PT4128C中文资料

ESD 保护芯片CH412中文手册 版本：1B 1、概述CH412是四路ESD 保护二极管阵列，能够承受IEC 61000-4-2规定的最高±15KV 人体模型、±8KV 接触放电以及±15KV 气隙放电的ESD 脉冲，用于电子产品对外接口中的高速信号和差分信号以及通用信号的ESD 保护。

CH412K 提供4通道低电容二极管保护和TVS 瞬态电压抑制器箝位，适用于高速和中低速信号，可以用于USB 超速、高速和全速以及低速信号保护。

CH412Z 提供4通道TVS 瞬态电压抑制器箝位，适用于中低速信号，可以用于USB 全速和低速信号保护。

CH412K CH412Z2、特点● 支持±15KV 人体模型HBM 。

● 支持±8KV 接触放电。

● 支持±15KV 气隙放电。

● CH412K ：内部4路独立箝位二极管，典型值1pF 的低输入电容，适用于高速和中低速信号。

● CH412Z ：内部4路TVS 箝位保护，典型值20pF 的输入电容，适用于中低速信号。

● 采用SOT 小体积晶体管级贴片无铅封装，兼容RoHS 。

3、封装封装形式 塑体宽度 引脚间距 封装说明 订货型号 SOT363 1.25mm 49mil 0.65mm 26mil 小型6脚贴片 CH412K SOT353 1.25mm 49mil 0.65mm 26mil 小型5脚贴片 CH412Z 注：1、封装体积较小，正面印字仅有代号而不含全部型号，例如CH412Z 代号是12。

2、盘装，每盘整包装数量为3000只，可以零售，但是零售时不会逐个清点数量。

IO4 IO3 IO3 VCC IO44、型号CH412B已经停产，请换用CH412K，多出的两个通道可以悬空或并联（低速时）。

4、引脚CH412K 引脚号CH412Z引脚号引脚名称类型引脚说明2 2 GND 电源公共接地端，必须直接连接到全局地5 无VCC 电源正电源端，必须靠近引脚对GND连接0.1μF电容，用于USB信号保护时通常为3.3V（或者5V），用于其它信号须同被保护芯片的电源电压（2V～5V）1,3,4,6 1,3,4,5 IO1～IO4 信号ESD保护通道，与被保护芯片的信号引脚并联5、应用说明CH412设计用来与被保护芯片内置的ESD保护一起工作。

MIC4126/27/28Dual 1.5A-Peak Low-Side MOSFETDrivers in Advanced PackagingGeneral DescriptionThe MIC4126, MIC4127, and MIC4128 family are highly-reliable dual 1.5A low-side MOSFET drivers fabricated onMicrel’s BiCMOS/DMOS process. The devices feature lowpower consumption and high efficiency. TheMIC4126/27/28 translate TTL or CMOS input logic levels tooutput voltage levels that swing within 25mV of the positivesupply or ground whereas comparable bipolar devices arecapable of swinging only to within 1V of the supply. TheMIC4126/7/8 is available in three configurations: dualinverting, dual non-inverting, and complimentary output.The MIC4126/27/28 offer pin-compatible as well as smallerfootprint replacements for the MIC4426/27/28 withimproved packaging and electrical performance. TheMIC4126/27/28 are available in exposed pad, EPAD,SOIC-8L and MSOP-8L options as well as a small-size3mm x 3mm MLF™-8L option. The devices have an inputoperating range of 4.5V to 20V.Primarily intended for driving power MOSFETs,MIC4426/7/8 drivers are suitable for driving other loads(capacitive, resistive, or inductive) which require low-impedance, high peak current, and fast switching time. Thedevices can withstand up to 500mA of reverse current(either polarity) without latching and up to 5V noise spikes(either polarity) on ground pins.Data sheets and support documentation can be found onMicrel’s web site at .Features•Dual 1.5A-peak drivers• 4.5V to 20V operating range•Exposed backside pad packaging reduces heat–ePAD SOIC-8L (θJA = 58°C/W)–ePAD MSOP-8L (θJA = 60°C/W)–3mm x 3mm MLF™-8L (θJA = 60°C/W)• Bipolar/CMOS/DMOS construction–25mV maximum output offset from supply or ground•Latch-up protection to >200mA reverse current•Switches 1000pF in 25ns•Logic-input threshold independent of supply voltage•Logic-input protection to –5V•6pF typical equivalent input capacitance•Dual inverting, dual non-inverting, and complementaryconfigurations• -40°C to +125°C operating junction temperature rangeApplications• DC/DC converters• Motor drivers•Clock line driverFunctional DiagramMIC4126/27/28 Block DiagramOrdering InformationPin ConfigurationEPAD SOIC-8L (ME) EPAD MSOP-8L (MME)MLF-8L (ML)EPAD SOIC-8L (ME) EPAD MSOP-8L (MME)MLF-8L (ML)EPAD SOIC-8L (ME) EPAD MSOP-8L (MME)MLF-8L (ML)Pin DescriptionPin NumberPin NamePin Function1, 8 NC Not internally connected2 INA Control Input A: TTL/CMOS compatible logic input3 GND Ground4 INB Control Input B: TTL/CMOS compatible logic input.5 OUTB Output B: CMOS totem-pole output.6 V S Supply Input: +4.5V to +20V7 OUTA Output A: CMOS totem-pole output. EPGNDGround, backside pad.Part Number Configuration PackageJunction Temp. Range (1) Lead Finish MIC4126YME Dual Inverting EPAD 8-lead SOIC –40° to +125°C Pb-Free MIC4126YMME Dual Inverting EPAD 8-lead MSOP –40° to +125°C Pb-Free MIC4126YML Dual Inverting 8-lead MLF –40° to +125°C Pb-Free MIC4127YME Dual Non-inverting EPAD 8-lead SOIC –40° to +125°C Pb-Free MIC4127YMME Dual Non-inverting EPAD 8-lead MSOP –40° to +125°C Pb-Free MIC4127YML Dual Non-inverting 8-lead MLF –40° to +125°C Pb-Free MIC4128YME Inverting + Non-inverting EPAD 8-lead SOIC –40° to +125°C Pb-Free MIC4128YMME Inverting + Non-inverting EPAD 8-lead MSOP –40° to +125°C Pb-Free MIC4128YMLInverting + Non-inverting8-lead MLF–40° to +125°CPb-FreeAbsolute Maximum Ratings (1)Supply Voltage (V S)......................................................+24V Input Voltage (V IN)...........................V S + 0.3V to GND – 5V Junction Temperature (T J).........................................150°C Storage Temperature................................–65°C to +150°C Lead Temperature (10 sec.)......................................300°C ESD Rating, Note 3Operating Ratings (2)Supply Voltage (V S)......................................+4.5V to +20V Temperature Range (T J)...........................–40°C to +125°C Package Thermal Resistance3X3MLF™θJA.................................................60°C/W EPAD MSOP-8L θJA ...............................60°C/WEPADSOIC-8LθJA .................................58°C/WElectrical Characteristics (4)4.5V ≤ V S≤ 20V; Input voltage slew rate >1V/µs; C OUT = 1000pF. T A = 25°C, bold values indicate full specified temperature range;unless noted.Symbol Parameter Condition Min Typ Max Units InputV IH Logic 1 Input Voltage 2.42.41.41.6VV IL Logic 0 Input Voltage 1.11.30.80.8VI IN InputCurrent 0 ≤ V IN≤ V S–1 1 µA OutputV OH High Output Voltage V S–0.025 V V OL Low Output Voltage 0.025VR O Output Resistance I OUT = 10mA, V S = 20V 68 1012ΩI PK Peak Output Current 1.5 A I Latch-Up Protection Withstand reverse current >200 mA Switching Timet R Rise Time Test Figure 1 13203040nst F Fall Time Test Figure 1 15182540nst D1Delay Time Test Figure 1 37435060nst D2Delay Time Test Figure 1 40456070nsPower SupplyI S Power Supply Current V INA = V INB = 3.0V 1.41.54.58mAI S Power Supply Current V INA = V INB = 0.0V 0.180.190.40.6mANotes:1. Exceeding the absolute maximum rating may damage the device.2. The device is not guaranteed to function outside its operating rating.3. Devices are ESD sensitive. Handling precautions recommended. Human body model: 1.5kΩ in series with 100pF.4. Specification for packaged product only.Test CircuitFigure 1a. Inverting ConfigurationFigure 2a. Non-inverting ConfigurationFigure 1b. Inverting TimingFigure 2b. Non-inverting TimingTypical CharacteristicsApplication InformationSupply BypassingLarge currents are required to charge and discharge large capacitive loads quickly. For example, changing a 1000pF load by 16V in 25ns requires 0.8A from the supply input.To guarantee low supply impedance over a wide frequency range, parallel capacitors are recommended for power supply bypassing. Low-inductance ceramic MLC capacitors with short lead lengths (< 0.5") should be used. A 1.0µF film capacitor in parallel with one or two 0.1µF ceramic MLC capacitors normally provides adequate bypassing. GroundingWhen using the inverting drivers in the MIC4126 or MIC4128, individual ground returns for the input and output circuits or a ground plane are recommended for optimum switching speed. The voltage drop that occurs between the driver’s ground and the input signal ground, during normal high-current switching, will behave as negative feedback and degrade switching speed.The E-pad and MLF packages have an exposed pad under the package. It’s important for good thermal performance that this pad is connected to a ground plane.Control InputUnused driver inputs must be connected to logic high (which can be V S) or ground. For the lowest quiescent current (< 500µA), connect unused inputs-to-ground. A logic-high signal will cause the driver to draw up to 9mA. The control input voltage threshold is approximately 1.5V. The control input recognizes 1.5V up to V S as a logic high and draws less than 1µA within this range.Power DissipationPower dissipation should be calculated to make sure that the driver is not operated beyond its thermal ratings. Quiescent power dissipation is negligible. A practical value for total power dissipation is the sum of the dissipation caused by the load and the transition power dissipation (P L + P T).Load DissipationPower dissipation caused by continuous load current (when driving a resistive load) through the driver’s output resistance is:P L = I L2 R OFor capacitive loads, the dissipation in the driver is: P L = f C L V S2Transition DissipationIn applications switching at a high frequency, transition power dissipation can be significant. This occurs during switching transitions when the P-channel and N-channel output FETs are both conducting for the brief moment when one is turning on and the other is turning off.P T = 2 f V S QCharge (Q) is read from the following graph:Crossover Energy Loss per TransitionPackage Information8-Pin Exposed Pad SOIC (M)8-Pin Exposed Pad MSOP (MM)8-Pin MLF (ML)。

