ICS7152MI-11T中文资料

verviewWell-suited for low traffic areas, this unit is similar to the 0210 but reduced capacity to dispense 200 C-fold or 275 multi-fold paper towels without adjustment or adapters and is fitted with tumbler lock and heavy-duty stainless steel piano hinge.American Specialties, I nc. | 441 Saw Mill River Road, Yonkers, NY 10701 | (914) 476-9000 | Model:#0215Issued:11/1/2021Revised:3/10/2023Page:1 of 2Revision :R1uStainability /lEEDPaper Towel Dispenser - Petite (Multi - C-Fold) -Surface MountedToilet Accessories CSI:10 28 13MR 6 (1)EQ 4.1 (1)EQ 4.2 (1)EQ 4.4 (1)661_1O peratiOn & M aintenancet echnical i nfOrMatiOn / p rOduct p rOpertiesi nstallatiOnW arrantySurface mount unit on wall or partition using five #10 self-threading screws (by others) through concealed mounting holes provided. Four mounting holes through back are keyhole slots for ease in hanging unit on pre-installed screws. Center top mounting hole is horizontal slot for ease of adjustment and vandal resistant locking. For compliance with 2010 ADA Accessibility Standars install unit so that centerline of towel dispenser slot is 48" [1219] maximum above finished floor (AFF).Manufacturer reserves the right to make changes to the design, dimensions or functionality of the product without formal notice.Towels are self-feeding as withdrawn by hand until supply is depleted. Unit may be reloaded with a partial load in-place and will continue to feed properly. Low level of towel supply is indicated from 35% capacity to empty. Unit is a reduced-size model and has less capacity than larger models, therefore it is recommended to use this unit in space-restricted or low traffic areas. Locking door prevents unauthorized access or removal.One (1) Y ear from date of InvoiceAmerican Specialties, I nc. | 441 Saw Mill River Road, Yonkers, NY 10701 | (914) 476-9000 | Model:CSI:#021510 28 13Toilet Accessories Issued:11/1/2021Revised:3/10/2023Page:Revision :Type 304 Stainless Steel - Matte Black Powder Coated Concealed multi-staked hinge - 3/16" Dia. [Ø5]200 C-fold or 275 multi-fold paper towelsPropertyValueDimensions Construction 11" [279] W x 8" [203] H x 4" [102] DManual - Pull T ype Surface MountedN/A2 of 2R1Power Operation Mounting Capacity。

1US Headquarters TEL +(1) 781-935-4850FAX +(1) 781-933-4318 • Europe TEL +(44) 1628 404000FAX +(44) 1628 404090Asia Pacific TEL +(852) 2 428 8008FAX +(852) 2 423 8253South America TEL +(55) 11 3917 1099FAX +(55) 11 3917 0817Superior elongation and tensilestrength help to prevent tearing in use due to mishandling. Typical properties for CHO-SEAL 1310 and 1273 materi-al are shown on pages 33 and 32respectively.High Shielding PerformanceCHO-SEAL 1310 material provides more than 80 dB of shielding effectiv-ness from 100 MHz to 10 GHz, while CHO-SEAL 1273 material provides more than 100 dB.Low Volume ResistivityBoth materials have exceptionally low volume resistivity, which makes them well suited for grounding appli-cations in which a flexible electrical contact is needed.Low Compression GasketSpacer gaskets are typicallydesigned to function under low deflec-tion forces. Chomerics uses design tools such as Finite Element Analysis (FEA) to accurately predict compres-sion-deflection behavior of various cross section options. Refer to page16.LCP Plastic SpacerLiquid crystal polymer (LCP)spacers, including those made with Vectra A130 material, provide aCHO-SEAL ®1310 or 1273Conductive ElastomersWith EMI spacer gaskets, shielding and grounding are provided by Chomerics’CHO-SEAL 1310 and 1273 conductive elastomers, specifi-cally formulated for custom shape molded parts. They provide excellent shielding and isolation against electro-magnetic interference (EMI), or act as a low impedance ground path between PCB traces and shielding media. Physically tough, these elas-tomers minimize the risk of gasket damage, in contrast to thin-walled extrusions or unsupported molded gaskets.Silicone-based CHO-SEAL 1310and 1273 materials offer excellent resistance to compression set over a wide temperature range, resulting in years of continuous service. CHO-SEAL 1310 material is filled with silver-plated-glass particles, while 1273 utilizes silver-plated-copper filler to provide higher levels of EMI shielding effectiveness.EMI Spacer GasketsThe unique design of Chomerics’EMI spacer gaskets features a thin plastic retainer frame onto which a conductive elastomer is molded. The elastomer can be located inside or outside the retainer frame, as well as on its top and bottom surface. EMI spacer gaskets provide a newapproach to designing EMI gaskets into handheld electronics such as dig-ital cellular phones. Board-to-board spacing is custom designed to fit broad application needs. Customized cross sections and spacer shapes allow for very low closure forcerequirements and a perfect fit in any design or device.Robotic InstallationSpacer gaskets can be installed quickly by robotic application. Integral locater pins in the plastic spacer help ensure accuratepositioning in both manual and pick-and-place assembly. Benefits include faster assembly and lower labor costs.The integrated conductive elastomer/plastic spacer gasket is a low cost,easily installed system for providing EMI shielding and grounding in small electronic enclosures.Figure 1Single Piece EMI Gasket/Locator PinsCHO-SEAL 1310 or 1273 Conductive Elastomer (Inside)Plastic Spacer Around Outsideor InsideApplications for EMI Spacer GasketsThe spacer gasket concept is especially suited to digital and dual board telephone handsets or other handheld electronic devices. It provides a low impedance path between peripheral ground traces on printed circuit boards and components such as:•the conductive coating on a plastic housing•another printed circuit board •the keypad assemblyTypical applications for EMI spacer gaskets include:•Digital cellular, handyphone and personal communications services (PCS) handsets •PCMCIA cards•Global Positioning Systems (GPS)•Radio receivers•Other handheld electronics, e.g.,personal digital assistants (PDAs)•Replacements for metal EMI shield-ing “fences” on printedcircuit boards in wireless tele-communications devicesstable platform for direct, highprecision molding of conductive elas-tomers. The Vectra A130 material described in Table 1 has excellent heat deflection temperature character-istics (489°F, 254°C). For weight con-siderations, the LCP has aspecific gravity of only 1.61. This plas-tic is also 100% recyclable.Typical EMI Spacer Gasket Design ParametersThe EMI spacer gasket concept can be considered using the design parameters shown in Table 2. Some typical spacer gasket profiles are shown below.Figure 2Typical Spacer Gasket Profiles3US Headquarters TEL +(1) 781-935-4850FAX +(1) 781-933-4318 • Europe TEL +(44) 1628 404000FAX +(44) 1628 404090Asia Pacific TEL +(852) 2 428 8008FAX +(852) 2 423 8253South America TEL +(55) 11 3917 1099FAX +(55) 11 3917 0817Finite Element AnalysisChomerics, a division of the Parker Hannifin Corporation’s Seal Group, is the headquarters of Parker Seal’s Elastomer Simulation Group. This unit specializes in elastomer finite element analysis (FEA) using MARC K6 series software as a foundation for FEA capability.Benefits of FEA include:•Quickly optimizing elastomer gasket designs•Allowing accurate predictions of alternate elastomer design concepts •Eliminating extensive trial and error prototype evaluationTypical use of FEA in EMI spacer gasket designs is to evaluate the force vs. deflection requirements of alternate designs.For example, onespacer design features a continuous bead of con-ductive elastomer molded onto a plastic spacer. An alternative designemploys an “interrupted bead,” where the interrup-tions (gaps left on the plastic frame) are sized to maintain the requiredlevel of EMI shielding. Figure 4illustrates these alternative designs.Gasket DeflectionFigure 5 compares the effect of continuous and interrupted elastomer gasket designs in terms of the force required to deflect the conductive elastomer. This actual cellular handset application required a spacer gasket with interrupted bead to meet desired deflection forces.Chomerics Designand Application ServicesChomerics will custom design a spacer for your application. Advice,analysis and design assistance will be provided by Chomerics Applications and Design engineers at no additional fee. Contact Chomerics directlyat the locations listed at the bottom of the page.Figure 3FEA Example of an EMISpacer Gasket Cross SectionFigure 4Continuous (top) and InterruptedElastomer GasketsFigure 5Typical Spacer Gasket Deflection。

电子元器件的质量等级汇总整理张增照1........................................................................................................................... 元器件质量保证有关标准31.1............................................................................................................................... 规范31.2............................................................................................................................... 标准42......................................................................................................................................... 可靠性表征方式52.1..................................................................................................... 元件的失效率等级52.2............................................................................................................. 产品保证等级63...................................................................................................................................... 元器件的质量认证74...................................................................................................................................... 元器件的质量等级74.1................................................ 用于元器件生产控制、选择和采购的质量等级74.2用于电子设备可靠性预计的质量等级 (9)4.3元器件两种质量等级的比较 (9)5元器件的选用与质量标记 (17)5.1元器件的选用 (17)5.2质量标记 (19)6结束语 (20)1元器件质量保证有关标准为了保证军用元器件的质量，我国制订了一系列的元器件标准。

