SpeedMixer不可混合爆炸易燃物。

混合机不应空运行或超重(> 150克)，影响平衡引起严重的振动和破坏。

总设备移动导致损害,甚至人员受伤。

SpeedMixer需要保证适合的混合量和合理的操作。

出于安全原因,我们参考的未经授权的贸易、技术变化包括软件参数值将导致到期保证通过制造商。

SpeedMixer线路设备的马达驱动配备电机频率调节器。

泄漏电流的频率监管机构复杂的个人安全供应系统,所以需要有频率监管。

与一个ac-de敏感的剩余电流断路器,其频率响应曲线协调的典型的泄漏电流,能达成个人安全。

VDE草案规定E VDE 0664部分100(简称RCD B型)和EN 50178。

技术原因:隔离的直流误差可以起源于频率调节器,将驱动变压器饱和商业剩余电流断路器的保护开关是严重影响在其功能进一步行过滤器创建安装地线中泄漏电流。

线过滤器是必需遵守法律要求EMV-safety测量(电磁兼容性。

无线interferencesl)。

PDE-150-118-28V Intelligent Automotive ITX Power Supply安装指导在您安装PPL-ITX到您的汽车前，请用仔细阅读这份手册。

通常，急着安装该电源会导致你的PPL-ITX板、电脑及你的汽车电力系统遭到严重损伤。

PPL-ITX板有几条线需要严格的确认后才能接到正确的插槽内。

当安装时，要再次用电压表测试你的电线的极性。

避免使用cigarette plug(点烟头）作为电的来源，通常这样的接触是不能确保传输高电流到你的PC上。

介绍谢谢您购买了PPL-ITX电源排序器/汽车ITX电源。

PDE-150-11是设计与广泛的主板一起使用的，除了Pentium-M Celeron和全能量的P4系统，还有VIA mini-ITX主板。

1.1PDE-150-11 Logic Diagram逻辑图表1.2 PDE-150-11 Connection diagram连接图表PDE-150-11, top view顶视图 1. 电源的输入接头J1电池+(un-switched电池，正极)J3点火(switched电池，正极。

连接到电池上可测试出+)J4电池-(负极)。

2. 控制与设置J6通过遥控ON/OFF控制扩音器.左pin是信号，右pin是地(接地) J8连至主板ON/OFF开关J10用户跳线设置(1,2,3)J9连至外部ON/OFF开关(可选，J8与J9并联)3. 电源输出接头J2可选P4-12V电源J7 ITX电源20P标准接头(连至主板)J5连至LED(可选)电源运行模式：注意：如果HARDOFF被设置为”never”, 当电池电压低于11.2V超过1分钟时，为了防止“深放电“情况的出现，PPL-ITX会自动关闭。

运行模式“0“是常规电源模式，相当普通ITX电源，使用于非机车设备。

同时尽量避免使用HARDOFF=Never运行模式，因为假设你长时间不使用汽车时这样会消耗光你汽车上电池的电能，建议使用模式1， 2， 和4。