Technical Data Sheet Chip Phototransistor With Right Angle LensPT12-21C/TR8Features․Fast response time ․High photo sensitivity ․Small junction capacitance ․Package in 8mm tape on 7” diameter reels. ․Pb free ․The product itself will remain within RoHS compliant version.Descriptions․PT12-21C/TR8 is a phototransistor in miniature SMD package which is molded in a water clear with right angle lens. The device is Spectrally matched to visible and infrared emitting diode.Applications․Miniature switch ․Counters and sorter ․Position sensor ․Infrared applied systemDevice Selection Guide LED Part No.PTChip MaterialSiliconLens ColorWater clearEverlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 1 of 10Prepared by：David Huang/PT12-21C/TR8Package DimensionsCollector EmitterNotes: 1.All dimensions are in millimeters 2.Tolerances unless dimensions ±0.1mmAbsolute Maximum Ratings (Ta=25℃)Parameter Collector-Emitter Voltage Emitter-Collector-Voltage Collector Current Operating Temperature Storage Temperature Soldering Temperature *1 Power Dissipation at(or below) 25℃Free Air Temperature Symbol VCEO VECO IC Topr Tstg Tsol Pc Rating 30 5 50 -25 ~ +85 -40 ~ +85 260 75 Units V V mA ℃ ℃ ℃ mWNotes: *1:Soldering time≦5 seconds.Everlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 2 of 10Prepared by：David Huang/PT12-21C/TR8Electro-Optical Characteristics (Ta=25℃)Parameter Rang Of Spectral Bandwidth Wavelength Of Peak Sensitivity Collector-Emitter Breakdown Voltage Emitter-Collector Breakdown Voltage Collector-Emitter Saturation Voltage Collector Dark Current Symbol λ0.5 λP BVCEO BVECO VCE(sat) ICEO Condition ----IC=100μA Ee=0mW/cm2 IE=100μA Ee=0mW/cm2 IC=2mA Ee=1m W/cm2 VCE=20V Ee=0mW/cm2 VCE=5V Ee=1mW /cm2 VCE=5V IC=1mA RL=1000Ω Min 400 --30 5 ----Typ --940 --------Max 1100 ------0.4 100 Unit nm nm V V V nAOn State Collector Current Rise Time Fall TimeIC(ON) tr tf0.3 -----1.14 15 15-----mAμS ---Everlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 3 of 10Prepared by：David Huang/PT12-21C/TR8Typical Electro-Optical Characteristics CurvesFig.1Collector Power Dissipation vs. Ambient Temperature Fig.2 Spectral Sensitivity100 80 60 40 20 01.0 Ta=25 C 0.8 0.6 0.4 0.2 0-250255075 85 100100 300 500 700 900 1100 1300Fig.3 Relative Collector Current vs. Ambient TemperatureFig.4 Collector Current vs. Irradiance160 140 120 100 80 60 40 20 0 0 10 20 30 40 50 60 702100 C 10 1 0.10.01 0.51325Everlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 4 of 10Prepared by：David Huang/PT12-21C/TR8Typical Electro-Optical Characteristics CurvesFig.5 Collector Dark Current vs. Ambient Temperature Fig.6 Collector Current vs. Collector-Emitter Voltage1014 1210 1010 8 610 10 0 25 50 75 1004 2 0 0 1 2 3 4Everlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 5 of 10Prepared by：David Huang/PT12-21C/TR8Precautions For Use1. Over-current-proof Customer must apply resistors for protection , otherwise slight voltage shift will cause big current change ( Burn out will happen ). 2. Storage 2.1 Do not open moisture proof bag before the products are ready to use. 2.2 Before opening the package, the LEDs should be kept at 30℃ or less and 90%RH or less. 2.3 The LEDs should be used within a year. 2.4 After opening the package, the LEDs should be kept at 30℃ or less and 70%RH or less. 2.5 The LEDs should be used within 168 hours (7 days) after opening the package. 2.6 If the moisture absorbent material (silica gel) has faded away or the LEDs have exceeded the storage time, baking treatment should be performed using the following conditions. Baking treatment : 60±5℃ for 24 hours. 3. Soldering Condition 3.1 Pb-free solder temperature profile3.2 Reflow soldering should not be done more than two times. 3.3 When soldering, do not put stress on the LEDs during heating. 3.4 After soldering, do not warp the circuit board.Everlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 6 of 10Prepared by：David Huang/PT12-21C/TR84.Soldering Iron Each terminal is to go to the tip of soldering iron temperature less than 280℃ for 3 seconds within once in less than the soldering iron capacity 25W. Leave two seconds and more intervals, and do soldering of each terminal. Be careful because the damage of the product is often started at the time of the hand solder. 5.Repairing Repair should not be done after the LEDs have been soldered. When repairing is unavoidable, a double-head soldering iron should be used (as below figure). It should be confirmed beforehand whether the characteristics of the LEDs will or will not be damaged by repairing.Everlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 7 of 10Prepared by：David Huang/PT12-21C/TR8Package DimensionsLoaded Quantity Per Reel 2000PCS/ReelCollector EmitterUnit : mmEverlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 8 of 10Prepared by：David Huang/PT12-21C/TR8Reliability Test Item And ConditionThe reliability of products shall be satisfied with items listed below. Confidence level：90% LTPD：10% NO. Item Test Conditions Test Hours/ Cycles 6Mins 50Cycles Sample Failure Sizes Judgement Criteria 22pcs 22pcs IC(ON)≦L×0.8 L：Lower 50Cycles 22pcs Specification Limit 0/1 Ac/Re1 REFLOW Soldering TEMP.：240℃±5℃ 5secs 15mins 2 Temperature Cycle H : +100℃ L : -40℃ 3 Thermal Shock H :+100℃ L :-10℃ 4 High Temperature Storage 5 Low Temperature Storage 5mins 15mins 5mins 10secs 5mins0/1 0/1TEMP.：+100℃ TEMP.：-40℃1000hrs 1000hrs 1000hrs 1000hrs22pcs 22pcs 22pcs 22pcs0/1 0/1 0/1 0/16 DC Operating Life VCE=5V 7 High Temperature/ 85℃ / 85% R.H High HumidityEverlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 9 of 10Prepared by：David Huang/PT12-21C/TR8Packing Quantity Specification1.2000Pcs/1Volume，1Volume/1Bag 2.10Boxes/1CartonLabel Form SpecificationCPN: Customer’s Production Number P/N : Production Number QTY: Packing Quantity CAT: Ranks HUE: Peak Wavelength REF: Reference LOT No: Lot Number MADE IN TAIWAN: Production PlaceRoHSPT12/21C/TR8Notes1. Above specification may be changed without notice. EVERLIGHT will reserve authority on material change for above specification. 2. When using this product, please observe the absolute maximum ratings and the instructions for using outlined in these specification sheets. EVERLIGHT assumes no responsibility for any damage resulting from use of the product which does not comply with the absolute maximum ratings and the instructions included in these specification sheets. 3. These specification sheets include materials protected under copyright of EVERLIGHT corporation. Please don’t reproduce or cause anyone to reproduce them without EVERLIGHT’s consent.EVERLIGHT ELECTRONICS CO., LTD. Office: No 25, Lane 76, Sec 3, Chung Yang Rd, Tucheng, Taipei 236, Taiwan, R.O.CTel: 886-2-2267-2000, 2267-9936 Fax: 886-2267-6244, 2267-6189, 2267-6306 http:\\Everlight Electronics Co., Ltd. Device No：DTT-012-083http:\\ Prepared date：07-20-2005Rev 2Page: 10 of 10Prepared by：David Huang/分销商库存信息: EVERLIGHTPT12-21C/TR8。