PCI-EXPRESS CLOCK SOURCEDescriptionThe ICS557-01 is a clock chip designed for use inPCI-Express Cards as a clock source. It provides a pair of differential outputs at 100 MHz in a small 8-pin SOIC package.Using IDT’s patented Phase-Locked Loop (PLL) techniques, the device takes a 25 MHz crystal input and produces HCSL (Host Clock Signal Level) differential outputs at 100 MHz clock frequency. LVDS signal levels can also be supported via an alternative termination scheme.Features•Supports PCI-Express TM HCSL Outputs0.7 V current mode differential pair •Supports LVDS Output Levels•Packaged in 8-pin SOIC•RoHS 5 (green ) or RoHS 6 (green and lead free) compliant packaging•Operating voltage of 3.3 V•Low power consumption•Input frequency of 25 MHz•Short term jitter 100 ps (peak-to-peak)•Output Enable via pin selection•Industrial temperature range availableBlock DiagramPin Assignment Pin DescriptionsPin NumberPinNamePinTypePin Description1OE Input Output Enable signal(H = outputs are enabled, L = outputs are disabled/tristated).Internal pull-up resistor.2X1Input Crystal or clock input. Connect to a 25 MHz crystal or single ended clock. 3X2XO Crystal Connection. Connect to a parallel mode crystal.Leave floating if clock input.4GND Power Connect to ground.5IREF Output A 475Ω precision resistor connected between this pin and groundestablishes the external reference current.6CLK Output HCSL differential complementary clock output.7CLK Output HCSL differential clock output.8VDD Power Connect to +3.3 V.Applications Information External ComponentsA minimum number of external components are required for proper operation.Decoupling CapacitorsDecoupling capacitors of 0.01 μF should be connected between VDD and the ground plane (pin 4) as close to the VDD pin as possible. Do not share ground vias between components. Route power from power source through the capacitor pad and then into IDT pin.CrystalA 25 MHz fundamental mode parallel resonant crystal with C L = 16 pF should be used. This crystal must have less than 300 ppm of error across temperature in order for theICS557-01 to meet PCI Express specifications.Crystal CapacitorsCrystal capacitors are connected from pins X1 to ground and X2 to ground to optimize the accuracy of the output frequency.C L= Crystal’s load capacitance in pFCrystal Capacitors (pF) = (C L- 8) * 2For example, for a crystal with a 16 pF load cap, each external crystal cap would be 16 pF. (16-8)*2=16.Current Source (Iref) Reference Resistor - R RIf board target trace impedance (Z) is 50Ω, then R R = 475Ω(1%), providing IREF of 2.32 mA. The output current (I OH) is equal to 6*IREF.Output TerminationThe PCI-Express differential clock outputs of the ICS557-01 are open source drivers and require an external series resistor and a resistor to ground. These resistor values and their allowable locations are shown in detail in thePCI-Express Layout Guidelines section.The ICS557-01can also be configured for LVDS compatible voltage levels. See the LVDS Compatible Layout Guidelines sectionGeneral PCB Layout RecommendationsFor optimum device performance and lowest output phase noise, the following guidelines should be observed.1. Each 0.01µF decoupling capacitor should be mounted on the component side of the board as close to the VDD pin as possible.2. No vias should be used between decoupling capacitor and VDD pin.3. The PCB trace to VDD pin should be kept as short as possible, as should the PCB trace to the ground via. Distance of the ferrite bead and bulk decoupling from the device is less critical.4. An optimum layout is one with all components on the same side of the board, minimizing vias through other signal layers (any ferrite beads and bulk decoupling capacitors can be mounted on the back). Other signal traces should be routed away from the ICS557-01.This includes signal traces just underneath the device, or on layers adjacent to the ground plane layer used by the device.PCI-Express Layout GuidelinesFigure 1: PCI-Express Device RoutingTypical PCI-Express (HCSL) WaveformLVDS Compatible Layout GuidelinesFigure: LVDS Device RoutingTypical LVDS WaveformAbsolute Maximum RatingsStresses above the ratings listed below can cause permanent damage to the ICS557-01. These ratings are stress ratings only. Functional operation of the device at these or any other conditions above those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods can affect product reliability. Electrical parameters are guaranteed only over the recommended operating temperature range.DC Electrical CharacteristicsUnless stated otherwise, VDD = 3.3 V ±5%, Ambient Temperature -40 to +85°C1 Single edge is monotonic when transitioning through region.2 Inputs with pull-ups/-downs are not included.ItemRatingSupply Voltage, VDD, VDDA 5.5 VAll Inputs and Outputs-0.5 V to VDD+0.5 V Ambient Operating Temperature (commercial)0 to +70°C Ambient Operating Temperature (industrial)-40 to +85°C Storage Temperature -65 to +150°C Junction Temperature 125°C Soldering Temperature 260°CESD Protection (Input)2000 V min. (HBM)ParameterSymbolConditions Min.Typ.Max.UnitsSupply Voltage V 3.135 3.465Input High Voltage 1V IH 2.0VDD +0.3V Input Low Voltage 1V IL VSS-0.30.8V Input Leakage Current 2I IL 0 < Vin < VDD-55μA Operating Supply Current I DD With 50Ω and 2 pF load 55mA I DDOE OE =Low35mA Input Capacitance C IN Input pin capacitance 7pF Output Capacitance C OUT Output pin capacitance 6pF Pin Inductance L PIN 5nH Output Resistance Rout CLK outputs 3.0k ΩPull-up ResistorR PUPOE60k ΩAC Electrical Characteristics - CLK/CLKUnless stated otherwise, VDD=3.3 V ±5%, Ambient Temperature -40 to +85°C1 Test setup is R L =50 ohms with2 pF , R R = 475Ω (1%).2 Measurement taken from a single-ended waveform.3 Measurement taken from a differential waveform.4Measured at the crossing point where instantaneous voltages of both CLKOUT and CLKOUT are equal.5 CLKOUT pins are tri-stated when OE is low asserted. CLKOUT is driven differential when OE is high.Thermal Characteristics (8-pin SOIC)ParameterSymbolConditions Min.Typ.Max.UnitsInput Frequency 25MHz Output Frequency 100MHzOutput High Voltage 1,2V OH 660700850mV Output Low Voltage 1,2V OL-150027mV Crossing Point Voltage 1,2Absolute250350550mV Crossing Point Voltage 1,2,4Variation over all edges140mV Jitter, Cycle-to-Cycle 1,380ps Rise Time 1,2t OR From 0.175 V to 0.525 V 175332700ps Fall Time 1,2t OFFrom 0.525 V to 0.175 V175344700ps Rise/Fall Time Variation 1,2125ps Duty Cycle 1,34555%Output Enable Time 5All outputs 30µs Output Disable Time 5All outputs30µs Stabilization Time t STABLEFrom power-up VDD=3.3 V3.0ms Spread Change Timet SPREAD Settling period after spread change3.0msParameterSymbolConditionsMin.Typ.Max.UnitsThermal Resistance Junction to AmbientθJA Still air150°C/W θJA 1 m/s air flow 140°C/W θJA 3 m/s air flow120°C/W Thermal Resistance Junction to CaseθJC40°C/WMarking Diagram (ICS557M-01LF) Marking Diagram (ICS557MI-01LF)Notes:1. ###### is the lot code.2. YYWW is the last two digits of the year, and the week number that the part was assembled.3. “L ” designates Pb (lead) free packaging.4. “I” denotes industrial temperature.5. Bottom marking: (orgin). Origin = country of origin if not USA.Package Outline and Package Dimensions (8-pin SOIC, 150 Mil. Narrow Body) Package dimensions are kept current with JEDEC Publication No. 95Ordering InformationPart / Order Number Marking Shipping Packaging Package Temperature 557M-01LF See Page 8Tubes8-pin SOIC0 to +70° C557M-01LFT Tape and Reel8-pin SOIC0 to +70° C557MI-01LF Tubes8-pin SOIC-40 to +85° C557MI-01LFT Tape and Reel8-pin SOIC-40 to +85° C"LF" suffix to the part number are the Pb-Free configuration and are RoHS compliant.While the information presented herein has been checked for both accuracy and reliability, Integrated Device Technology (IDT) assumes no responsibility for either its use or for the infringement of any patents or other rights of third parties, which would result from its use. No other circuits, patents, or licenses are implied. This product is intended for use in normal commercial applications. Any other applications such as those requiring extended temperature range, high reliability, or other extraordinary environmental requirements are not recommended without additional processing by IDT. IDT reserves the right to change any circuitry or specifications without notice. IDT does not authorize or warrant any IDT product for use in life support devices or critical medical instruments.Corporate HeadquartersIntegrated Device Technology, For Sales800-345-7015408-284-8200Fax: 408-284-2775For Tech Support/go/clockhelpInnovate with IDT and accelerate your future networks. Contact:www.IDT .com。

®715Volt/mA Calibrator说明书 简介Fluke 715伏特/毫安校准仪 (Volt/mA Calibrator) 是一个伏特/毫安源及测量工具，用于 0到 24毫安的电流回路和 0到 20/25 V的直流电压测试上。

本校准仪不能同时用作输出和测量上。

您的校准仪应包括以下附件：皮套、一对测试导线、已经安装的9 V碱电池、以及本说明书。

校准仪功能摘要功能量程分辨率直流毫伏输入0 到 200 mV 0.01 mV直流毫伏输出到 25 V直流电压输入 00.001 V直流电压输出0 到 20 V直流毫安输入0 到 24 mA 0.001 mA直流毫安输出回路电源输出24 V dc 输出不适用PN 650314 (Simplified Chinese) July 1997 Rev. 3, 8/051997-2005 Fluke Corporation. All rights reserved. Printed in U.S.A.All product names are trademarks of their respective companies.若校准仪有损坏或缺少某些附件，请立即与采购的地方联系。

有关附件的资料，请和您的Fluke 经销商联系。

欲订购零件或备件，请参阅“更换零件”。

要和Fluke 联系，请打电话：通讯地址：Fluke Corporation Fluke Europe B.V. P.O. Box 9090, P.O. Box 1186, Everett, WA 98206-9090 5602 BD Eindhoven U.S.A.（美国） The Netherlands （荷兰）或向我们的全球网址查询，地址是：国际符号符号含义J 接地 I 保险丝 M 电池W 有关本项功能的资料，请参阅本说明书。

T双重绝缘$符合 Canadian Standards Association 的相关指令。

ICS7152ASpread Spectrum Clock GeneratorDescriptionThe ICS7152A-02 and -11 are clock generators for EMI (Electromagnetic Interference) reduction (see below for frequency ranges and multiplier ratios). Spectral peaks are attenuated by modulating the system clock frequency. Down or center spread profiles areselectable. Down spread will not exceed the maximum frequency of an unspread clock, and center spread does not change the average operating frequency of the systemICS offers many other clocks for computers andcomputer peripherals. Consult ICS when you need to remove crystals and oscillators from your board.Features•Operating voltage of 3.3 V ±0.3 V •Packaged in 8-pin SOIC•Input frequency range of 16.6 to 134.0 MHz •Output frequency range of 16.6 to 134.0 MHz •Provides a spread spectrum clock output (±0.5%, ±1.5% center spread; -1.0%, -3.0% down spread)•Low cycle-to-cycle jitter - less than 100 ps •Advanced, low-power CMOS process •Industrial and commercial temperature ranges •Available in Pb (lead) free package•Pin compatible with Fujitsu MB88152-102 and -111Block DiagramProduct LineupProductInput Frequency RangeModulation TypeModulation Enable PinICS7152AM-02, ICS7152AMI-0240.0 MHz to 134.0 MHz Down spread Y esICS7152AM-11, ICS7152AMI-1116.6 MHz to 67.0 MHzCenter spreadSpread Spectrum Clock GeneratorModulation Enable Select TableSpread Direction and Percentage Select TableFrequency Select TablePin DescriptionsXENS Pin 8Modulation 0Modulation 1No modulationSEL Pin 4Spread DirectionSpread Percentage (%)Part Number0Center ±0.5ICS7152AM-11Down-1.0ICS7152AM-021Center ±1.5ICS7152AM-11Down-3.0ICS7152AM-02FREQ Pin 7Frequency016.6 to 40 MHz ICS7152AM-1140 to 80 MHzICS7152AM-02133 to 67 MHz ICS7152AM-1166 to 134 MHzICS7152AM-02Pin NumberPin NamePin TypePin Description1XIN Input Crystal/clock input pin.2XOUT Output Crystal.3GND Power Connect to ground.4SEL Input Spread modulation select.5CKOUT Output Spread modulation select.6VDD Power Connect to +3.3 V.7FREQ Input Frequency select.8XENSOutputModulation enable select.Spread Spectrum Clock GeneratorExternal ComponentsThe ICS7152A requires a minimum number of external components for proper operation.Decoupling CapacitorA decoupling capacitor of 0.01µF must be connected between GND and VDD on pins 3 and 6, as close to these pins as possible. For optimum device performance, the decoupling capacitor should be mounted on the component side of the PCB. Avoid the use of vias in the decoupling circuit.Series Termination ResistorSeries termination should be used on the clock output. To series terminate a 50Ω trace (a commonly used trace impedance) place a 27Ω resistor in series with the clock line, as close to the clock output pin as possible. The nominal impedance of the clock output is 25Ω.PCB Layout RecommendationsFor optimum device performance and lowest output phase noise, the following guidelines should be observed.1) The 0.01µF decoupling capacitor should be mounted on the component side of the board as close to the VDD pin as possible. No vias should be used between the decoupling capacitor and VDD pin. The PCB trace to VDD pin should be kept as short as possible, as should the PCB trace to the ground via.2) To minimize EMI, the 27Ω series termination resistor (if needed) should be placed close to the clock output.3) An optimum layout is one with all components on the same side of the board, minimizing vias through other signal layers. Other signal traces should be routed away from the ICS7152A. This includes signal traces just underneath the device, or on layers adjacent to the ground plane layer used by the device.Crystal InformationThe crystal used should be a fundamental mode, parallel resonant. Crystal capacitors should be connected from pins X1 to ground and X2 to ground to optimize the initial accuracy. The value of these capacitors is given by the following equation:Crystal caps (pF) = (C L - 6) x 2In the equation, C L is the crystal load capacitance. So, for a crystal with a 16 pF load capacitance, two 20 pF [(16-6) x 2] capacitors should be used.Spread Spectrum ProfileThe ICS7152A low EMI clock generator uses a triangular frequency modulation profile for optimal down stream tracking of zero delay buffers and other PLL devices. The frequency modulation amplitude is constant with variations of the input frequency.Spread Spectrum Clock GeneratorAbsolute Maximum RatingsStresses above the ratings listed below can cause permanent damage to the ICS7152A. These ratings, which are standard values for ICS commercially rated parts, are stress ratings only. Functional operation of the device at these or any other conditions above those indicated in the operational sections of thespecifications is not implied. Exposure to absolute maximum rating conditions for extended periods can affect product reliability. Electrical parameters are guaranteed only over the recommended operating temperature range.Recommended Operation ConditionsItemRatingSupply Voltage, VDD-0.5 to 4.0 VAll Inputs and Outputs (referenced to GND)-0.5 V to VDD+0.5 V Ambient Operating Temperature -40 to +85°C Storage Temperature -55 to +125°C Junction Temperature -40 to +125°C Soldering Temperature 260°COvershoot (V IOVER )VDD + 1.0 V (t OVER < 50 ns) max Undershoot (V IUNDER )GND - 1.0 V (t UNDER < 50 ns) minParameterMin.Typ.Max.UnitsAmbient Operating Temperature-40+85°C Power Supply Voltage (measured in respect to GND)+3.03.33.6VSpread Spectrum Clock GeneratorDC Electrical CharacteristicsUnless stated otherwise, VDD = 3.3 V ±0.3 V, Ambient Temperature -40 to +85°CParameter Symbol Conditions Min.Typ.Max.Units Operating Voltage VDD 3.0 3.3 3.6VSupply Current IDD No load, at 3.3 V,output = 24 MHz1014mAInput High Voltage V IH SEL, FREQ, XENS VDD x 0.8VDD + 0.3V XIN, Input slew rate3 V/ns, 16.6 to 100MHzVDD x 0.8VDD + 0.3VXIN, Input slew rate3 V/ns, 100 to 134MHzVDD x 0.9VDD + 0.3VInput Low Voltage V IL SEL, FREQ, XENS GND VDD x 0.20V XIN, Input slew rate3 V/ns, 16.6 to 100MHzGND VDD x 0.20VXIN, Input slew rate3 V/ns, 100 to 134MHzGND VDD x 0.10VOutput High Voltage V OH CKOUT, I OH = -4 mA VDD - 0.5VDD V Output Low Voltage V OL CKOUT, I OL = 4 mA GND0.4V Input Capacitance C IN XIN, SEL, XENS16pFLoad Capacitance C L CKOUT, 16.6 to 67MHz15pFCKOUT, 67 to 100MHz10pFCKOUT, 100 to 134MHz7pFOutput Impedance Z O CKOUT, 16.6 to 134MHz 25ΩSpread Spectrum Clock GeneratorAC Electrical CharacteristicsUnless stated otherwise, VDD = 3.3 V ±0.3 V , Ambient Temperature -40 to +85° CNote 1: Contact ICS Applications for more information.ParameterSymbolConditionsMin.Typ.Max.UnitsOscillation Frequencyf XXIN, XOUT, Fundamental oscillation16.640MHzXIN, XOUT, 3rd over tone, note 14048MHz Input Frequency f IN XIN, ICS7152A-1116.667MHz XIN, ICS7152A-0240134MHz Output Frequency f OUT CKOUT , ICS7152A-1116.667MHz CKOUT , ICS7152A-0240134MHz Input Clock Duty Cycle t DCI XIN, 16.6 to 100 MHz 405060%XIN, 100 to 134 MHz 455055%Output Clock Duty Cycle t DCCCKOUT , 1.5 V4060%Output Slew Rate CKOUT , 0.4 to 2.4 V , load capacitance 15 pF0.5TBD 3.0V/ns Cycle to Cycle Jitter t JC No load, standard deviation TBD 100ps Lock Timet LK CKOUT 25ms Modulation Frequencyf MODCKOUT=TBD33kHzSpread Spectrum Clock GeneratorInput Frequency (f IN = 1/t IN )Output Slew RateThermal CharacteristicsParameterSymbolConditionsMin.Typ.Max.UnitsThermal Resistance Junction to AmbientθJAStill air 150°C/W θJA 1 m/s air flow 140°C/W θJA 3 m/s air flow120°C/W Thermal Resistance Junction to CaseθJC40°C/WPackage dimensions are kept current with JEDEC Publication No. 95Spread Spectrum Clock GeneratorOrdering InformationParts that are ordered with a “LF” suffix to the part number are the Pb-Free configuration and are RoHS compliant.While the information presented herein has been checked for both accuracy and reliability, Integrated Circuit Systems (ICS) assumes no responsibility for either its use or for the infringement of any patents or other rights of third parties, which would result from its use. No other circuits, patents, or licenses are implied. This product is intended for use in normal commercial applications. Any other applications such as those requiring extended temperature range, high reliability, or other extraordinary environmental requirements are not recommended without additional processing by ICS. ICS reserves the right to change any circuitry or specifications without notice. ICS does not authorize or warrant any ICS product for use in life support devices or critical medical instruments.Part / Order NumberMarkingShipping PackagingPackageTemperatureICS7152AM-027152AM02Tubes 8-pin SOIC 0 to +70° C ICS7152AM-02T 7152AM02Tape and Reel8-pin SOIC 0 to +70° C ICS7152AM-02LF 152AM02L Tubes 8-pin SOIC 0 to +70° C ICS7152AM-02LFT 152AM02L Tape and Reel8-pin SOIC 0 to +70° C ICS7152AMI-02152AMI02Tubes 8-pin SOIC -40 to +85° C ICS7152AMI-02T 152AMI02Tape and Reel8-pin SOIC -40 to +85° C ICS7152AMI-02LF 52AMI02L Tubes 8-pin SOIC -40 to +85° C ICS7152AMI-02LFT 52AMI02L Tape and Reel8-pin SOIC -40 to +85° C ICS7152AM-117152AM11Tubes 8-pin SOIC 0 to +70° C ICS7152AM-11T 7152AM11Tape and Reel8-pin SOIC 0 to +70° C ICS7152AM-11LF 152AM11L Tubes 8-pin SOIC 0 to +70° C ICS7152AM-11LFT 152AM11L Tape and Reel8-pin SOIC 0 to +70° C ICS7152AMI-11152AMI11Tubes 8-pin SOIC -40 to +85° C ICS7152AMI-11T 152AMI11Tape and Reel8-pin SOIC -40 to +85° C ICS7152AMI-11LF 52AMI11L Tubes 8-pin SOIC -40 to +85° C ICS7152AMI-11LFT52AMI11LTape and Reel8-pin SOIC-40 to +85° CRevision HistoryRev.Originator Date Description of ChangeA J. Sarma10/20/05Rev A; new device/datasheet.。