Type 401C –55 °C to 105 °C Low-ESR, Wide Temperature Grade2,000 h at 85 °C per EIA IS-749 with 85 ºC ripple current∆ Capacitance ±10% ESR 200% of limit DCL 100% of limit4,000 h at 105ºC with rated voltage∆ Capacitance ±10% ESR 200% of limit DCL 100% of limit500 h at +105 °C, capacitance, ESR and DCL, will meet initialrequirements10 to 55 Hz, 0.06” and 10 g max, 2 h each planeThe Type 401C is the wide-temperature, low-voltage version of the Type 450C. It is ideal for high-ripple current military and industrial applications that need full performance at cold temperatures. It also excels as a power-supply output capacitor because of its exceptionally low ESR. The extended cathode foil of the 401C assures cool operation and heat flow from the capacitor element to the can in all mounting orientations.Highlights• Better value than large snap-in capacitors • Ripple Currents to >50 amps at 55 °C • ESRs to 3.5 m Ω• > 90% capacitance at –40 °C• Thermal-Pak™ extended cathode constructionSpecificationsOperating Temperature:Rated Voltage:Capacitance:DC Leakage Current:Cold Impedance:Ripple Current Multipliers:EIA Ripple Life:Life Test:Shelf Life Test: Vibration: The Ultimate in Cold Performance and ESRFrequency–55 °C to 105 °C 6.3 to 250 Vdc380 µF to 570,000 µF ± 20%≤ 1.5 √CV µA, 4 mA max, 5 minutes –55 °C multiple of 25 °C Z ≤ 3Ambient Temperature45 °C 55 °C 65 °C 75 °C 85 ºC 95 ºC 105 °C 1.661.521.371.201.000.750.3650 Hz 60 Hz 120 Hz 360 Hz 1 kHz 5 kHz 10 kHz & up6.3 to 50 V 0.850.90 1.00 1.05 1.10 1.10 1.1063 to 250 V0.500.531.001.151.151.201.20Complies with the EU Directive 2002/95/EC requirementrestricting the use of Lead (Pb), Mercury (Hg), Cadmium (Cd), Hexavalent chromium (Cr(VI)), PolyBrominated Biphenyls (PBB) and PolyBrominated Diphenyl Ethers (PBDE).元器件交易网Type 401C –55 °C to 105 °C Low-ESR, Wide Temperature GradeOutline DrawingsCase DimensionsPart Numbering System401CType Terminal8InsulationAKCase Code100Voltage M Tolerance393Capacitance(blank) = Straight Leads 0 = Bare can8 = PVC andStandoffs9 = Polyester and Standoffs100 = 100 V 450 = 100 V M = ±20%T = –10% +50% U = –10% +75%242 = 2400 µF 221 = 220 µFCase InchesMillimeters Code D ± .031 L MAX C ± .015 S ± .031 E ± .031 F ± .015 D ± .78 L MAX C ± .78 S ± .78 E ± .78 F ± .38AK 1.375 1.750.500.1750.250.5534.9344.4512.70 4.45 6.3513.97 AA 1.375 2.250.500.1750.250.5534.9357.1512.70 4.45 6.3513.97 AH 1.375 2.750.500.1750.250.5534.9869.8512.70 4.45 6.3513.97 AB 1.375 3.250.500.1750.250.5534.9382.5512.70 4.45 6.3513.97 AJ 1.375 3.750.500.1750.250.5534.9395.2512.70 4.45 6.3513.97 AC 1.375 4.250.500.1750.250.5534.93107.9512.70 4.45 6.3513.97 AD 1.375 4.750.500.1750.250.5534.93120.6512.70 4.45 6.3513.97 AE 1.375 5.250.500.1750.250.5534.93133.3512.70 4.45 6.3513.97 AF 1.375 5.750.500.1750.250.5534.93146.0512.70 4.45 6.3513.97 EA 1.75 2.250.700.3750.350.9044.4557.1517.789.538.8922.86 EH 1.75 2.750.700.3750.350.9044.4569.8517.789.538.8922.86 EB 1.75 3.250.700.3750.350.9044.4582.5517.789.538.8922.86 EJ 1.75 3.750.700.3750.350.9044.4595.2517.789.538.8922.86 EC 1.75 4.250.700.3750.350.9044.45107.9517.789.538.8922.86 ED 1.75 4.750.700.3750.350.9044.45120.6517.789.538.8922.86 EE 1.75 5.250.700.3750.350.9044.45133.3517.789.538.8922.86 EF 1.75 5.750.700.3750.350.9044.45146.0517.789.538.8922.86 BA 2.00 2.250.800.4250.40 1.0050.8057.1520.3210.8010.1625.40 BH 2.00 2.750.800.4250.40 1.0050.8069.8520.3210.8010.1625.40 BB 2.00 3.250.800.4250.40 1.0050.8082.5520.3210.8010.1625.40 BJ 2.00 3.750.800.4250.40 1.0050.8095.2520.3210.8010.1625.40 BC 2.00 4.250.800.4250.40 1.0050.80107.9520.3210.8010.1625.40 BD 2.00 4.750.800.4250.40 1.0050.80120.6520.3210.8010.1625.40 BE 2.00 5.250.800.4250.40 1.0050.80133.2520.3210.8010.1625.40 BF2.005.750.800.4250.401.0050.80146.0520.3210.8010.1625.40元器件交易网Type 401C –55 °C to 105 °C Low-ESR, Wide Temperature GradeTypical Performance Curves元器件交易网Type 401C –55 °C to 105 °C Low-ESR, Wide Temperature Grade RatingsESR Max.25 ºC 120 Hz 20kHz Ripple Amps,85 ºC120 Hz 20 kHz(A) (A)NominalSizeD X L(in)ESR Max.25 ºC120 Hz 20kHzRipple Amps,85 ºC120 Hz 20 kHz(A) (A)NominalSizeD X L(in)Cap. (µF)Catalog PartNumberCap.(µF)Catalog PartNumber6.3 Vdc (9 Vdc Surge) 380000401C384M7R5EE87.20 5.1027.5030.50 1 3/4 X 5 1/842000401C423M6R3AK8 33.4022.708.409.20 1 3/8 X 1 5/8 420000401C424M7R5BD8 5.20 3.9030.9033.40 2 X 4 5/8 66000401C663M6R3AA8 23.0016.1010.8011.80 1 3/8 X 2 1/8 440000401C444M7R5EF8 6.70 4.8030.3033.40 1 3/4 X 5 5/8 92000401C923M6R3AH8 16.8012.0013.0014.20 1 3/8 X 2 5/8 500000401C504M7R5BE8 4.80 3.6032.6035.80 2 X 5 1/8 100000401C104M6R3EA8 21.2015.0011.9013.40 1 3/4 X 2 1/8 560000401C564M7R5BF8 4.50 3.5034.0037.90 2 X 5 5/8 120000401C124M6R3AB8 14.608.5015.4017.00 1 3/8 X 3 1/8 10 Vdc (15 Vdc Surge)140000401C144M6R3AJ8 12.307.3017.7019.20 1 3/8 X 3 5/8 31000401C313M010AK8 33.4022.708.409.20 1 3/8 X 1 5/8 150000401C154M6R3BA8 12.7010.3016.4017.20 2 X 2 1/8 50000401C503M010AA8 23.0016.1010.8011.80 1 3/8 X 2 1/8 150000401C154M6R3EH8 15.1010.7015.1016.90 1 3/4 X 2 5/8 69000401C693M010AH8 16.8012.0013.0014.20 1 3/8 X 2 5/8 170000401C174M6R3AC8 10.80 6.4019.7021.30 1 3/8 X 4 1/8 81000401C813M010EA8 21.2013.3011.9013.40 1 3/4 X 2 1/8 200000401C204M6R3AD8 9.70 5.8021.5023.10 1 3/8 X 4 5/8 91000401C913M010AB8 14.609.5015.4017.00 1 3/8 X 3 1/8 200000401C204M6R3BH8 9.307.3020.5022.10 2 X 2 5/8 110000401C114M010AJ8 12.308.0017.7019.20 1 3/8 X 3 5/8 200000401C204M6R3EB8 11.908.4018.2020.40 1 3/4 X 3 1/8 110000401C114M010BA8 12.7010.3016.4017.20 2 X 2 1/8 230000401C234M6R3AE8 9.00 5.4023.3024.90 1 3/8 X 5 1/8 120000401C124M010EH8 15.109.5015.1016.90 1 3/4 X 2 5/8 250000401C254M6R3BB8 7.40 5.8024.2026.00 2 X 3 1/8 130000401C134M010AC8 10.807.1019.7021.30 1 3/8 X 4 1/8 250000401C254M6R3EJ8 10.007.1020.5022.80 1 3/4 X 3 5/8 150000401C154M010AD8 9.70 6.4021.5023.10 1 3/8 X 4 5/8 260000401C264M6R3AF8 8.40 5.1025.1026.70 1 3/8 X 5 5/8 150000401C154M010BH8 9.307.3020.5022.10 2 X 2 5/8 290000401C294M6R3EC8 8.70 6.2022.6025.20 1 3/4 X 4 1/8 150000401C154M010EB8 11.907.5018.2020.40 1 3/4 X 3 1/8 310000401C314M6R3BJ8 6.50 4.9026.6028.80 2 X 3 5/8 170000401C174M010AE8 9.00 5.9023.3024.90 1 3/8 X 5 1/8 350000401C354M6R3ED8 7.80 5.6025.0027.80 1 3/4 X 4 5/8 180000401C184M010EJ8 10.00 6.3020.5022.80 1 3/4 X 3 5/8 370000401C374M6R3BC8 5.70 4.3029.0030.80 2 X 4 1/8 190000401C194M010AF8 8.40 5.6025.1026.70 1 3/8 X 5 5/8 390000401C394M6R3EE8 7.20 5.1027.5030.50 1 3/4 X 5 1/8 190000401C194M010BB8 7.40 5.8024.2026.00 2 X 3 1/8 420000401C424M6R3BD8 5.20 3.9030.9033.40 2 X 4 5/8 230000401C234M010EC8 8.70 5.5022.6025.20 1 3/4 X 4 1/8 440000401C444M6R3EF8 6.70 4.8030.3033.40 1 3/4 X 5 5/8 240000401C244M010BJ8 6.50 4.9026.6028.80 2 X 3 5/8 510000401C514M6R3BE8 4.80 3.6032.6035.80 2 X 5 1/8 260000401C264M010ED8 7.80 5.0025.0027.80 1 3/4 X 4 5/8 570000401C574M6R3BF8 4.50 3.5034.0037.90 2 X 5 5/8 280000401C284M010BC8 5.70 4.3029.0030.80 2 X 4 1/87.5 Vdc (10 Vdc Surge) 290000401C294M010EE8 7.20 4.6027.5030.50 1 3/4 X 5 1/841000401C413M7R5AK8 33.4022.708.409.20 1 3/8 X 1 5/8 330000401C334M010BD8 5.20 3.9030.9033.40 2 X 4 5/862000401C623M7R5AA8 23.0016.1010.8011.80 1 3/8 X 2 1/8 340000401C344M010EF8 6.70 4.3030.3033.40 1 3/4 X 5 5/8 90000401C903M7R5AH8 16.8012.0013.0014.20 1 3/8 X 2 5/8 390000401C394M010BE8 4.80 3.6032.6035.80 2 X 5 1/8 100000401C104M7R5EA8 21.2015.0011.9013.40 1 3/4 X 2 1/8 440000401C444M010BF8 4.50 3.5034.0037.90 2 X 5 5/8 120000401C124M7R5AB8 14.609.5015.4017.00 1 3/8 X 3 1/8 16 Vdc (24 Vdc Surge)140000401C144M7R5AJ8 12.308.0017.7019.20 1 3/8 X 3 5/8 20000401C203M016AK8 34.7023.008.309.10 1 3/8 X 1 5/8 140000401C144M7R5BA8 12.7010.3016.4017.20 2 X 2 1/8 33000401C333M016AA8 23.9016.3010.6011.70 1 3/8 X 2 1/8 150000401C154M7R5EH8 15.1010.7015.1016.90 1 3/4 X 2 5/8 46000401C463M016AH8 17.4011.2012.8014.20 1 3/8 X 2 5/8 170000401C174M7R5AC8 10.807.1019.7021.30 1 3/8 X 4 1/8 53000401C533M016EA8 21.5015.9011.8013.30 1 3/4 X 2 1/8 190000401C194M7R5AD8 9.70 6.4021.5023.10 1 3/8 X 4 5/8 60000401C603M016AB8 14.908.9015.2016.90 1 3/8 X 3 1/8 190000401C194M7R5BH8 9.307.3020.5022.10 2 X 2 5/8 74000401C743M016AJ8 12.507.5017.5019.10 1 3/8 X 3 5/8 190000401C194M7R5EB8 11.908.4018.2020.40 1 3/4 X 3 1/8 75000401C753M016BA8 12.7010.2016.4017.40 2 X 2 1/8 230000401C234M7R5AE8 9.00 5.9023.3024.90 1 3/8 X 5 1/8 78000401C783M016EH8 15.3011.3014.9016.80 1 3/4 X 2 5/8 240000401C244M7R5EJ8 10.007.1020.5022.80 1 3/4 X 3 5/8 89000401C893M016AC8 11.00 6.6019.5021.20 1 3/8 X 4 1/8 250000401C254M7R5AF8 8.40 5.6025.1026.70 1 3/8 X 5 5/8 100000401C104M016AD8 9.407.3020.4022.10 2 X 2 5/8 250000401C254M7R5BB8 7.40 5.8024.2026.00 2 X 3 1/8 100000401C104M016BH8 12.008.9018.1020.30 1 3/4 X 3 1/8 290000401C294M7R5EC8 8.70 6.2022.6025.20 1 3/4 X 4 1/8 100000401C104M016EB8 9.90 6.0021.3023.00 1 3/8 X 4 5/8 300000401C304M7R5BJ8 6.50 4.9026.6028.80 2 X 3 5/8 120000401C124M016AE8 9.10 5.5023.1024.80 1 3/8 X 5 1/8 340000401C344M7R5ED8 7.80 5.6025.0027.80 1 3/4 X 4 5/8 130000401C134M016AF8 8.60 5.2024.9026.60 1 3/8 X 5 5/8 370000401C374M7R5BC8 5.70 4.3029.0030.80 2 X 4 1/8 130000401C134M016BB8 7.50 5.8024.0026.00 2 X 3 1/8 元器件交易网Type 401C –55 °C to 105 °C Low-ESR, Wide Temperature GradeESR Max.25 ºC 120 Hz 20 kHz (mΩ) (mΩ)Ripple Amps,85 ºC120 Hz 20 kHz(A) (A)NominalSizeD X L(in)ESR Max.25 ºC120 Hz 20 kHz(mΩ) (mΩ)Ripple Amps,85 ºC120 Hz 20 kHz(A) (A)NominalSizeD X L(in)Cap. (µF)Catalog PartNumberCap.(µF)Catalog PartNumber130000401C134M016EJ8 10.107.5020.3022.80 1 3/4 X 3 5/8 66000401C663M025AD8 10.70 6.8020.4022.80 1 3/8 X 4 5/8 150000401C154M016EC8 8.80 6.6022.5025.10 1 3/4 X 4 1/8 66000401C663M025EB8 12.808.8017.5020.20 1 3/4 X 3 1/8 160000401C164M016BJ8 6.60 5.0026.4028.80 2 X 3 5/8 75000401C753M025AE8 9.90 6.3022.2024.60 1 3/8 X 5 1/8 170000401C174M016ED8 7.90 6.0024.9027.70 1 3/4 X 4 5/8 81000401C813M025EJ8 10.707.4019.7022.60 1 3/4 X 3 5/8 180000401C184M016BC8 5.80 4.4028.8030.70 2 X 4 1/8 83000401C833M025BB8 8.00 6.1023.4025.80 2 X 3 1/8 190000401C194M016EE8 7.30 5.5027.4030.40 1 3/4 X 5 1/8 84000401C843M025AF8 9.20 5.9023.9026.40 1 3/8 X 5 5/8 220000401C224M016BD8 5.20 4.0030.7033.30 2 X 4 5/8 96000401C963M025EC8 9.30 6.5021.8025.00 1 3/4 X 4 1/8 220000401C224M016EF8 6.80 5.2030.1033.40 1 3/4 X 5 5/8 100000401C104M025BJ8 7.00 5.1025.7028.60 2 X 3 5/8 260000401C264M016BE8 4.80 3.7032.4035.70 2 X 5 1/8 110000401C114M025ED8 8.40 5.8024.2027.50 1 3/4 X 4 5/8 280000401C284M016BF8 4.60 3.5033.8037.90 2 X 5 5/8 120000401C124M025BC8 6.10 4.5028.1030.60 2 X 4 1/820 Vdc (30 Vdc Surge) 130000401C134M025EE8 7.70 5.3026.6030.20 1 3/4 X 5 1/817000401C173M020AK8 37.9023.708.409.10 1 3/8 X 1 5/8 140000401C144M025BD8 5.50 4.1029.9033.20 2 X 4 5/8 26000401C263M020AA8 26.0016.8010.9011.70 1 3/8 X 2 1/8 140000401C144M025EF8 7.10 5.0029.3033.20 1 3/4 X 5 5/8 33000401C333M020AH8 18.9012.4013.2014.10 1 3/8 X 2 5/8 160000401C164M025BE8 5.10 3.8031.7035.60 2 X 5 1/8 45000401C453M020EA8 22.3015.5011.6013.30 1 3/4 X 2 1/8 180000401C184M025BF8 4.80 3.6033.1037.70 2 X 5 5/8 50000401C503M020AB8 15.609.9015.1016.80 1 3/8 X 3 1/8 40 Vdc (60 Vdc Surge)58000401C583M020BA8 13.2010.4016.1017.30 2 X 2 1/8 8200401C822M040AK8 44.2025.907.608.80 1 3/8 X 1 5/8 61000401C613M020AJ8 13.108.3017.1019.00 1 3/8 X 3 5/8 12000401C123M040AA8 30.2018.309.7011.40 1 3/8 X 2 1/8 64000401C643M020EH8 15.8011.0014.7016.80 1 3/4 X 2 5/8 20000401C203M040EA8 24.7016.5011.0013.10 1 3/4 X 2 1/8 73000401C733M020AC8 11.507.3019.1021.10 1 3/8 X 4 1/822000401C223M040AH8 22.1013.6011.9013.80 1 3/8 X 2 5/8 82000401C823M020BH8 9.807.5020.1022.00 2 X 2 5/823000401C233M040AB8 17.8010.7013.7016.50 1 3/8 X 3 1/8 84000401C843M020EB8 12.408.7017.8020.30 1 3/4 X 3 1/8 27000401C273M040BA8 14.7011.1015.1017.10 2 X 2 1/8 85000401C853M020AD8 10.30 6.6020.9022.90 1 3/8 X 4 5/828000401C283M040AJ8 14.909.0015.2018.60 1 3/8 X 3 5/8 96000401C963M020AE8 9.50 6.1022.6024.70 1 3/8 X 5 1/830000401C303M040EH8 17.5011.7013.9016.50 1 3/4 X 2 5/8 100000401C104M020AF8 10.407.3020.0022.70 1 3/4 X 3 5/834000401C343M040AC8 13.007.9016.5020.70 1 3/8 X 4 1/8 