STPTIC-15L2C4WLCSP 3 solder barsPTICRF1Features•High power capability •5:1 tuning range •High linearity (48x)•High quality factor (Q)•Low leakage current•Compatible with high voltage control IC (STHVDAC series)•RF tunable passive implementation in mobile phones to optimize antenna radiated performance•Available in wafer level chip scale package:–WLCSP package 0.75 x 0.72 x 0.32 mm •ECOPACK ®2 compliant componentApplications•Cellular antenna open loop tunable matching network in multi-band GSM/WCDMA/LTE mobile phone •Open loop tunable RF filtersDescriptionThe ST integrated tunable capacitor offers excellent RF performance, low power consumption and high linearity required in adaptive RF tuning applications. Thefundamental building block of PTIC is a tunable material called Parascan™, which is a version of barium strontium titanate (BST) developed by Paratek microwave.BST capacitors are tunable capacitors intended for use in mobile phone application and dedicated to RF tunable applications. These tunable capacitors are controlled through an extended bias voltage ranging from 1 to 24 V. The implementation of BST tunable capacitor in mobile phones enables significant improvement in terms of radiated performance making the performance almost insensitive to the external environment.Parascan is a trademark of Paratek Microwave Inc.Parascan™ tunable integrated capacitorSTPTIC-15C4DatasheetSTPTIC-15C4STPTIC-15C4 characteristics 1STPTIC-15C4 characteristicsTable 1. Absolute maximum ratings (limiting values)1.Class 1B defined as passing 500 V, but fails after exposure to 1000V ESD pulse.Table 2. Recommended operating conditionsTable 3. Representative performance (T amb = 25 °C otherwise specified)1.Measured at low frequency2.F 1 = 894 MHz, F 2 = 849 MHz, P 1 = +25 dBm, P 2 = +25 dBm, 2f 1 - f 2 = 939 MHz3.IP3 and harmonics are measured in the shunt configuration in a 50 Ω environment4.850 MHz, P IN = +34 dBm5.One or both of RF IN and RF OUT must be connected to DC ground, using the HVDAC turbo mode. Transition time for tunerbetween Cmin. to 90% of Cmax. or Cmax. to 90% of Cmin. include MIPI order work time (trig with last MIPI CLK).1.1RF measurementsFigure 3. Harmonic power versus bias voltage (shunt)Figure 4. Harmonic power versus bias voltage (series)STPTIC-15C4RF measurementsFigure 5.Third order intercept point (IP3)STPTIC-15C4RF measurements2Package informationIn order to meet environmental requirements, ST offers these devices in different grades of ECOPACK®packages, depending on their level of environmental compliance. ECOPACK® specifications, grade definitionsand product status are available at: . ECOPACK® is an ST trademark.2.1WLCSP 3 solder bars package informationFigure 8. WLCSP 3 solder bars package outlineBottom view(balls up)Top view(balls down)Side view Table 4. WLCSP 3 solder bars package dimensionsSTPTIC-15C4Package informationSTPTIC-15C4WLCSP 3 solder bars package informationFigure 9. Recommended PCB land pattern for WLCSP 3 solder bars package Copper pads Solder stencilTable 5. Dimensions2.2Packing informationFigure 10. Tape and reel outlineTable 6. Pocket dimensionsFigure 11. MarkingTop view (balls down)Bottom view (balls up)STPTIC-15C4Packing informationSTPTIC-15C4Reflow profileTable 7. Pinout description1.When connected in shunt, please connect RF2 (B2 ball) to GND2.3Reflow profileFigure 12. ST ECOPACK® recommended soldering reflow profile for PCB mountingNote:Minimize air convection currents in the reflow oven to avoid component movement.Table 8. Recommended values for soldering reflow3Evaluation boardFigure 14.Layer 1 and layer 4Figure 15. Layer 2 and layer 3RFinRFoutDC BiasSerie RFinRFoutDC BiasSHUNTSTPTIC-15C4Evaluation board4Ordering informationFigure 16. Ordering information schemeST PTIC - 15 L 2 C4ST MicroelectronicsPTICParascan™ tunableIntegrated capacitorCapacitorvalueLinearityF: Standard (x24)G: Standard (x24)L: High (x48)PackageTuning15 = 1.5 pF27 = 2.7 pF33 = 3.3 pF39 = 3.9 pF47 = 4.7 pF56 = 5.6 pF68 = 6.8 pF82 = 8.2 pFM6 : QFNC5 : WLCSP400 µm coating1 = 4/1 tuning2 = 5/1 tuningProduct familyManufacturer-C4 : WLCSP3 solder barsTable 9. Ordering informationOrdering informationRevision historyTable 10. Document revision historyIMPORTANT NOTICE – PLEASE READ CAREFULLYSTMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, enhancements, modifications, and improvements to ST products and/or to this document at any time without notice. Purchasers should obtain the latest relevant information on ST products before placing orders. ST products are sold pursuant to ST’s terms and conditions of sale in place at the time of order acknowledgement.Purchasers are solely responsible for the choice, selection, and use of ST products and ST assumes no liability for application assistance or the design of Purchasers’ products.No license, express or implied, to any intellectual property right is granted by ST herein.Resale of ST products with provisions different from the information set forth herein shall void any warranty granted by ST for such product.ST and the ST logo are trademarks of ST. All other product or service names are the property of their respective owners.Information in this document supersedes and replaces information previously supplied in any prior versions of this document.© 2018 STMicroelectronics – All rights reservedSTPTIC-15L2C4。

带内部开关的1A LED驱动器一般说明FP7152是一种连续电流模式感应降压转换器。

它可以驱动单个或多个串联LED。

FP7152包括输出开关和高压侧输出电流传感电路，使用外部电阻器设置平均输出电流。

输出电流也可以通过对“ADJ”引脚施加外部信号来调整。

ADJ引脚接受直流电压或PWM调光波形。

PWM调光滤波器组件包含在芯片内。

在ADJ引脚上施加低于0.2V的电压将关闭输出。

FP7152在SOT89-5L封装中提供，它节省的空间占用了小PCB面积，可用于各种应用领域。

特征●1A输出电流●内部0.5Ω26V功率MOSFET开关●宽7至26V工作输入范围●20μA关机模式电流●典型的4%输出电流精度●信号管脚开/关及亮度控制●可调软启动●效率高达95%●高达1MHz的开关频率●内部调光过滤器●SOT89-5L包装应用芯片135代2845理8039 Mr。