100000401C104M020BB8 7.70 5.9023.7025.90 2 X 3 1/838000401C383M040BH8 10.808.0019.0021.80 2 X 2 5/8 100000401C104M020EJ8 8.90 5.8024.4026.50 1 3/8 X 5 5/839000401C393M040AD8 11.607.1018.1022.50 1 3/8 X 4 5/8 120000401C124M020EC8 9.10 6.4022.1025.00 1 3/4 X 4 1/839000401C393M040EB8 13.709.2016.9020.00 1 3/4 X 3 1/8 130000401C134M020BJ8 6.80 5.0026.0028.70 2 X 3 5/8 45000401C453M040AE8 10.70 6.6019.7024.30 1 3/8 X 5 1/8 140000401C144M020ED8 8.10 5.7024.5027.60 1 3/4 X 4 5/849000401C493M040EJ8 11.407.7019.1022.50 1 3/4 X 3 5/8 150000401C154M020BC8 6.00 4.5028.5030.70 2 X 4 1/8 50000401C503M040BB8 8.60 6.3022.5025.70 2 X 3 1/8 160000401C164M020EE8 7.50 5.3027.0030.30 1 3/4 X 5 1/850000401C503M040AF8 9.90 6.2021.3026.10 1 3/8 X 5 5/8 170000401C174M020BD8 5.40 4.0030.3033.20 2 X 4 5/8 58000401C583M040EC8 9.90 6.7021.1024.80 1 3/4 X 4 1/8 180000401C184M020EF8 7.00 4.9029.7033.30 1 3/4 X 5 5/8 61000401C613M040BJ8 7.50 5.3025.0028.40 2 X 3 5/8 220000401C224M020BE8 4.90 3.7032.1035.70 2 X 5 1/8 68000401C683M040ED8 8.90 6.0023.4027.40 1 3/4 X 4 5/8 240000401C244M020BF8 4.70 3.5033.5037.80 2 X 5 5/8 73000401C733M040BC8 6.50 4.7027.0030.40 2 X 4 1/825 Vdc (35 Vdc Surge) 77000401C773M040EE8 8.10 5.5025.9030.00 1 3/4 X 5 1/813000401C133M025AK8 41.0024.408.109.00 1 3/8 X 1 5/884000401C843M040BD8 5.90 4.2029.1033.00 2 X 4 5/8 20000401C203M025AA8 28.1017.2010.5011.60 1 3/8 X 2 1/8 86000401C863M040EF8 7.60 5.2028.5033.00 1 3/4 X 5 5/8 33000401C333M025AH8 20.3012.8012.8014.00 1 3/8 X 2 5/8 100000401C104M040BE8 5.40 3.9030.9035.40 2 X 5 1/8 35000401C353M025EA8 23.0015.8011.4013.20 1 3/4 X 2 1/8110000401C114M040BF8 5.10 3.7031.8037.50 2 X 5 5/8 38000401C383M025AB8 16.3010.1014.6016.70 1 3/8 X 3 1/8 50 Vdc (75 Vdc Surge)45000401C453M025BA8 13.6010.6015.9017.30 2 X 2 1/85600401C562M050AK8 46.6027.307.208.40 1 3/8 X 1 5/8 48000401C483M025AJ8 13.608.5016.7018.90 1 3/8 X 3 5/88400401C842M050AA8 30.2019.309.2010.80 1 3/8 X 2 1/8 50000401C503M025EH8 16.3011.2014.4016.70 1 3/4 X 2 5/811000401C113M050AH8 22.5014.3011.6013.10 1 3/8 X 2 5/8 57000401C573M025AC8 11.907.5018.7021.00 1 3/8 X 4 1/814000401C143M050EA8 28.3018.9010.0011.80 1 3/4 X 2 1/8 63000401C633M025BH8 10.107.6019.8021.90 2 X 2 5/815000401C153M050AB8 18.1011.3013.4015.70 1 3/8 X 3 1/8 元器件交易网Type 401C –55 °C to 105 °C Low-ESR, Wide Temperature GradeESR Max.25 ºC 120 Hz 20 kHz (mΩ) (mΩ)Ripple Amps,85 ºC120 Hz 20 kHz(A) (A)NominalSizeD X L(in)ESR Max.25 ºC120 Hz 20 kHz(mΩ) (mΩ)Ripple Amps,85 ºC120 Hz 20 kHz(A) (A)NominalSizeD X L(in)Cap. (µF)Catalog PartNumberCap.(µF)Catalog PartNumber18000401C183M050BA8 18.7014.4012.4014.80 2 X 2 1/8 75 Vdc (100 Vdc Surge)19000401C193M050AJ8 15.109.5014.6017.80 1 3/8 X 3 5/8 2500401C252M075AK8 93.8046.00 5.70 6.40 1 3/8 X 1 5/8 20000401C203M050EH8 20.0013.4012.7015.00 1 3/4 X 2 5/8 4100401C412M075AA8 59.0029.107.608.60 1 3/8 X 2 1/8 23000401C233M050AC8 13.008.3015.3019.90 1 3/8 X 4 1/8 6600401C662M075AH8 39.8019.709.7010.70 1 3/8 X 2 5/8 26000401C263M050BH8 13.7010.2015.9018.90 2 X 2 5/8 7900401C792M075EA8 41.0021.209.0010.70 1 3/4 X 2 1/8 27000401C273M050AD8 12.207.4016.7021.70 1 3/8 X 4 5/8 8200401C822M075AB8 30.3015.1011.4013.10 1 3/8 X 3 1/8 27000401C273M050EB8 15.6010.5015.5018.20 1 3/4 X 3 1/8 10000401C103M075BA8 30.8017.509.0014.30 2 X 2 1/8 30000401C303M050AE8 11.20 6.8018.1023.40 1 3/8 X 5 1/8 10000401C103M075AJ8 24.6012.4012.2015.00 1 3/8 X 3 5/8 33000401C333M050EJ8 13.008.8017.6020.50 1 3/4 X 3 5/8 11000401C113M075EH8 28.7014.9011.4013.60 1 3/4 X 2 5/8 34000401C343M050AF8 10.40 6.4019.4025.20 1 3/8 X 5 5/8 12000401C123M075AC8 20.9010.7012.9017.00 1 3/8 X 4 1/8 34000401C343M050BB8 10.808.1018.9022.40 2 X 3 1/8 14000401C143M075BH8 18.309.4014.2018.70 1 3/8 X 4 5/8 39000401C393M050EC8 11.207.6019.5022.70 1 3/4 X 4 1/8 14000401C143M075AD8 21.7012.3013.0017.80 2 X 2 5/8 41000401C413M050BJ8 9.30 6.8022.6025.00 2 X 3 5/8 15000401C153M075EB8 22.3011.7013.9016.60 1 3/4 X 3 1/8 46000401C463M050ED8 10.00 6.8021.7025.20 1 3/4 X 4 5/8 16000401C163M075AE8 16.308.5015.5020.40 1 3/8 X 5 1/8 50000401C503M050BC8 8.10 5.9024.3026.90 2 X 4 1/8 18000401C183M075BB8 14.907.9016.9022.20 1 3/8 X 5 5/8 52000401C523M050EE8 9.10 6.2024.1027.80 1 3/4 X 5 1/8 18000401C183M075EJ8 18.309.7015.8018.70 1 3/4 X 3 5/8 58000401C583M050EF8 8.40 5.8026.6030.60 1 3/4 X 5 5/8 18000401C183M075AF8 16.809.7015.4021.60 2 X 3 1/8 58000401C583M050BD8 7.20 5.3026.1029.20 2 X 4 5/8 22000401C223M075EC8 15.708.3017.6020.80 1 3/4 X 4 1/8 60000401C603M050BE8 6.50 4.8028.0031.70 2 X 5 1/8 23000401C233M075BJ8 13.908.1021.3024.10 2 X 3 5/8 70000401C703M050BF8 6.10 4.5028.9033.90 2 X 5 5/8 25000401C253M075ED8 13.807.4019.7023.20 1 3/4 X 4 5/863 Vdc (90 Vdc Surge) 27000401C273M075BC8 12.007.0020.4026.00 2 X 4 1/84800401C482M063AK8 50.0028.20 6.908.30 1 3/8 X 1 5/8 28000401C283M075EE8 12.40 6.7021.8025.70 1 3/4 X 5 1/8 7200401C722M063AA8 32.4019.608.9010.70 1 3/8 X 2 1/8 31000401C313M075BD8 10.60 6.2022.3028.30 2 X 4 5/8 11000401C113M063AH8 24.1014.7011.2013.00 1 3/8 X 2 5/8 33000401C333M075EF8 12.80 6.2024.3028.40 1 3/4 X 5 5/8 12000401C123M063EA8 26.0019.309.9011.80 1 3/4 X 2 1/8 37000401C373M075BE8 9.30 5.6024.4030.80 2 X 5 1/8 13000401C133M063AB8 19.0011.6013.0015.60 1 3/8 X 3 1/8 41000401C413M075BF8 8.60 5.2026.2032.90 2 X 5 5/8 15000401C153M063BA8 19.3014.7011.9014.80 2 X 2 1/8 100 Vdc (140 Vdc Surge)16000401C163M063AJ8 15.809.7014.2017.70 1 3/8 X 3 5/8 1400401C142M100AK8 118.0034.70 4.30 6.20 1 3/8 X 1 5/8 17000401C173M063EH8 18.3013.7012.5014.90 1 3/4 X 2 5/8 2200401C222M100AA8 73.1020.90 5.908.50 1 3/8 X 2 1/8 19000401C193M063AC8 13.608.5014.9019.80 1 3/8 X 4 1/8 3500401C352M100AH8 46.5014.007.5010.60 1 3/8 X 2 5/8 22000401C223M063BH8 14.1010.4015.3018.90 2 X 2 5/8 4100401C412M100EA8 44.7017.508.0010.30 1 3/4 X 2 1/8 23000401C233M063EB8 12.707.6016.3021.50 1 3/8 X 4 5/8 4600401C462M100AB8 36.0011.009.1012.90 1 3/8 X 3 1/8 23000401C233M063AD8 14.3010.7015.3018.10 1 3/4 X 3 1/8 5300401C532M100BA8 37.5016.508.2011.90 2 X 2 1/8 26000401C263M063AE8 11.607.0017.7023.30 1 3/8 X 5 1/8 5700401C572M100AJ8 29.609.2010.5014.70 1 3/8 X 3 5/8 28000401C283M063EJ8 11.908.9017.3020.40 1 3/4 X 3 5/8 6000401C602M100EH8 31.3012.4010.2013.10 1 3/4 X 2 5/8 29000401C293M063BB8 10.80 6.6019.1025.10 1 3/8 X 5 5/8 6800401C682M100AC8 25.308.1011.9016.50 1 3/8 X 4 1/8 29000401C293M063AF8 11.108.2018.1022.40 2 X 3 1/8 7500401C752M100BH8 26.3011.7010.6015.30 2 X 2 5/8 34000401C343M063EC8 10.307.7019.2022.60 1 3/4 X 4 1/8 7900401C792M100EB8 22.207.2013.2018.10 1 3/8 X 4 5/8 36000401C363M063BJ8 9.60 6.9022.2024.90 2 X 3 5/8 7900401C792M100AD8 24.209.7012.5015.90 1 3/4 X 3 1/8 39000401C393M063ED8 9.20 6.9021.4025.10 1 3/4 X 4 5/8 9000401C902M100AE8 19.90 6.6014.5019.80 1 3/8 X 5 1/8 42000401C423M063BC8 8.30 6.0024.0026.80 2 X 4 1/8 9700401C972M100EJ8 19.908.1014.1018.00 1 3/4 X 3 5/8 45000401C453M063EE8 8.30 6.3023.7027.70 1 3/4 X 5 1/8 10000401C103M100BB8 20.409.2012.6018.20 2 X 3 1/8 50000401C503M063BD8 7.70 5.9026.3030.50 1 3/4 X 5 5/8 10000401C103M100AF8 18.10 6.2015.8021.40 1 3/8 X 5 5/8 50000401C503M063EF8 7.40 5.4025.8029.10 2 X 4 5/8 12000401C123M100BJ8 15.80 6.9016.3023.60 2 X 4 1/8 59000401C593M063BE8 6.70 4.8027.7031.70 2 X 5 1/8 12000401C123M100EC8 17.007.0015.8020.00 1 3/4 X 4 1/8 66000401C663M063BF8 6.20 4.5028.6033.80 2 X 5 5/8 12000401C123M100BC8 16.907.6015.5022.30 2 X 3 5/8 元器件交易网Type 401C –55 °C to 105 °C Low-ESR, Wide Temperature GradeESR Max.25 ºC 120 Hz 20 kHz (mΩ) (mΩ)Ripple Amps,85 ºC120 Hz 20 kHz(A) (A)NominalSizeD X L(in)ESR Max.25 ºC120 Hz 20 kHz(mΩ) (mΩ)Ripple Amps,85 ºC120 Hz 20 kHz(A) (A)NominalSizeD X L(in)Cap. (µF)Catalog PartNumberCap.(µF)Catalog PartNumber13000401C133M100ED8 14.90 6.2017.6022.20 1 3/4 X 4 5/8 2500401C252M200EB8 89.0058.108.4010.80 2 X 2 5/8 15000401C153M100BD8 13.40 5.7019.6024.60 1 3/4 X 5 1/8 2500401C252M200AD8 81.8054.407.7011.00 1 3/8 X 4 5/8 15000401C153M100EE8 13.60 6.3017.9025.60 2 X 4 5/8 2500401C252M200BH8 80.4055.607.6010.90 1 3/4 X 3 1/8 17000401C173M100EF8 13.80 5.3021.8027.20 1 3/4 X 5 5/8 2800401C282M200AE8 75.4049.208.6012.00 1 3/8 X 5 1/8 18000401C183M100BE8 11.80 5.5019.8028.10 2 X 5 1/8 3100401C312M200EJ8 65.4045.208.7012.40 1 3/4 X 3 5/8 20000401C203M100BF8 10.80 5.1021.4030.30 2 X 5 5/8 3300401C332M200AF8 66.6044.7010.1012.90 2 X 3 1/8 150 Volts (200 Volts Surge) 3300401C332M200BB8 70.1045.109.5012.90 1 3/8 X 5 5/8 710401C711M150AK8 342.00245.00 2.60 3.60 1 3/8 X 1 5/8 3700401C372M200EC8 55.2038.209.8013.90 1 3/4 X 4 1/8 1100401C112M150AA8 228.00164.00 3.70 5.00 1 3/8 X 2 1/8 4000401C402M200BJ8 53.9036.4012.0015.90 2 X 3 5/8 1500401C152M150AH8 159.00114.00 4.50 6.30 1 3/8 X 2 5/8 4400401C442M200ED8 47.8033.2011.0015.60 1 3/4 X 4 5/8 1700401C172M150EA8 145.00101.00 5.307.10 1 3/4 X 2 1/8 4800401C482M200BC8 45.5030.8012.9017.30 2 X 4 1/8 1900401C192M150AB8 122.0087.20 5.507.70 1 3/8 X 3 1/8 4900401C492M200EE8 42.3029.4012.4017.50 1 3/4 X 5 1/8 2500401C252M150AJ8 112.0078.807.008.60 2 X 2 1/8 5500401C552M200EF8 42.1027.4014.0018.90 2 X 4 5/8 2500401C252M150BA8 98.8071.00 6.408.90 1 3/8 X 3 5/8 5500401C552M200BD8 38.0026.4013.9019.50 1 3/4 X 5 5/8 2600401C262M150EH8 100.0070.30 6.709.00 1 3/4 X 2 5/8 6200401C622M200BE8 37.7024.3014.8020.60 2 X 5 1/8 2900401C292M150AC8 83.4059.907.4010.20 1 3/8 X 4 1/8 7000401C702M200BF8 34.3021.9015.5022.20 2 X 5 5/8 3400401C342M150AD8 80.2057.008.9011.00 2 X 2 5/8 250 Vdc (300 Vdc Surge)3400401C342M150EB8 77.0054.008.3011.10 1 3/4 X 3 1/8 380401C381M250AK8 510.00285.00 2.20 3.30 1 3/8 X 1 5/8 3400401C342M150BH8 72.3052.008.2011.30 1 3/8 X 4 5/8 610401C611M250AA8 309.00190.00 3.10 4.70 1 3/8 X 2 1/8 3900401C392M150AE8 63.9046.009.2012.40 1 3/8 X 5 1/8 860401C861M250AH8 215.00132.00 3.90 6.00 1 3/8 X 2 5/8 4200401C422M150EJ8 62.6043.909.5012.60 1 3/4 X 3 5/8 960401C961M250EA8 222.00113.00 4.40 6.60 1 3/4 X 2 1/8 4400401C442M150AF8 62.9041.4010.1013.50 1 3/8 X 5 5/8 1100401C112M250AB8 165.00101.00 4.707.30 1 3/8 X 3 1/8 4500401C452M150BB8 60.1044.2010.7013.20 2 X 3 1/8 1300401C132M250AJ8 134.0082.50 5.508.30 1 3/8 X 3 5/8 5000401C502M150EC8 52.9037.2010.7014.10 1 3/4 X 4 1/8 1400401C142M250EH8 149.0091.20 5.908.30 2 X 2 1/8 5500401C552M150BJ8 48.6036.3012.9016.20 2 X 3 5/8 1400401C142M250BA8 154.0078.60 5.608.50 1 3/4 X 2 5/8 5800401C582M150ED8 45.9032.3012.0015.80 1 3/4 X 4 5/8 1700401C172M250AC8 101.0062.40 6.9010.30 1 3/8 X 4 5/8 6600401C662M150BC8 41.1031.2013.7017.60 2 X 4 1/8 1700401C172M250AD8 100.0062.20 6.6010.00 1 3/8 X 4 1/8 6700401C672M150EE8 40.6028.6013.5017.50 1 3/4 X 5 1/8 1800401C182M250EB8 118.0060.40 6.9010.40 1 3/4 X 3 1/8 7300401C732M150BD8 38.0028.0014.7019.20 2 X 4 5/8 1900401C192M250BH8 103.0063.307.6010.60 2 X 2 5/8 7400401C742M150EF8 36.5025.7015.1019.30 1 3/4 X 5 5/8 2000401C202M250AE8 88.8054.907.7011.20 1 3/8 X 5 1/8 8400401C842M150BE8 34.1025.2015.7020.90 2 X 5 1/8 2300401C232M250EJ8 79.3049.208.6012.20 1 3/8 X 5 5/8 9400401C942M150BF8 31.0023.0016.8022.60 2 X 5 5/8 2300401C232M250AF8 96.0049.107.9011.80 1 3/4 X 3 5/8 200 Vdc (250 Vdc Surge) 2500401C252M250BB8 79.3048.709.1012.70 2 X 3 1/8 520401C521M200AK8 370.00233.00 2.50 3.50 1 3/8 X 1 5/8 2800401C282M250EC8 81.0041.508.9013.30 1 3/4 X 4 1/8 810401C811M200AA8 247.00156.00 3.40 4.90 1 3/8 X 2 1/8 3000401C302M250BJ8 64.5039.7011.0015.70 2 X 3 5/8 1100401C112M200AH8 172.00111.00 4.20 6.10 1 3/8 X 2 5/8 3100401C312M250ED8 70.2036.0010.1014.90 1 3/4 X 4 5/8 1300401C132M200EA8 151.0096.20 4.807.00 1 3/4 X 2 1/8 3600401C362M250EE8 62.0031.9011.3016.70 1 3/4 X 5 1/8 1500401C152M200AB8 132.0086.60 5.207.50 1 3/8 X 3 1/8 3700401C372M250BC8 54.5033.6011.9017.20 2 X 4 1/8 1800401C182M200AJ8 124.0080.80 6.608.40 2 X 2 1/8 3900401C392M250EF8 55.6028.6012.7018.60 1 3/4 X 5 5/8 1800401C182M200BA8 107.0071.80 6.008.80 1 3/8 X 3 5/8 4200401C422M250BD8 47.3029.2012.8018.70 2 X 4 5/8 1900401C192M200EH8 105.0072.40 6.208.90 1 3/4 X 2 5/8 4800401C482M250BE8 41.9025.9013.6020.00 2 X 5 1/8 2200401C222M200AC8 90.2061.80 6.9010.10 1 3/8 X 4 1/8 5300401C532M250BF8 37.6023.3014.4021.20 2 X 5 5/8 元器件交易网。