郑，工程FAE●低压卤素替代LED●LED备用照明应用电路功能描述操作FP7152是一个连续模式感应降压转换器，易于配置在不同的应用范围从7V到26V输入。

该转换器采用高侧电流敏感电阻RS来检测和调节LED电流。

电流传感电阻器上的电压保持在100mV±15mV范围内测量和调节。

内部1.25V参考电压用于提供0.25V参考电压以启用部件，并提供1.25V上拉电压作为电流参考电压。

当VADJ>0.25V时，比较器的输出变高，其他模块启用。

当第一次施加输入电压VIN时，L1和RS中的初始电流为零，电流检测电路没有输出。

在这种情况下，比较器的输出很高。

这将打开一个内部开关并将SW引脚切换到低电平，从而使电流通过RS、L1和LED从VIN流向地面。

电流以VIN和L1确定的速率上升，从而在RS上产生电压斜坡。

当（VIN-VSENSE）>115mV时，比较器的输出切换到低，并将LX引脚输出转换为高阻抗状态。

然后流经RS的电流以另一个速率减小。

当（VIN-VSENSE）<85mV时，LX 开关再次打开，LED上的平均电流为100mV/RS。

T e s t & M e a s u r e m e n tD a t a S h e e t | 03.00R&S®ESCI/ESCI7 EMI Test Receiver Specifications 800-404-ATEC (2832)e d 1981Version 03.00, June 20092 Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test ReceiverSpecificationsSpecifications apply under the following conditions: 15 minutes warm-up time at ambient temperature, specified environmentalconditions met, calibration cycle adhered to, and all internal automatic adjustments performed. Data without tolerances: typical values only. Data designated 'nominal' applies to design parameters and is not assured by Rohde & Schwarz.FrequencyR&S ®ESCIDC, AC coupled 9 kHz to 3 GHz R&S ®ESCI7 DC coupled 9 kHz to 7 GHz Frequency rangeAC coupled 1 MHz to 7 GHzResolution0.01 Hz Internal reference frequency (nominal) standardAging per year after 30 days of continuous operation 1 × 10–6Temperature drift +5 °C to +45 °C 1 × 10–6Internal reference frequency (nominal) R&S ®FSP-B4 option (OCXO)Aging per year after 30 days of continuous operation 1 × 10–7Temperature drift +5 °C to +45 °C 1 × 10–8External reference frequency 10 MHz Frequency display (receiver mode) numeric display Resolution 0.1 Hz Frequency display (analyzer mode)with marker or frequency counter Marker resolution span/500 Max. deviation sweep time > 3 × auto sweep time ±(marker frequency × reference frequencyerror + 0.5 % × span + 10 % × resolution bandwidth + ½ (last digit))Frequency counter resolution selectable 0.1 Hz to 10 kHz Count accuracy S/N > 25 dB ± (marker frequency × referencefrequency error + ½ (last digit))Display range of frequency axis R&S ®ESCI 0 Hz, 10 Hz to 3 GHzR&S ®ESCI7 0 Hz, 10 Hz to 7 GHz Max. deviation of display range 0.1 % f = 500 MHz, for f > 500 MHz see diagram100 Hz < –84 dBc (1 Hz), typ. –90 dBc (1 Hz) 1 kHz < –100 dBc (1 Hz), typ. –108 dBc (1 Hz) 10 kHz < –106 dBc (1 Hz), typ. –113 dBc (1 Hz) 100 kHz, span > 100 kHz < –110 dBc (1 Hz), typ. –113 dBc (1 Hz) 1 MHz, span > 100 kHz < –120 dBc (1 Hz), typ. –125 dBc (1 Hz) Spectral purity, SSB phase noise 10 MHz typ. –145 dBc (1 Hz)Residual FM f = 500 MHz, RBW = 1 kHz, sweep time = 100 mstyp. 3 HzVersion 03.00, June 2009Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test Receiver 3Scan (receiver mode)Scanscan of max. 10 subranges with different, independent settings Measurement time per frequencyselectable33 μs to 100 sSweep (analyzer mode)in time domain, span = 0 Hz 1 μs to 16000 sresolution 125 ns Sweep timein frequency domain, span ≥ 10 Hz 2.5 ms to 16000 s Max. deviation of sweep time1 %Resolution bandwidthsSweep filters3 dB bandwidths10 Hz to 3 MHz, in steps of 1/3/10 ≤ 100 kHz< 3 % Bandwidth accuracy 300 kHz to 3 MHz < 10 % ≤ 100 kHz< 5 Shape factor 60 dB:3 dB 300 kHz to 3 MHz < 156 dB bandwidths 200 Hz, 9 kHz, 120 kHz EMI bandwidths pulse bandwidth 1 MHz ≤ 120 kHz < 3 % Bandwidth accuracy 1 MHz < 10 % ≤ 120 kHz < 5 Shape factor 60 dB:6 dB 1 MHz< 15Video bandwidths analyzer mode1 Hz to 10 MHz, in steps of 1/3/10FFT filtersanalyzer mode 3 dB bandwidths 1 Hz to 30 kHz, in steps of 1/3/10 Bandwidth accuracy 5 %, nominal Shape factor 60 dB:3 dB2.5, nominalChannel filtersBandwidths100/200/300/500 Hz; 1/1.5/2/2.4/2.7/3/3.4/4/4.5/5/6/8.5/9/10/ 12.5/14/15/16/18 (RRC)/20/21/24.3 (RRC)/ 25/30/50/100/150/192/200/300/500 kHz 1/1.228/1.28 (RRC)/1.5/2/3/3.84 (RRC)/ 4.096 (RRC)/ 5 MHz(RRC = root raised cosine)PreselectionPreselectioncan be switched off in analyzer mode R&S ®ESCI: 11 preselection filtersR&S ®ESCI7: 12 preselection filters Bandwidths (–6 dB), nominal R&S ®ESCI, R&S ®ESCI7 < 150 kHz230 kHz, fixed-tuned lowpass filter 150 kHz to 2 MHz 2.6 MHz, fixed-tuned bandpass filter 2 MHz to 8 MHz 2 MHz, tracking bandpass filter 8 MHz to 30 MHz 6 MHz, tracking bandpass filter 30 MHz to 70 MHz 15 MHz, tracking bandpass filter 70 MHz to 150 MHz 30 MHz, tracking bandpass filter 150 MHz to 300 MHz 60 MHz, tracking bandpass filter 300 MHz to 600 MHz 80 MHz, tracking bandpass filter 600 MHz to 1 GHz 100 MHz, tracking bandpass filter 1 GHz to 2 GHz tracking highpass filter2 GHz to3 GHz fixed-tuned highpass filter R&S ®ESCI73 GHz to 7 GHztracking bandpass filter Preamplifier switchable, between preselection and 1st mixer20 dBVersion 03.00, June 20094 Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test ReceiverLevelDisplay rangedisplayed average noise level (DANL) to 30 dBmMaximum input level DC-coupled 0 V DC voltage AC-coupled 50 V RF attenuation 0 dB 20 dBm CW RF power RF attenuation ≥ 10 dB 30 dBm Pulse spectral density RF attenuation 0 dB 97 dB μV/MHz Max. pulse voltage RF attenuation ≥ 10 dB, 10 μs 150 VR&S ®ESCIRF attenuation ≥ 10 dB, 20 μs 10 mWs R&S ®ESCI7Max. pulse energyRF attenuation ≥ 10 dB, 10 μs 1 mWs Intermodulation1 dB compression of input mixer f > 200 MHz, RF attenuation 0 dB, preselection and preamplifier off5 dBm, nominal RF attenuation 0 dB, level 2 × –30 dBm, ∆f > 5 × RBW or 10 kHz, whichever is larger without preselection, without preamplifierR&S ®ESCI, R&S ®ESCI7 20 MHz to 200 MHz > 5 dBm 200 MHz to 3 GHz > 7 dBm, typ. 10 dBm R&S ®ESCI73 GHz to 7 GHz > 10 dBm, typ. 15 dBm with preselection, without preamplifierR&S ®ESCI, R&S ®ESCI7 20 MHz to 200 MHz > 0 dBm 200 MHz to 3 GHz > 2 dBm, typ. 5 dBm R&S ®ESCI73 GHz to 7 GHz > 10 dBm, typ. 15 dBm with preselection, with preamplifierR&S ®ESCI, R&S ®ESCI7 20 MHz to 200 MHz > –20 dBm 200 MHz to 3 GHz > –18 dBm, typ. –15 dBm R&S ®ESCI7Third-order intercept (TOI)3 GHz to 7 GHz > –10 dBm, typ. –5 dBmRF attenuation 0 dB, level –10 dBm, without preselection, without preamplifierR&S ®ESCI, R&S ®ESCI7 < 100 MHz typ. 25 dBm 100 MHz to 1.5 GHz typ. 35 dBm R&S ®ESCI71.5 GHz to 3.5 GHz typ. 70 dBmRF attenuation 0 dB, level –15 dBm, with preselection, without preamplifierR&S ®ESCI, R&S ®ESCI7 4 MHz to 100 MHz > 40 dBm 100 MHz to 1.5 GHz > 50 dBm R&S ®ESCI71.5 GHz to 3.5 GHz typ. 70 dBmRF attenuation 0 dB, level –35 dBm, with preselection, with preamplifierR&S ®ESCI, R&S ®ESCI7 4 MHz to 100 MHz > 25 dBm 100 MHz to 1.5 GHz > 35 dBm R&S ®ESCI7Second harmonic intercept (SHI)1.5 GHz to 3.5 GHz typ. 10 dBmVersion 03.00, June 2009Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test Receiver 5RF attenuation 0 dB, RBW = 10 Hz,VBW = 1 Hz, span = 0 Hz, trace average function over 20 sweeps, 50 Ω termination without preselection, without preamplifier, AC-coupledR&S ®ESCI 9 kHz < –105 dBm, nominal 100 kHz < –110 dBm, nominal 1 MHz < –130 dBm, nominal 10 MHz to 1 GHz < –142 dBm, typ. –145 dBm 1 GHz to 2.5 GHz < –140 dBm, typ. –143 dBm 2.5 GHz to 3 GHz < –138 dBm, typ. –141 dBm R&S ®ESCI7 1 MHz < –128 dBm, nominal 10 MHz to 1 GHz < –140 dBm, typ. –143 dBm 1 GHz to 2.5 GHz < –138 dBm, typ. –141 dBm 2.5 GHz to 3 GHz < –136 dBm, typ. –139 dBm 3 GHz to 7 GHz < –138 dBm, typ. –141 dBm without preselection, without preamplifier, DC-coupledR&S ®ESCI 9 kHz < –115 dBm 100 kHz < –120 dBm 1 MHz < –140 dBm, typ. –143 dBm 10 MHz to 1 GHz < –142 dBm, typ. –145 dBm 1 GHz to 2.5 GHz < –140 dBm, typ. –143 dBm 2.5 GHz to 3 GHz < –138 dBm, typ. –141 dBm R&S ®ESCI7 9 kHz < –115 dBm 100 kHz < –120 dBm 1 MHz < –138 dBm, typ. –141 dBm 10 MHz to 1 GHz < –140 dBm, typ. –143 dBm 1 GHz to 2.5 GHz < –138 dBm, typ. –141 dBm 2.5 GHz to 3 GHz < –136 dBm, typ. –139 dBm 3 GHz to 7 GHz < –138 dBm, typ. –141 dBm with preselection, without preamplifier, DC-coupledR&S ®ESCI 9 kHz < –115 dBm 100 kHz < –120 dBm, typ. –140 dBm 1 MHz < –140 dBm, typ. –148 dBm 10 MHz to 1 GHz < –142 dBm, typ. –150 dBm 1 GHz to 2.5 GHz < –140 dBm, typ. –148 dBm 2.5 GHz to 3 GHz < –138 dBm, typ. –141 dBm R&S ®ESCI7 9 kHz < –115 dBm 100 kHz < –120 dBm, typ. –140 dBm 1 MHz < –138 dBm, typ. –146 dBm 10 MHz to 1 GHz < –140 dBm, typ. –148 dBm 1 GHz to 2.5 GHz < –138 dBm, typ. –146 dBm 2.5 GHz to 3 GHz < –136 dBm, typ. –139 dBm 3 GHz to 7 GHz < –138 dBm, typ. –141 dBm with preselection, with preamplifier, DC-coupledR&S ®ESCI 9 kHz < –135 dBm 100 kHz < –140 dBm 1 MHz < –150 dBm, typ. –153 dBm 10 MHz to 1 GHz < –152 dBm, typ. –155 dBm Displayed average noise level (DANL) (analyzer mode)1 GHz to 3 GHz < –150 dBm, typ. –153 dBm R&S ®ESCI7 9 kHz < –135 dBm 100 kHz < –140 dBm 1 MHz < –148 dBm, typ. –151 dBm 10 MHz to 1 GHz < –150 dBm, typ. –153 dBm1 GHz to 7 GHz < –148 dBm, typ. –151 dBmVersion 03.00, June 2009 6 Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test ReceiverNoise indication (receiver mode) Nominal, calculated from DANL data, 0 dB RF attenuation, 50 Ω termination without preamplifierR&S ®ESCI, R&S ®ESCI7 9 kHz, BW = 200 Hz < 5 dB μV 150 kHz, BW = 200 Hz < 0 dB μV 150 kHz, BW = 9 kHz < 16 dB μV 1 MHz, BW = 9 kHz < –4 dB μV 10 MHz to 30 MHz, BW = 9 kHz < –6 dB μV 30 MHz to 1 GHz, BW = 120 kHz < 6 dB μV 1 GHz to 3 GHz, BW = 1 MHz < 16 dB μV R&S ®ESCI73 GHz to 7 GHz, BW = 1 MHz < 20 dB μV with preamplifierR&S ®ESCI, R&S ®ESCI7 9 kHz, BW = 200 Hz < –15 dB μV 150 kHz, BW = 200 Hz < –20 dB μV 150 kHz, BW = 9 kHz < –4 dB μV 1 MHz, BW = 9 kHz < –14 dB μV 10 MHz to 30 MHz, BW = 9 kHz < –16 dB μV 30 MHz to 1 GHz, BW = 120 kHz < –4 dB μV 1 GHz to 3 GHz, BW = 1 MHz < 6 dB μV R&S ®ESCI7Average (AV) display3 GHz to 7 GHz, BW = 1 MHz < 3 dB μV max peak typ. +11 dB RMS typ. +1 dB quasi-peak band A typ. +3 dB band B typ. +4 dB Increase of DANL relative to AV displaybands C and D typ. +6 dB Immunity to interference Image frequency> 70 dB Intermediate frequency> 70 dB Spurious response f > 1 MHz, 0 dB RF attenuation, without input signal< –103 dBmOther interfering signals ∆f > 100 kHz, mixer level < –10 dBm< –70 dBcRF shielding field strength 3 V/m, 0 dB RF attenuation, 50 Ω termination, f ≠ f IFlevel indication < 10 dB μV, nominalLevel display (receiver mode) digital numeric, resolution 0.01 dB Level displayanalog bargraph display separate for eachdetectorlevel axis 10 dB to 200 dB in steps of 10 dB Spectrum frequency axis linear or logarithmic selectable DetectorsThree detectors can be switched on simultaneously. average (AV), RMS, max peak, min peak, quasi-peak (QPK), CISPR-AV, CISPR-RMS Units of level display dB μV, dBm, dB μA, dBpW, dBpT Measurement timeselectable 33 μs to 100 s Level display (analyzer mode) Screen501 × 400 pixels(one measurement diagram); max. two measurement diagrams with independent settingsLogarithmic level display range 1 dB, 10 dB to 200 dB in steps of 10 dB Linear level display range10 % of reference level per level division, 10 divisions one measurement diagram 3 Number of traces two measurement diagrams 6Trace detectorsmax peak, min peak, auto peak, sample, quasi-peak, average, RMSTrace functionsclear/write, max hold, min hold, average default value 501Number of measurement pointsrange125 to 8001 in steps of approx. a factor of 2Version 03.00, June 2009Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test Receiver 7logarithmic level display –130 dBm to 30 dBm in steps of 0.1 dB Setting range of reference level linear level display70.71 nV to 7.07 V in steps of 1 % logarithmic level display dBm, dBmV, dB μV, dB μA, dBpW Units of level axislinear level displaymV, μV, mA, μA, nW, pWMax. uncertainty of level measurement level = –30 dBm, RF attenuation 10 dB, RBW 10 kHz, reference level –25 dBm without preselection/preamplifier <0.2 dB (σ = 0.07 dB) Reference level uncertainty at 128 MHzwith preselection/preamplifier <0.3 dB (σ = 0.1 dB) without preselection/preamplifier, AC-coupledR&S ®ESCI9 kHz to 50 kHz < +0.5 dB/–1 dB, nominal 50 kHz to 3 GHz < 0.5 dB (σ = 0.17 dB) R&S ®ESCI71 MHz to 3 GHz < 0.5 dB (σ = 0.17 dB) 3 GHz to 7 GHz <2 dB (σ = 0.7 dB) without preselection/preamplifier, DC-coupledR&S ®ESCI9 kHz to 3 GHz < 0.5 dB (σ = 0.17 dB) R&S ®ESCI79 kHz to 3 GHz < 0.5 dB (σ = 0.17 dB) 3 GHz to 7 GHz < 2 dB (σ = 0.7 dB) with preselection/preamplifier, AC-coupledR&S ®ESCI9 kHz to 50 kHz < +0.8 dB/–1.3 dB, nominal 50 kHz to 3 GHz < 0.8 dB (σ = 0.27 dB) R&S ®ESCI71 MHz to 3 GHz < 0.8 dB (σ = 0.27 dB) 3 GHz to 7 GHz <2 dB (σ = 0.7 dB) with preselection/preamplifier, DC-coupledR&S ®ESCI9 kHz to 3 GHz < 0.8 dB (σ = 0.27 dB) R&S ®ESCI79 kHz to 3 GHz < 0.8 dB (σ = 0.27 dB) Frequency response referenced to 128 MHz3 GHz to 7 GHz < 2 dB (σ = 0.7 dB)Uncertainty of attenuator settingf = 128 MHz,0 dB to 70 dB, referenced to 10 dB RF attenuation < 0.2 dB (σ = 0.07 dB) Uncertainty of reference level setting < 0.2 dB (σ = 0.07 dB) S/N > 16 dBRBW ≤ 120 kHz 0 dB to –70 dB < 0.2 dB (σ = 0.07 dB) –70 dB to –90 dB < 0.5 dB (σ = 0.17 dB) RBW > 120 kHz 0 dB to –50 dB < 0.2 dB (σ = 0.07 dB) Log/lin display nonlinearity–50 dB to –70 dB < 0.5 dB (σ = 0.17 dB) referenced to RBW = 10 kHz 10 kHz to 120 kHz < 0.1 dB (σ = 0.03 dB) 300 kHz to 10 MHz < 0.2 dB (σ = 0.07 dB) Bandwidth switching uncertaintyFFT filter, 1 Hz to 3 kHz < 0.2 dB (σ = 0.07 dB)Total measurement uncertainty (95 % confidence level) Signal level 0 dB to –70 dB below reference level, S/N > 20 dB, RBW ≤ 120 kHz, DC-coupledwithout preselection/preamplifier < 3 GHz 0.5 dB 3 GHz to 7 GHz 1.5 dB with preselection/preamplifier < 3 GHz 1 dB3 GHz to 7 GHz 1.5 dB Quasi-peak indication in line with CISPR 16-1-1Version 03.00, June 20098 Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test ReceiverTrigger functionsTriggerTrigger sourcefree run, video, external, IF levelspan ≥ 10 Hz 125 ns to 100 s, resolution min. 125 ns (or 1 % of offset)Trigger offsetspan = 0 Hz±(125 ns to 100 s), resolution min. 125 ns, dependent on sweep timeMax. deviation of trigger offset±(125 ns + (0.1 % × trigger offset))Gated sweep Gate source video, external, IF level Gate delay 1 μs to 100 sGate length125 ns to 100 s, resolution min. 125 ns (or 1 % of gate length)Max. deviation of gate length± (125 ns + (0.1 % × gate length))Audio demodulationAF demodulation modes AM and FMAudio outputloudspeaker and earphone jack Marker hold time in analyzer modeselectable100 ms to 60 sInputs and outputs (front panel)RF inputImpedance 50 ΩConnector N femaleRF attenuation < 10 dB, DC-coupledR&S ®ESCI, R&S ®ESCI7 9 kHz to 1 GHz < 2.0, typ. 1.5 1 GHz to 3 GHz < 3.0, typ. 2.5 R&S ®ESCI73 GHz to 7 GHz< 3.0, typ. 2.5RF attenuation ≥ 10 dB, DC-coupledR&S ®ESCI, R&S ®ESCI7 9 kHz to 1 GHz < 1.2 1 GHz to 3 GHz < 1.5 R&S ®ESCI73 GHz to 7 GHz< 2.0RF attenuation < 10 dB, AC-coupledR&S ®ESCI9 kHz to 100 kHz 2.5 100 kHz to 1 GHz 2.0 1 GHz to 3 GHz 3.0 R&S ®ESCI71 MHz to 5 MHz 2.5 5 MHz to 1 GHz 2.0 1 GHz to 7 GHz3.0RF attenuation ≥ 10 dB, AC-coupledR&S ®ESCI9 kHz to 100 kHz typ. 2.5 100 kHz to 1 GHz < 1.2 1 GHz to 3 GHz < 1.5R&S ®ESCI71 MHz to 5 MHz typ. 2.5 5 MHz to 1 GHz < 1.2 1 GHz to3 GHz < 1.5 VSWR 3 GHz to 7 GHz< 2.0Setting range of attenuator 0 dB to 70 dB in steps of 5 dBProbe power supply Supply voltages+15 V DC, –12.6 V DC and ground, max. 150 mA, nominalVersion 03.00, June 2009Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test Receiver 9Power supply for antennas, etc. Supply voltages±10 V DC and ground, max. 100 mA, nominalUSB interface2 ports, type A plug, version 2.0AF output Connector3.5 mm jackImpedance 10 ΩOpen-circuit voltageadjustable up to 1.5 VInputs and outputs (rear panel)IF 20.4 MHz Connector BNC female Impedance50 Ωmixer level > –60 dBm RBW ≤ 100 kHz or FFT –10 dBm at reference level LevelRBW > 100 kHz0 dBm at reference levelReference frequency outputConnector BNC female Impedance 50 Ω Output frequency 10 MHzLevel 0 dBm, nominalReference frequency inputConnector BNC female Input frequency 10 MHzRequired level 0 dBm from 50 ΩPower supply for noise sourceConnector BNC female Output voltage switchable 28 V, nominalExternal trigger/gate inputConnector BNC female Impedance > 10 k Ω Trigger voltage 1.4 V (TTL)IEC/IEEE bus remote control interface in line with IEC 625-2 (IEEE 488.2)Connector 24-pin Amphenol female Command set SCPI 1997.0Interface functionsSH1, AH1, T6, SR1, RL1, PP1, DC1, DT1, C0Serial interfaceRS-232-C (COM), 9-pin D-SubPrinter interfaceparallel (Centronics compatible)upper connector type A plug, version 1.1 USB interface lower connectortype A plug, version 2.0External monitor (VGA) ConnectorVGA-compatible, 15-pin D-SubUser interface 25-pin D-SubVersion 03.00, June 200910 Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test ReceiverGeneral dataDisplay 21 cm TFT color display Resolution 640 × 480 pixel (VGA)Pixel error rate< 2 × 10–5Mass memory1.44 Mbyte 3½'' disk drive, hard disk Data storage R&S ®ESCI only> 500 instrument setups and tracesTemperature ranges+5 °C to + 40 °C Operating temperature range with R&S ®ESCI-B20 option 0 °C to +50 °C+5 °C to + 45 °C Permissible temperature range with R&S ®ESCI-B20 option 0 °C to +55 °C Storage temperature range –40 °C to +70 °CClimatic loading+40 °C at 95 % relative humidity (EN 60068-2-30)Mechanical resistance Sinusoidal vibration0.5 g from 5 Hz to 150 Hz, max. 2 g at 55 Hz,in line with EN 60068-2-6, EN 61010-1, MIL-T-28800D, class 510 Hz to 100 Hz, acceleration 1 g (rms) Random vibration with R&S ®ESCI-B20 option 10 Hz to 300 Hz, acceleration 1.9 g (rms) Shock40 g shock spectrum,in line with MIL-STD-810C and MIL-T-28800D, classes 3 and 5operation with external reference 2 years Recommended calibration interval operation with internal reference1 yearPower supply AC supply100 V to 240 V AC, 50 Hz to 400 Hz, 3.1 A to 1.3 A,class of protection I in line with VDE 411 Power consumption typ. 70 VASafety in line with EN 61010-1, UL 3111-1, CSA C22.2 No. 1010-1, IEC 1010-1 EMCEMC Directive 2004/108/EC including:EN 61326 class B (emission),CISPR 11/EN 55011 group 1 class B (emission)EN 61326 table A.1 (immunity, industrial)Test marksVDE, GS, CSA, CSA-NRTL/CDimensions and weight DimensionsW × H × D 412 mm × 197 mm × 417 mm (16.22 in × 7.76 in × 16.42 in) R&S ®ESCI10.5 kg (23.15 lb) Weight without options R&S ®ESCI712.4 kg (27.34 lb)Version 03.00, June 2009Rohde & Schwarz R&S ®ESCI/ESCI7 EMI Test Receiver 11Ordering informationDesignation Type Order No.EMI Test Receiver 9 kHz to 3 GHz R&S ®ESCI 1166.5950.03EMI Test Receiver 9 kHz to 7 GHz R&S ®ESCI7 1166.5950.07 Accessories suppliedPower cable, operating manual, service manualOptionsDesignation Type Order No.Rugged Case, with carrying handle R&S ®FSP-B1 1129.7998.02OCXO Reference Frequency R&S ®FSP-B4 1129.6740.02TV Trigger/RF Power Trigger R&S ®FSP-B6 1129.8594.02Internal Tracking Generator, I/Q Modulator R&S ®FSP-B9 1129.6991.02External Generator Control R&S ®FSP-B10 1129.7246.03LAN Interface 100BaseT R&S ®FSP-B16 1129.8042.03Expanded Environmental Specifications R&S ®ESCI-B20 1155.1606.14DC Power Supply R&S ®FSP-B30 1155.1158.02Battery Pack R&S ®FSP-B31 1155.1258.02Spare Battery Pack R&S ®FSP-B32 1155.1506.02Service OptionsDesignation Type Order No.R&S ®ESCIOne-Year Repair Service following the warranty periodR&S ®RO2ESCI 1166.5950.S16 Two-Year Repair Service following the warranty periodR&S ®RO3ESCI 1166.5950.S12 Four-Year Repair Service following the warranty periodR&S ®RO5ESCI 1166.5950.S14 Two-Year Calibration Service R&S ®CO2ESCI 1166.5950.S15Three-Year Calibration Service R&S ®CO3ESCI 1166.5950.S11Five-Year Calibration Service R&S ®CO5ESCI 1166.5950.S13R&S ®ESCI7One-Year Repair Service following the warranty periodR&S ®RO2ESCI7 1166.5950.S26 Two-Year Repair Service following the warranty periodR&S ®RO3ESCI7 1166.5950.S22 Four-Year Repair Service following the warranty periodR&S ®RO5ESCI7 1166.5950.S24 Two-Year Calibration Service R&S ®CO2ESCI7 1166.5950.S25Three-Year Calibration Service R&S ®CO3ESCI7 1166.5950.S21Five-Year Calibration Service R&S ®CO5ESCI7 1166.5950.S23For product brochure, see:• PD 0758.1558.12 (ESCI) • PD 5214.2762.12 (ESCI7)and About Rohde & SchwarzRohde & Schwarz is an independent group of companies specializing in electronics. It is a leading supplier of solu-tions in the fields of test and measurement, broadcasting, radiomonitoring and radiolocation, as well as secure com-munications. Established 75 years ago, Rohde & Schwarz has a global presence and a dedicated service network in over 70 countries. Company headquarters are in Munich, Germany.Regional contactEurope, Africa, Middle East+49 1805 12 42 42* or +49 89 4129 137 74 *********************************North America1888TESTRSA(188****8772)**********************************.com Latin America +1 410 910 79 88************************************Asia/Pacific+65 65 13 04 88**************************************Rohde & Schwarz GmbH & Co. KG Mühldorfstraße 15 | 81671 MünchenPhone +49 89 41 290 | Fax +49 89 41 29 121 R&S® is a registered trademark of Rohde & Schwarz GmbH & Co. KG Trade names are trademarks of the owners | Printed in Germany (sv) PD 0758.1558.22 | Version 03.00 | June 2009 | R&S®ESCI/ESCI7 Subject to change*0.14 €/min within German wireline network; rates may vary in othern etworks (wireline and mobile) and countries. Certified Environmental SystemISO 14001Certified Quality SystemISO 9001。