Lattice ispMACH TM 4000V/B/C/Z 设计指南及常见问题解答目录1介绍 (4)1.1特征 (4)1.2产品系列和器件选择手册 (4)1.3性能分析 (5)1.3.1超快性能 (5)1.3.2最低功耗 (6)2体系结构概述 (7)2.1ISP MACH4000体系结构 (7)2.2结构特征 (9)2.2.1逻辑分配器和3种速度路径 (9)2.2.2带可编程延时的输入寄存器 (10)2.2.3灵活的时钟和时钟使能 (10)2.2.4初始化控制 (11)2.2.5ORP BYPASS多路复用器 (11)2.2.6I/O 单元 (12)2.2.7OE 控制 (12)3设计实现 (13)3.1全局约束 (13)3.1.1Fitter 选项 (13)3.1.2利用率选项 (14)3.2约束编辑器 (15)3.2.1设备设置表 (15)3.2.2封装察看/引脚编辑规划 (15)3.2.3引脚/节点位置分配 (16)3.2.4组分配 (16)3.2.5I/O类型设置 (16)3.2.6资源预留 (17)3.2.7缺省设置 (17)3.3资源约束 (17)3.3.1使用源约束注意事项 (17)3.3.2源约束语法 (18)3.4优化设计方法 (21)3.4.1ispLEVEL 约束选项控制 (21)3.4.2HDL 源文件约束控制 (22)4器件应用要点 (22)4.14K系列器件VCC和VCCO的作用和连接 (22)4.24K系列器件各电源上电时间及要求 (22)4.34K系列器件的全局复位 (22)4.4关于4K系列器件时钟的用法 (22)4.5全局输出使能信号 (23)4.6CPLD的I/O口作为双向口使用时应注意的问题 (23)4.7关于设计中使用宽多路复用器的问题 (24)4.8未使用引脚的处理 (25)4.9I/O5V兼容问题 (25)4.10I/O口的电平设置 (25)4.114K系列器件引脚上、下拉电阻,OD,慢摆率特性的设定 (25)4.12关于引脚的缺省值和更改 (27)4.134K系列器件功耗的计算 (27)4.144K系列器件节点温度的计算 (27)4.154K器件的热插拔 (28)4.16ISP JTAG编程/测试信号 (28)4.17CPU加载的频率 (28)4.184K系列器件可承受的加载次数 (28)4.19加载过程中I/O口的状态 (29)4.20综合工具的选择 (29)4.21关于约束文件 (29)4.22用嵌入的M ODEL S IM 仿真 (29)4.23M ODEL S IM应用点滴 (30)4.244K器件上电电压阀值 (31)4.25ISP LEVER中的版本控制功能 (31)4.26ISP LEVER中C ONSTRAINT E DITOR的G LOBAL C ONSTRAINTS设置 (33)4.27ISP LEVER中的时序分析 (33)5ISPLEVER优化参数快速指南 (34)5.1ISP LEVER常用约束优化参数的含义与推荐设置 (34)5.2ISP LEVER推荐的优化参数设置 (36)6ISPLEVER安装说明 (37)6.1ISP LEVER安装说明 (37)6.2ISP VM S YSTEM安装说明 (38)7相关资料 (38)8附录：LATTICE器件深圳中兴支持联系方法 ....................... 错误!未定义书签。

5月技术重点5月挂网维修手册：1、8K84机芯维修手册：采用MT5308芯片，集成度高，功能强大。

该机芯所配机型为有32K08RD、37K08RD、42K08RD、47K08RD。

2、8M95\96机芯维修手册：主芯片芯片MSD489SV-Z1-TM，主配E72RD系列电视。

升级U412（NAND）软件方法：将相应尺寸软件的USB.BIN文件放在U盘的根目录下，插入USB3、USB4接口，开机时按键控板上的“频道—”键，待6秒后无开机Log后则开始升级软件，时间大约2分钟左右。

升级U12（Mboot）软件方法:将Mboot.bin文件放在U盘的根目录下，插入USB3、USB4接口,按菜单键，选择“通道选择”项，按确定键后再连续按数字键2580，进入工厂菜单后选择“其他设置”，按确定键后选择“软件升级（USB）”，按确定键后选择“升级Nand”,按确定键后选择“YES”升级Mboot,升级时黑屏，升级完成后自动重起，通常Mboot需要升级两次。

3、168P-P24TWB-W1维修手册(待机芯片NXP TEA1733P+主芯片OB2263)4、168P-P37TLU-00维修手册（此电源采用Sanken公司的待机芯片STR-A6059M。

PFC控制芯片FA5591 与主芯片FA5641 ，主芯片为反激控制芯片机芯知识：1、E92\K08\E82系列机芯主板硬件差异如下，。

E92的主要配置是3颗DDR、256M-flash存储K08的主要配置是2颗DDR、256M-flash存储E82的主要配置是2颗DDR、128M-flash存储上不同系列机型软件不相同。

但相同型号的机器软件相同，主要不同尺寸屏的参数存放在EEP内，因此换存储器时可能会造成黑屏等问题。

上列机型的升级方法有：强制升级（upgrade_loader.pkg）、本地升级(upgrade.pkg)、在线升级，其中在线升级要注意：E92和K08要求是最后下载完毕后，拔掉U盘重启。

ODR-C08用户手册USB至RS232/422/485隔离转换器2006年六月印刷 Rev 1.2O-dear International Co., Ltd台湾（ROC）台北县三重市兴德路111-2号12楼电话：886-2-85122893 传真：886-2-85124968网址：版权版权声明：为了改善可靠性、设计和功能，本手册中的信息如有改变恕不另行通知且厂商亦不承担责任。

未经厂商允许不得以任何形式对本手册中的内容进行翻版、复制或传播。

本手册中提及的产品只为识别目的而被提及。

手册中出现的产品名可能是或不是各自公司的注册商标或版权。

1.简介 (3)1-1特点 (3)1-2规格 (3)2.硬件说明 (4)2-1 操作盘配置 (4)2-2 LED指示灯 (4)2-3串行连接 (4)2-4电源连接 (4)2-5 USB连接 (5)2-6 RS485配线 (5)2-7 RS422配线 (5)2-8 RS232配线 (5)2-9 USB电缆配线 (6)3.ODR-C08软件安装 (6)4. 删除或更新ODR-C08驱动程序 (8)5. 终端电阻 (9)5-1 RS422终端电阻连接 (9)5-2 RS485终端电阻连接 (9)5-3终端电阻规格 (9)6.测试ODR-C08的方法 (10)6-1 Res422回路回送测试 (10)6-2 RS232回路回送测试 (10)6-3回路回送测试软件 (10)7. 测试RS485的方法 (11)7-1 RS485针配线 (12)1. 简介ODR-C08允许用户通过USB接口将串口设备与系统连接。

数据格式自动检测和波特率自动切换功能使ODR-C08能够自动检测数据流和切换数据线的方向，同时无需进行外部切换设置可自动为RS232/RS422/485信号设置任意波特率。

在各数据线上装有3000VDC 的隔离和内部过电压保护，ODR-C08使主计算机和模块本身完全免受破坏性电压的损坏和未调电压输入的危险。

8-Channel Home Theater Amplifier PT8000CHMulti-Zone Audio Source Control,Rack Mount Amp, 8000 WattRead through this user manual before using the product to ensure its correct use. Keep this manual for future reference.The PT8000CH contains the excellent performance and reliability that PYLEUSA products have been recognized for. The PT8000CH features the exibility needed for demanding custom installation applications. It is ideal for use in home theater, stereo, multi-room, multi-zone and commercial applications.For best performance, please carefully read the instructions in this manual.TABLE OF CONTENTSFeaturesFront Panel DiagramRear Panel DiagramSystem Design & Operation Considerations System Design ExamplesDiagram 4 - Multi Room InstallationDiagram 5 - Multi-Zone Installation #1Diagram 6 - Multi-Zone Installation #2Diagram 7- Home Theater/Multi-Room Installation Installation ConsiderationsInstallationOperationTroubleshootingSpeci cations3 4 4 6 8 9 10 11 12 13 14 18 19 212FEATURESAudiophile DesignSophisticated design and superior internal components result in outstanding sound quality, performance and long term reliability.Advanced ProtectionEach channel is individually protected. If the circuitry determines that a channel must be shutdown for protection, a rare occurrence, only the channel a ected will be turned o . The other channels will continue to play. Once conditions return to normal, the a ected channel will be turned back on and operate as normal. Flexible Input SelectionEach of the 8 channels can be assigned a variety of source inputs. A dedicated input can be assigned to each channel. Each channel can also be con gured to play common signals from the Bus or Auxiliary inputs. This provides the exibility needed in sophisticated custom audio installations.BridgingThe power output of adjacent channels can be combined to provide extra power when needed in certain areas. This is easliy accomplished by ipping a single switch. Individual Channel Level AdjustmentsEach channel has its own level adjustment. This allows the loudness of each speaker to be perfectly matched to its area.Multiple Power Modes and Output TriggerThere are three ways to turn the ampli er ON: constant, trigger and audio sense. This allows the ampli er to operate seamlessly as part of a sophisticated custom installation. A separate output trigger allows the ampli er to activate other components via voltage trigger.3DIAGRAM 1 FRONT PANEL1. POWER SWITCHMaster power switch. Turns o power to ampli er and Power Mode Circuitry.2. POWER OUTPUT LEVEL INDICATORThis is level meter which shows outputs levels of ch 1-2 ch 3-4 ch 5-6 & ch 7-8 condition on the operation. Therefore, you can see output condition thru this master indicator.DIAGRAM 2 REAR PANEL41-2. Main bus inputs allow outputs from receivers, CD players, TVs, or any stereoaudio sources to be ampli ed across all channels for easy multi-roomapplications. Auxiliary inputs allows an addition audio source to be played on any channel that is switched to AUX .3-4. Bus outputs allows the bus inputs to be sent to other ampli ers or a daisy chain without the need for “Y” cable splitters. Auxiliary output allows you to daisychain the input to other audio sources.5. Bridging switch allows you to easily double the power output by coupling two channels together.6. Level controls for each channel.7. Input Selection switch allows you to select between the common bus andauxiliary inputs or the individual channel input.8. One switch allows you to select which stereo Input channel will play through the speaker outputs: left, right, or left and right combined. lf switched to Left + Right, both input channels are combined.9. Gold plated individual channel inputs allow you to connect di erent audiosources to each channel.10. Line signal output11. Voltage Selector 110-220V12. The Power Mode switch is used to toggle between three di erent triggermethods to power up the ampli er.13. 12V output to turn on other devices when ampli er is powered up.Connect to projector screens, powered drapes, or other devices with voltage triggers.14. 12-15V A/C or D/C input to trigger power up with voltage from anotherdevice, such as a receiver.15. Speaker channel output binding posts.16. Speaker channel bridged mode binding.17. 3-Prong removable power plug.18. Fused AC5SYSTEM DESIGN & OPERATION CONSIDERATIONSTo best understand system design and operation of the PT8000CH, it is useful to understand the following terms and features as they relate to the PT8000CH. Multi-RoomA system design that plays the same source at the same time in all rooms.If a change is made in one room, the same changes takes place in all other rooms. For example, if a listener changes from CD to Tuner in the bedroom, the same change will be heard in the kitchen.Note: With the use of volume controls or speaker switchers the volume of each room can be controlled separately of the other rooms.Multi-ZoneA system design that allows di erent sources to be played in each room. A change in one room can be made without changing the other rooms. For example the CD player can be heard in the bedroom while the kitchen is playing the tuner. BridgingThe combining of 2 channels to create one mono channel. It is useful when more volume is needed in a particular area.SourceComponent, audio or video, that provides an audio signal. Examples are CD, VCR, DVD, tape deck and tuner. The source provides the audio information that is ampli ed by the PT8000CH.ChannelA distinct unit of the ampli er that provides output to one speaker. On thePT8000CH the input to each channel can be con gured to select from the BUS INPUT, the AUX INPUT or that channel’s unique CHANNEL INPUT. Two adjacent channels can be bridged to provide higher power to one speaker.Level ControlsAllows any of the channels to be adjusted independently to raise or lower the output of each channel. This may be used to control the speaker output in order to balance di erent rooms or areas of the system.6BUS* AUX* LINE SwitchAllows each channel to play a variety of di erent inputs. Depending on the switch position the channel ampli es the signal connected to the BUS input, the AUX input, or its own LINE input.R R + L L SwitchWhen either a BUS or AUX input is selected, this switch is used to direct the channel to play the left signal from the input “L” or the right signal from the input “R”, or a combined right and left signal from the input “R+L”.Bus InputAllows the signal from a source to be distributed to any of the 12 channels on the ampli er.Auxiliary InputsAllows the signal from a secondary source to be distributed to any of the 12 channels of the ampli er.Power Mode SelectionThere are three ways to turn the ampli er on and o . Use the following list to decide which mode will work best for your application. See Diagram 3 below. 1. ConstantUse this selection when you wish to manually turn the ampli er on and o byusing the front mounted power button.2. TriggerUse this selection if you wish the ampli er turn on when it receives voltage(12-15V A/C or D/C) from an external source and turn o once that voltage has stopped. Some components have voltage outputs that are designed for this use. In addition there are devices that can be used as part of an automated system that will provide voltage to enable the mode. The voltage source must beconnected to the trigger-input jack on the back of the ampli er.3. Audio SenseUse this selection when you want the ampli er to turn on when the ampli er’s main input receives an audio signal. At the moment that either the left or right input jacks receive a signal the ampli er is turned on. Once the signal stops the ampli er waits 3 minutes and then turns o .78DIAGRAM 3: POWER MODE SELECTIONSYSTEM DESIGN EXAMPLESThere are many ways to con gure the PT8000CH ampli er. The following pages contain some typical installation examples. Use these examples to generate ideas for your system design.Multi-Room Installation Example (Diagram 4)This illustrates the simplest use of the PT8000CH, distributing audio throughout the home. In this example only one source can be selected at a time, all pairs of speakers have the same audio signal available. The Input Selection switch is set to “BUS” on all channels. Adjacent channels are assigned left and right.Multi-Zone Example #1 (Diagram 5)This illustrates the simplest way to provide an audio signal to one area that is independent of the main audio signal. Zone 2 uses a CD player connected to just that Zone. The rest of the system operates Zone 1 and is connected to the preampli er/receiver. The Input Selection switch on channels 1-10 is set to “BUS” with adjacent channels assigned left and right. The Input Selection Switch on channels 11 and 12 are set to “LINE”.Multi-Zone Example #2 (Diagram 6)This illustrates the ability to listen to di erent audio signals in each zone, indepen-dent of every other zone. The system relies on a multi-zone preampli er or up to 6 independent preampli ers.The Input Selection switch on each channel is set to “LINE”12-15V AC/DC TRIGGER INPUT 12-15V AC/DCTRIGGER INPUT 12V CONTROL OUTPUTAUDIO SENSE CONSTANT2.1mm x 5.5mm Power Input Jack Mode Switch3.5mm Power Output JackHome Theater / Multi-Room Example (Diagram 7)This con guration allows the user to access the sources connected to a home theater receiver for use in a multi-room installation. It relies on the home theater receiver having a multi-room or similar output.The Input Selection switch on each channel is set to “BUS” with adjacent channels assigned left and right.DIAGRAM 4 MULTI ROOM INSTALLATION9 10DIAGRAM 5 MULTI ZONE INSTALLATION #1DIAGRAM 6 MULTI ZONE INSTALLATION #21112DIAGRAM 7 HOME THEATER/MULTI ROOM INSTALLATIONINSTALLATION CONSIDERATIONSDO:• Place the amplifier with the feet resting on a solid flat level surface.• Place the amplifier in a well-vented area to provide proper cooling. In areas thatlack proper ventilation, such as tight cabinets or racks, it may be necessary toinstall small fans to create air movement.DON’T:• Don’t block the ventilation holes on the top or bottom of the amplifier.Never place it on carpeting or similar material.• Don’t place the ampli er in any other position other than horizontal with the feet down. Never place on its side or resting on the back where the terminals arelocated.• Don’t the amplifier near heat sources, or in an area that it would be exposed tomoisture.YOU SHOULD KNOW• The power supply is very large and therefore may cause a hum to be heard insome components if they are placed very close to the ampli er.13INSTALLATIONCAUTION: All connections and switching must be done with the ampli er’s master power switch positioned to “o ”.Select the Power Mode SelectionRefer to the Power Mode Selection area under installation considerations to determine which setting to use to turn the ampli er on. Once you have determined which mode you will be using set the switches as outlined in the following chart:14Selecting Inputs (See Diagrams 8 & 9)Each channel is capable of delivering the source from many inputs. The three main inputs are BUS, AUX and LINE IN. The selection for these inputs is donevia the Input Selection switch, marked “BUS-AUX-LINE”. To select a source for each channel, follow the steps below:1. Select the desired source input. Set the Input Selection switch to BUS (will playsource connected to the BUS INPUT), AUX (will play source connected to theAUX INPUT) or LINE (will play source connected to the LINE IN).Diagram 8BUS.AUX.LINE2. The BUS and AUX inputs each have a left and right input. The left, right orcombined left and right signal from these may be selected via the switchmarked “R R+L L”. Select the side you want the channel to deliver. Selecting “R” ± will play the right channel of the selected input. Selecting “L” will play the leftchannel of the selected input. Selecting “R+L” will play the combined signals ofright and left.Diagram 9R R+L RSelecting Bridge Mode (See Diagram 10)Under normal operation, this should be left in the 8 ohm position. It is sometimes desirable to combine two channels into one through bridging. The output of the combined channels can then be used to power one speaker.To bridge two adjacent channels rst make sure that the Impedance Switch isin the 8ohm position. Next move the switch marked “BRIDGE” to the “ON” position.1516The speaker must be connected to the terminals immediately under the “BRIDGED” text as indicated in Diagram 10. All input selection and settings for the bridged channels will be done on the channel to the left.Do not connect more than one speaker to the outputs of the bridged channel.Control OutputThe 12V output jack on the back of the ampli er can be used to turn on a variety of components equipped to be activated when they receive a 12V DC output. Voltage is only delivered to the jack when the ampli er is “on” or active. When the ampli er turns o , the voltage ceases.Before connecting another device to the 12 output please make sure that the device can accept 12V DC at 150ma. To connect the output to another device you must access the output jack with a two-conductor plug that ts into the 3.5mm jack. Be aware that the tip of the plug will be (+). If you are unsure about using this feature please contact an authorized PYLEUSA dealer for assistance.Connecting the Speaker WiresCAUTION:Only make connections when the ampli er is turned o .Wires to speakerUsing Standard Connections (See Diagram 11)For best performance use high quality speaker cables. The banana plug outputs on the back of the ampli er allow for a variety of ways to connect your speakers to the ampli er.Diagram 11: Binding Post DetailOnly make connections when the ampli er is turned o . application.Audio OutputsSources connected to the “BUS” or “AUX” inputs can be forwarded to other components or ampli ers by connecting to the corresponding output sectionsto the right of each input section. By using standard audio patch cables, you can connect these outputs to the inputs of another ampli er. Up to 5 ampli ers canbe daisy-chained together.AC PowerPlug the socket of the AC cord supplied with the ampli er into the receptacle on the rear of the ampli er. Plug the 2 prong plug directly into a 120V 60Hz wall outlet. CAUTION: Do not plug the ampli er into the preampli er or receivers switched outlet. If you wish to have the ampli er turn on once the preampli er or receiveris activated, use one of the turn on modes, voltage or audio.Turn to tightenInsert Banana Plug17OPERATIONSee Diagram 1for the location of the following:Power SwitchThe switch marked “Power” on the front panel of the ampli er will turn o all ampli er circuitry no matter which turn on mode is selected.Refer to the “Power Mode Selection” section for further information.Active LEDWhen lit, the Active LED indicates that the ampli er is operating. Refer to the “Power Mode Selection” section of this manual for further information. Protection LEDsWhen lit the “Protection” LEDs located on the front of the ampli er indicate that either a fault in the wiring, the speaker, or the ampli er has caused the channels associated with the LED to shut down.Level Adjustment KnobsThe level adjustment knobs on the back panel of the ampli er can be used to adjust the level of each channel. There are many reasons for needing to adjust the level. You many wish to closely match other levels in the system, or you may wish to limit the volume level in an area, such as a child’s room.18TROUBLESHOOTINGThe ampli er is designed to function trouble-free. Most problems occur becauseof operating errors. If you have a problem please check the troubleshooting listrst. If the problem persists, contact your authorized dealer.19This product can expose you to a chemical or group of chemicals, which may include “Nickel Carbonate” which is known in the state of California to cause cancer, birth defects,or other reproductive harm. For more info, go to https:/// 20FEATURES:• Multi-Zone Audio Source Ampli er System• High-Powered & Distortion-Free Audio Distribution• 8-Channel Sound Processing Amp Design• Integrated 4-Channel Bridgeable (Bridge) Switches• Front Panel Color LED Graphic Audio Level Display• Independent Channel Rotary Level Control Knobs• Channel Con guration: Left/Right/Mono - Bus/AUX Input• Gold-Plated Audio/Speaker Connectors• 5-Way Speaker Binding Posts (Banana Plug) Outputs• Pass-Through Output for External Ampli er Linking (Daisy-Chaining)• Individual Channel Safety with Protection & Overload Circuitry• Master Power Button, ON/OFF• Universal Rack Mount Compatibility• Perfect for Home Theaters & Multi-Room Audio Control• Used in Home, O ce & Business ApplicationsWHAT’S IN THE BOX:• 8-Channel Ampli er• Power CableTECHNICAL SPECS:• MAX Power Output: 8-Ch. x 1000 Watt• RMS Power Output: 100W x 8-Ch @ 8Ohm• T.H.D.: <1%• Rack Mountable: 4U Rack Space• Power: 115/230V Switchable (DC 12-15V)• Dimension (W x D x H): 19.0'' x 19.3'' x 7.1''21Questions? Issues?We are here to help! Phone: (1) 718-535-1800Email: *******************。