ICS系列电子皮带秤使用说明书第一章序言一：概论ICS系列电子皮带秤是一种先进的微机控制动态称重仪表，是在皮带输送系统中对散状物料进行连续计量的理想设备，整机设计合理，紧凑，具有完善的称重合控制数学模型，并有多种输入，输出信号形式。

其结构简单，称量准确，工作稳定，运行可靠，操作方便，维护量极少。

不仅适用于常规环境，而且适用于酸，碱，盐及大气腐蚀环境。

广泛的应用于冶金，电力，矿山，港口，化工，水泥，建材，粮食等行业。

ICS系列电子皮带秤可根据你的选择提供各种高智能化仪表和进口传感器。

二：主要技术指标1：系统性能系统精度：ICS-17型为优于±0.25%；ICS-20型为优于±0.5%仪表精度：优于±0.05%称量范围：1-6000t/h皮带宽度：500-2200mm皮带速度：0.05-4m/s皮带输送机倾角：≤17°适用托辊形式：三节槽型托辊及平托辊环境温度：秤架为-30°-- +50°积算器为-10°-- +50°2：载荷传感器性能非线性：小于额定输出的0.03%FC非重复性：小于额定输出的0.03%FC滞后：小于额定输出的0.03%FC允许短时过载：125%激励电压：10VDC3：速度传感器性能频率范围：0-1.2KHz信号：0-30VAC速度范围：0.05-4m/s4:积算器性能精度：优于0.05%电源：220V（-15%-+10%） 50HZ±2% 功率：50VA重量输入：从一只，两只或四只称重传感器传来的毫伏信号速度输入：从数字式传感器传来的脉冲信号输出激励电压：10VDC输出至速度传感器：24VDC（编码器用）累计显示输出流量显示输出远程累计输出电流输出：4-20MA打印输出通讯接口：RS232 RS485 可选三：系统组成工作原理及特点1：系统组成ICS系列电子皮带秤主要有四部分组成：称重桥架，称重传感器，速度传感器和积算器。