Product Construction:Conductor:• Fully annealed tinned copper perASTM B-33• Fully annealed solid bare copper perASTM B-3, (C2754, C2755)Insulation:• Premium-grade, coIor-coded S-R PVCper UL 1061Jacket:• PVC, gray• Temperature Range: –20°C to +80°CApplications:• Public address systems• Intercoms• Remote control circuits• Suggested voltage rating: 300 voltsCompliances:• NEC Article 800 Type CM (UL: 75°C)• UL Style 2464 (UL: 80°C 300V)• CSA CMG (CSA: 60°C)• Designed to meet UL 70,000 BTU VerticalTray Flame Test• Passes CSA CMG Flame TestPackaging:• Please contact Customer Service forpackaging and color options*Capacitance between conductorsProduct Construction: Conductor:• 24 AWG fully annealed stranded tinnedcopper per ASTM B-33 Insulation:• Premium-grade, coIor-coded S-R PVCper UL 1061• Color Code: See charts below Jacket:• PVC, gray• Temperature Range: –20°C to +80°C Applications:• Public address systems• Intercoms• Internal telephones• Remote control circuits• Suitable for EIA RS-232 applications • Suggested voltage rating: 300 volts Features:• Easy to terminate• Excellent electrical properties• Tinned conductors provide excellentcorrosion resistance• Assists soldering applications Compliances:• NEC Article 800 Type CM (UL: 75°C)• UL Style 2464 (UL: 80°C, 300V)• UL Style 2576 (UL: 80˚C, 150V)• CSA CMG (CSA: 60°C)• Designed to meet UL 70,000 BTU Vertical Tray Flame Test• Passes CSA CMG Flame Test Packaging:• Please contact Customer Service forpackaging and color optionsProduct Construction:Conductor:• 22 AWG fully annealed, stranded tinnedcopper per ASTM B-33Insulation:• Premium-grade, coIor-coded S-R PVCper UL 1061• Color Code: See charts belowJacket:• PVC, gray• Temperature Range: –20°C to +80˚CApplications:• Public address systems• Intercoms• Internal telephones• Remote control circuits• Suitable for EIA RS-232 applications• Suggested voltage rating: 300 voltsFeatures:• Easy to terminate• Excellent electrical properties• Tinned conductors provide excellentcorrosion resistance• Assists soldering applicationsCompliances:• NEC Article 800 Type CM (UL: 75°C)• UL Style 2464 (UL: 80°C, 300V)• UL Style 2576 (UL: 80˚C, 150V)• CSA CMG (CSA 80°C)• Designed to meet UL 70,000 BTU VerticalTray Flame Test• Passes CSA CMG Flame TestPackaging:• Please contact Customer Service forpackaging and color options†CM-CSA CMG OnlyProduct Construction:Conductor:• 20 or 18 AWG fully annealed stranded,tinned copper per ASTM B-33Insulation:• Premium-grade, coIor-coded PVC perUL 1007• Color Code: See charts belowJacket:• PVC, gray• Temperature Range: –20˚C to +80°CApplications:• Public address systems• Intercoms• Internal telephones• Remote control circuits• Suitable for EIA RS-232 applications• Suggested voltage rating: 300 voltsCompliances:• NEC Article 800 Type CM (UL: 75°C)• UL Style 2464 (UL: 80°C, 300V)• UL Style 2576 (UL: 80˚C, 150V)• CSA CMG (CSA: 60°C)• Designed to meet UL 70,000 BTU VerticalTray Flame Test• Passes CSA CMG Flame TestPackaging:• Please contact Customer Service forpackaging and color options†CM (UL) c(UL), CSA CMG OnlyProduct Construction:Conductor:• 16 thru 12 AWG fully annealed strandedtinned copper per ASTM B-33Insulation:• Premium-grade, coIor-coded PVC• Color Code: See chart belowJacket:• PVC, gray• Temperature Range: –20°C to +80°CApplications:• Public address systems• Intercoms• Internal telephones• Remote control circuits• Suitable for EIA RS-232 applications• Suggested voltage rating: 300 voltsCompliances:• NEC Article 725 Type CL3 (UL: 75°C)• NEC Article 800 Type CM (UL: 75°C)• UL Style 2464 (UL: 80°C, 300V)• UL Style 2587 (UL: 90°C, 600V)• CSA CMG (CSA: 60°C)• Designed to meet UL 70,000 BTU VerticalTray Flame Test• Passes CSA CMG Flame TestPackaging:• Please contact Customer Service forpackaging and color options†CL3, UL2587, CSA CMH OnlyProduct Construction: Conductor:• 22 thru 18 fully annealed stranded tinnedcopper per ASTM B-33Insulation:• Premium-grade, coIor-coded PVC (18 AWG), S-R PVC (22 AWG)• Color Code: See chart belowJacket:• PVC, gray• Temperature Range: –20°C to +80°C Applications:• TV antenna rotor control• Satellite actuator control• Public address systems• Suggested voltage rating: 300 volts Features:• Tinned copper conductors provide excellent corrosion resistance• Assists with soldering applications Compliances:• NEC Article 800 Type CM (UL: 75°C)• UL Style 2464 (UL: 80°C, 300V)• CSA CMG (CSA: 60°C)• Designed to meet UL 70,000 BTU VerticalTray Flame Test• Passes CSA CMG Flame Test Packaging:• Please contact Customer Service forpackaging and color options。