Eaton 171172Eaton Moeller series xEffect - FRCmM-125 Type A RCCB.Residual current circuit breaker (RCCB), 125A, 2p, 300mA, type S/AGeneral specificationsEaton Moeller series xEffect - FRCmM-125 Type A RCCB17117285 mm75.5 mm 36 mm 0.28 kg RoHS conform IEC/EN 610084015081676613FRCMM-125/2/03-S/AProduct NameCatalog Number Product Length/Depth Product Height Product Width Product Weight Compliances Certifications EANModel CodeTwo-pole50 ms delayed, selective switch off Selective switch off125 A10 kA with back-up fuse300 mAPulse-current sensitive5 kA (8/20 μs) surge-proof 240 V AC240 V440 V4 kV0.3 A0.3 A50 Hz125 A (max. admissible back-up fuse) A1250 A80 A gG/gL10 kA5 kA184 V AC - 250 V AC24000 operationsApplicationNumber of polesTripping timeAmperage RatingRated short-circuit strength Fault current rating Sensitivity typeImpulse withstand current Type Voltage rating (IEC/EN 60947-2)Rated operational voltage (Ue) - maxRated insulation voltage (Ui)Rated impulse withstand voltage (Uimp) Rated fault current - minRated fault current - maxFrequency ratingShort-circuit ratingLeakage current typeRated residual making and breaking capacity Admissible back-up fuse overload - max Rated short-time withstand current (Icw) Surge current capacityTest circuit rangePollution degreeLifespan, electricalSwitchgear for industrial and advanced commercial applicationsxEffect - Switchgear for industrial and advanced commercial applicationsFRCmM-125Residual current circuit breakersType S/A45 mm235 mm (2 SU)70.5 mmQuick attachment for DIN-rail EN 50022DIN railAs requiredIP20, IP40 with suitable enclosureIP20Toggle-center postitionTwin-purpose terminals1.5 mm² - 16 mm² (2x)1.5 mm² - 50 mm²1.5 mm²50 mm²1.5 mm² - 5 mm²1.5 mm² - 16 mm² (2x)1.5 mm²16 mm²Finger and hand touch safe, DGUV VS3, EN 50274 Red / green 125 A0 W18 W0 W0 W-25 °C60 °CMeets the product standard's requirements.Meets the product standard's requirements.Meets the product standard's requirements.Meets the product standard's requirements.Meets the product standard's requirements.Does not apply, since the entire switchgear needs to be evaluated.Does not apply, since the entire switchgear needs to be evaluated.Meets the product standard's requirements.Does not apply, since the entire switchgear needs to beFrameWidth in number of modular spacingsBuilt-in width (number of units)Built-in depthMounting MethodMounting positionDegree of protectionStatus indicationTerminals (top and bottom)Terminal capacity (solid wire)Connectable conductor cross section (solid-core) - min Connectable conductor cross section (solid-core) - max Terminal capacity (stranded cable)Connectable conductor cross section (multi-wired) - min Connectable conductor cross section (multi-wired) - max Terminal protectionContact position indicator color Rated operational current for specified heat dissipation (In) Heat dissipation per pole, current-dependentEquipment heat dissipation, current-dependentStatic heat dissipation, non-current-dependentHeat dissipation capacityAmbient operating temperature - minAmbient operating temperature - max10.2.2 Corrosion resistance10.2.3.1 Verification of thermal stability of enclosures10.2.3.2 Verification of resistance of insulating materials to normal heat10.2.3.3 Resist. of insul. mat. to abnormal heat/fire by internal elect. effects10.2.4 Resistance to ultra-violet (UV) radiation10.2.5 Lifting10.2.6 Mechanical impact10.2.7 Inscriptions10.3 Degree of protection of assemblies0.8 mm - 2 mm 10000 operations-25 °C60 °C25-55 °C / 90-95% relative humidity according to IEC 60068-2evaluated.Meets the product standard's requirements.Does not apply, since the entire switchgear needs to be evaluated.Does not apply, since the entire switchgear needs to be evaluated.Is the panel builder's responsibility.Is the panel builder's responsibility.Is the panel builder's responsibility.Is the panel builder's responsibility.Is the panel builder's responsibility.The panel builder is responsible for the temperature rise calculation. Eaton will provide heat dissipation data for the devices.Is the panel builder's responsibility. The specifications for the switchgear must be observed.Is the panel builder's responsibility. The specifications for the switchgear must be observed.The device meets the requirements, provided the information in the instruction leaflet (IL) is observed.Additional equipment possible Selective protectionResidual current circuit breakereaton-rcd-application-guide-br019003en-en-us.pdf eaton-xeffect-frcmm-125-rccb-catalog-ca003020en-en-us.pdfBusbar material thickness Lifespan, mechanical Permitted storage and transport temperature - min Permitted storage and transport temperature - max Climatic proofing10.4 Clearances and creepage distances 10.5 Protection against electric shock10.6 Incorporation of switching devices and components 10.7 Internal electrical circuits and connections 10.8 Connections for external conductors 10.9.2 Power-frequency electric strength 10.9.3 Impulse withstand voltage 10.9.4 Testing of enclosures made of insulating material 10.10 Temperature rise10.11 Short-circuit rating10.12 Electromagnetic compatibility10.13 Mechanical functionFeaturesApplication notesCataloguesEaton Corporation plc Eaton House30 Pembroke Road Dublin 4, Ireland © 2023 Eaton. All rights reserved. Eaton is a registered trademark.All other trademarks areproperty of their respectiveowners./socialmediaInterlocking deviceResidual current circuit breakers FRCmM-125Type S/A eaton-xeffect-industrial-switchgear-range-catalog-ca003002en-en-us.pdf DA-DC-03_FRCmMas_frcmmeaton-frcm-dimensions.jpgIL019140ZUdfs_2.dwgdfs_2.stpeaton-xeffect-frcmm-125-rccb-wiring-diagram-002.jpgFitted with:Special features Used with Certification reports DrawingsInstallation instructions mCAD modelWiring diagramsCurrent test marks as per inscriptionMaximum operating temperature is 60 °C: Starting at 40 °C, the max. permissible continuous current decreases by 2.2% for every 1 °C。

产品规格书产品型号：****版本号：V0发布日期：2015-05-18编制：日期：审核：日期：批准：日期：发布部门：****技术部1. 目的规范及定义SH-715系列取暖器的产品设计要求、产品规格、工程测试方法、标准作业程序、材料清单、图纸、安规认证和质量控制。

产品必须遵守本文件所述的工程试验方法。

产品最终的制造、测试和包装均参照本要求。

2.范围本规格为SH-715电子版本，涵盖UL/CUL/ETL/CETL/CSA/SAA/GS/CQC等版本，包括对流式及辐射式加热器，。

3.参考及引用文件3.1.UL 1278 & UL10423.2.CSA C22.2 No.46-M19883.3.IEC60335-1 & IEC60335-2-303.4.GB 4706.23-20083.5.NOM standard3.6.State and Local Government Regulations3.7.UL 746C, Polymeric Materials - Use in Electrical Equipment Evaluations3.8.汉兴 QA 检验计划3.9.GYD-D产品开发指令单4.产品特点/定义GYD-D是包括对流式和辐射式的充油取暖器，俗称电热油汀，电子控制面板，适宜家庭居室或客厅使用，对应不同版本设计材料符合对应安规要求。

未经亿禾技术部批准，任何材料规格等不允许变更，包括设计、外购件、供应商、包装等；5.产品特点5.1.两档加热选择；5.2.2-4-6-8-10-12小时定时功能；5.3.LED指示灯显示；5.4.电子跌倒开关；5.5.保险丝安全防护；5.6.可拆卸支脚设计，独立把手设计；6.产品尺寸：6.1.机器尺寸 L370*W 250*H6306.2.包装尺寸 L400*W 160*H6607.产品参考图片8.产品重量8.1.净重 8.2Kg8.2.毛重 12Kg9.规格分类10.1标识/结构检查10.1.1规格标识永久性标记,所处的位置可使标记清楚可见.²列名公司的名称、商品名或商标;²编目码或等同物;²制造日期或其它日期期间;²完整的电气额定值;10.1.2电源线和插头检查²电源线的长度:1.8－2.4米(UL1278要求)²家用加热器(不用于室外)表面温度超过121℃,必须采用HPD/HPN/HSJO/HSJ 类型的电源线,并且此类电源线的最大电流承受能力18AWG(10A)/16AWG(15A)/14AWG(20A)表面温度低于121℃,可采用SP-2/SPT-2/SVO/SV/SVTO/SVT/SJO/SJ/SJTO/SJT类型的电源线,并且此类电源线的最大电流承受能力:18AWG(10A)/16AWG(13A)/14AWG(18A)²插头接线为锡焊型,铜焊,熔锡焊型(锡焊接线在焊接前要机械固定)²插头的电流额定值不得于加热器额定值的125％.如:15A插头适用的加热器额定值不超过1500W(120V)或3000W(240V)美国版本电源线需要符合UL1278要求，加拿大版本可以不考虑UL1278对电源线连接要求，金属外壳电源线连接需要铜带铆接后上锡，加玻纤套管后再加热缩套管收缩固定；非金属外壳，铜带连接后上锡，然后加热缩套管收缩固定。

77102标准是指电子产品可靠性试验规范，是目前国际上通行的电子产品可靠性试验标准之一。

该标准包括了电子产品在使用中可能遇到的各种环境和应力因素，如温度、湿度、振动等，通过测试来评估电子产品的可靠性。

下面我们将详细介绍77102标准。

一、标准概述77102标准是由国际电工委员会（IEC）发布的，是一个用于电子产品可靠性试验的全面标准。

它涵盖了电子产品在使用中所面临的各种环境和应力因素，包括机械、热、化学、电气等因素。

同时，该标准也包含了产品的可靠性评估方法和标准试验程序。

二、标准内容1. 试验方法77102标准共分为17个试验方法，包括了电子产品常见的应力因素和环境因素，如高温、低温、温度变化、湿热循环、机械振动、冲击等。

每种试验方法都有详细的试验程序和要求，并且提供了试验结果评定的标准方法。

2. 试验设备77102标准要求试验设备必须满足相关的精度和可靠性要求，同时需要在试验中记录下相关的数据。

试验设备的性能和稳定性是保证试验结果准确性的重要因素。

3. 试验条件77102标准规定了各种试验方法的试验条件，包括温度、湿度、气压、振动等环境因素，这些条件是根据电子产品使用环境的实际情况制定的，能够全面反映电子产品的可靠性。

4. 试验评定方法77102标准提供了对试验结果的评定方法，包括了可靠性指标的计算方法和评价方法。

这些评价方法可以为电子产品的设计和改进提供参考依据，并且可以为消费者提供选择电子产品的依据。

三、应用范围77102标准适用于各种类型的电子产品，包括通信设备、计算机、消费电子、医疗设备等。

它可以帮助制造商评估产品的可靠性和耐久性，为用户提供更可靠的电子产品。

四、总结77102标准是电子产品可靠性试验的全面标准，它涵盖了电子产品在使用中可能遇到的各种环境和应力因素，通过测试来评估电子产品的可靠性。

它不仅提供了试验方法和试验设备的要求，还提供了对试验结果的评定方法。

该标准适用于各种类型的电子产品，可以帮助制造商评估产品的可靠性和耐久性，为用户提供更可靠的电子产品。