ispMACH4000ZE Family1.8V In-System ProgrammableUltra Low Power PLDsAugust 2008Data Sheet DS1022®© 2008 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at /legal. All other brand Features■ High Performance•f MAX = 260MHz maximum operating frequency •t PD = 4.4ns propagation delay•Up to four global clock pins with programmable clock polarity control •Up to 80 PTs per output■ Ease of Design•Flexible CPLD macrocells with individual clock, reset, preset and clock enable controls •Up to four global OE controls•Individual local OE control per I/O pin •Excellent First-Time-Fit TM and refit•Wide input gating (36 input logic blocks) for fast counters, state machines and address decoders ■ Ultra Low Power•Standby current as low as 10µA typical •1.8V core; low dynamic power •Operational down to 1.6V V CC•Superior solution for power sensitive consumer applications•Per pin pull-up, pull-down or bus keeper control *• Power Guard with multiple enable signals*■ Broad Device Offering•32 to 256 macrocells•Multiple temperature range support – Commercial: 0 to 90°C junction (T j )– Industrial: -40 to 105°C junction (T j )•Space-saving packages■ Easy System Integration•Operation with 3.3V , 2.5V , 1.8V or 1.5V LVCMOS I/O•5V tolerant I/O for LVCMOS 3.3, LVTTL, and PCI interfaces•Hot-socketing support •Open-drain output option•Programmable output slew rate •3.3V PCI compatible•I/O pins with fast setup path • Input hysteresis*•1.8V core power supply•IEEE 1149.1 boundary scan testable •IEEE 1532 ISC compliant•1.8V In-System Programmable (ISP™) using Boundary Scan T est Access Port (T AP)•Pb-free package options (only)• On-chip user oscillator and timer**New enhanced features over original ispMACH 4000ZTable 1. ispMACH 4000ZE Family Selection GuideispMACH 4032ZEispMACH 4064ZEispMACH 4128ZEispMACH 4256ZEMacrocells 3264128256t PD (ns) 4.4 4.7 5.8 5.8t S (ns) 2.2 2.5 2.9 2.9t CO (ns) 3.0 3.2 3.8 3.8f MAX (MHz)260241200200Supply Voltages (V)1.8V 1.8V 1.8V1.8VPackages1 (I/O + Dedicated Inputs) 48-Pin TQFP (7 x 7mm)32+432+464-Ball csBGA (5 x 5mm)32+448+4100-Pin TQFP (14 x 14mm)64+1064+1064+10144-Pin TQFP (20 x 20mm)96+496+14144-Ball csBGA (7 x 7mm)64+1096+4108+41.Pb-free only.元器件交易网元器件交易网Lattice Semiconductor ispMACH 4000ZE Family Data SheetIntroductionThe high performance ispMACH 4000ZE family from Lattice offers an ultra low power CPLD solution. The new fam-ily is based on Lattice’s industry-leading ispMACH 4000 architecture. Retaining the best of the previous generation, the ispMACH 4000ZE architecture focuses on significant innovations to combine high performance with low power in a flexible CPLD family. For example, the family’s new Power Guard feature minimizes dynamic power consump-tion by preventing internal logic toggling due to unnecessary I/O pin activity.The ispMACH 4000ZE combines high speed and low power with the flexibility needed for ease of design. With its robust Global Routing Pool and Output Routing Pool, this family delivers excellent First-Time-Fit, timing predictabil-ity, routing, pin-out retention and density migration.The ispMACH 4000ZE family offers densities ranging from 32 to 256 macrocells. There are multiple density-I/O combinations in Thin Quad Flat Pack (TQFP) and Chip Scale BGA (csBGA) packages ranging from 32 to 176 pins/ balls. T able 1 shows the macrocell, package and I/O options, along with other key parameters.A user programmable internal oscillator and a timer are included in the device for tasks like LED control, keyboardscanner and similar housekeeping type state machines. This feature can be optionally disabled to save power.The ispMACH 4000ZE family has enhanced system integration capabilities. It supports a 1.8V supply voltage and3.3V, 2.5V, 1.8V and 1.5V interface voltages. Additionally, inputs can be safely driven up to 5.5V when an I/O bankis configured for 3.3V operation, making this family 5V tolerant. The ispMACH 4000ZE also offers enhanced I/O features such as slew rate control, PCI compatibility, bus-keeper latches, pull-up resistors, pull-down resistors, open drain outputs and hot socketing. Pull-up, pull-down and bus-keeper features are controllable on a “per-pin”basis. The ispMACH 4000ZE family members are 1.8V in-system programmable through the IEEE Standard 1532 interface. IEEE Standard 1149.1 boundary scan testing capability also allows product testing on automated test equipment. The 1532 interface signals TCK, TMS, TDI and TDO are referenced to V CC (logic core).OverviewThe ispMACH 4000ZE devices consist of multiple 36-input, 16-macrocell Generic Logic Blocks (GLBs) intercon-nected by a Global Routing Pool (GRP). Output Routing Pools (ORPs) connect the GLBs to the I/O Blocks (IOBs), which contain multiple I/O cells. This architecture is shown in Figure 1.Figure 1. Functional Block Diagram元器件交易网Lattice Semiconductor ispMACH 4000ZE Family Data Sheet The I/Os in the ispMACH 4000ZE are split into two banks. Each bank has a separate I/O power supply. Inputs can support a variety of standards independent of the chip or bank power supply. Outputs support the standards com-patible with the power supply provided to the bank. Support for a variety of standards helps designers implement designs in mixed voltage environments. In addition, 5V tolerant inputs are specified within an I/O bank that is con-nected to a V CCO of 3.0V to 3.6V for LVCMOS 3.3, LVTTL and PCI interfaces.ArchitectureThere are a total of two GLBs in the ispMACH 4032ZE, increasing to 16 GLBs in the ispMACH 4256ZE. Each GLB has 36 inputs. All GLB inputs come from the GRP and all outputs from the GLB are brought back into the GRP to be connected to the inputs of any other GLB on the device. Even if feedback signals return to the same GLB, they still must go through the GRP. This mechanism ensures that GLBs communicate with each other with consistent and predictable delays. The outputs from the GLB are also sent to the ORP. The ORP then sends them to the asso-ciated I/O cells in the I/O block.Generic Logic BlockThe ispMACH 4000ZE GLB consists of a programmable AND array, logic allocator, 16 macrocells and a GLB clock generator. Macrocells are decoupled from the product terms through the logic allocator and the I/O pins are decou-pled from macrocells through the ORP. Figure 2 illustrates the GLB.Figure 2. Generic Logic BlockAND ArrayThe programmable AND Array consists of 36 inputs and 83 output product terms. The 36 inputs from the GRP are used to form 72 lines in the AND Array (true and complement of the inputs). Each line in the array can be con-nected to any of the 83 output product terms via a wired-AND. Each of the 80 logic product terms feed the logic allocator with the remaining three control product terms feeding the Shared PT Clock, Shared PT Initialization and Shared PT OE. The Shared PT Clock and Shared PT Initialization signals can optionally be inverted before being fed to the macrocells.Every set of five product terms from the 80 logic product terms forms a product term cluster starting with PT0.There is one product term cluster for every macrocell in the GLB. Figure 3 is a graphical representation of the AND Array.元器件交易网Lattice Semiconductor ispMACH 4000ZE Family Data Sheet Figure 3. AND ArrayEnhanced Logic AllocatorWithin the logic allocator, product terms are allocated to macrocells in product term clusters. Each product term cluster is associated with a macrocell. The cluster size for the ispMACH 4000ZE family is 4+1 (total 5) product terms. The software automatically considers the availability and distribution of product term clusters as it fits the functions within a GLB. The logic allocator is designed to provide two speed paths: 20-PT Speed Locking path and an up to 80-PT path. The availability of these two paths lets designers trade timing variability for increased perfor-mance.The enhanced Logic Allocator of the ispMACH 4000ZE family consists of the following blocks:•Product T erm Allocator•Cluster Allocator•Wide Steering LogicFigure 4 shows a macrocell slice of the Logic Allocator. There are 16 such slices in the GLB.Figure 4. Macrocell Slice元器件交易网Lattice Semiconductor ispMACH 4000ZE Family Data SheetProduct Term AllocatorThe product term allocator assigns product terms from a cluster to either logic or control applications as required by the design being implemented. Product terms that are used as logic are steered into a 5-input OR gate associ-ated with the cluster. Product terms that used for control are steered either to the macrocell or I/O cell associated with the cluster. T able 2 shows the available functions for each of the five product terms in the cluster.Table 2. Individual PT SteeringProduct Term Logic ControlPT n Logic PT Single PT for XOR/ORPT n+1Logic PT Individual Clock (PT Clock)PT n+2Logic PT Individual Initialization or Individual Clock Enable (PT Initialization/CE)PT n+3Logic PT Individual Initialization (PT Initialization)PT n+4Logic PT Individual OE (PTOE)Cluster AllocatorThe cluster allocator allows clusters to be steered to neighboring macrocells, thus allowing the creation of functions with more product terms. T able 3 shows which clusters can be steered to which macrocells. Used in this manner, the cluster allocator can be used to form functions of up to 20 product terms. Additionally, the cluster allocatoraccepts inputs from the wide steering logic. Using these inputs, functions up to 80 product terms can be created.Table 3. Available Clusters for Each MacrocellMacrocell Available ClustersM0—C0C1C2M1C0C1C2C3M2C1C2C3C4M3C2C3C4C5M4C3C4C5C6M5C4C5C6C7M6C5C6C7C8M7C6C7C8C9M8C7C8C9C10M9C8C9C10C11M10C9C10C11C12M11C10C11C12C13M12C11C12C13C14M13C12C13C14C15M14C13C14C15—M15C14C15——Wide Steering LogicThe wide steering logic allows the output of the cluster allocator n to be connected to the input of the cluster alloca-tor n+4. Thus, cluster chains can be formed with up to 80 product terms, supporting wide product term functions and allowing performance to be increased through a single GLB implementation. T able 4 shows the product term chains.Lattice SemiconductorispMACH 4000ZE Family Data SheetTable 4. Product Term Expansion CapabilityEvery time the super cluster allocator is used, there is an incremental delay of t EXP . When the super cluster alloca-tor is used, all destinations other than the one being steered to, are given the value of ground (i.e., if the super clus-ter is steered to M (n+4), then M (n) is ground).MacrocellThe 16 macrocells in the GLB are driven by the 16 outputs from the logic allocator. Each macrocell contains a pro-grammable XOR gate, a programmable register/latch, along with routing for the logic and control functions.Figure 5 shows a graphical representation of the macrocell. The macrocells feed the ORP and GRP . A direct input from the I/O cell allows designers to use the macrocell to construct high-speed input registers. A programmable delay in this path allows designers to choose between the fastest possible set-up time and zero hold time. Figure 5. MacrocellEnhanced Clock MultiplexerThe clock input to the flip-flop can select any of the four block clocks along with the shared PT clock, and true and complement forms of the optional individual term clock. An 8:1 multiplexer structure is used to select the clock. The eight sources for the clock multiplexer are as follows:•Block CLK0•Block CLK1Expansion Chains Macrocells Associated with Expansion Chain(with Wrap Around)Max PT/MacrocellChain-0M0 → M4 → M8 → M12 → M075Chain-1M1 → M5 → M9 → M13 → M180Chain-2M2 → M6 → M10 → M14 → M275Chain-3M3 → M7 → M11 → M15 →M370元器件交易网元器件交易网Lattice Semiconductor ispMACH 4000ZE Family Data Sheet •Block CLK2•Block CLK3•PT Clock•PT Clock Inverted•Shared PT Clock•GroundClock Enable MultiplexerEach macrocell has a 4:1 clock enable multiplexer. This allows the clock enable signal to be selected from the fol-lowing four sources:•PT Initialization/CE•PT Initialization/CE Inverted•Shared PT Clock•Logic HighInitialization ControlThe ispMACH 4000ZE family architecture accommodates both block-level and macrocell-level set and reset capa-bility. There is one block-level initialization term that is distributed to all macrocell registers in a GLB. At the macro-cell level, two product terms can be “stolen” from the cluster associated with a macrocell to be used for set/reset functionality. A reset/preset swapping feature in each macrocell allows for reset and preset to be exchanged, pro-viding flexibility.Note that the reset/preset swapping selection feature affects power-up reset as well. All flip-flops power up to a known state for predictable system initialization. If a macrocell is configured to SET on a signal from the block-level initialization, then that macrocell will be SET during device power-up. If a macrocell is configured to RESET on a signal from the block-level initialization or is not configured for set/reset, then that macrocell will RESET on power-up. T o guarantee initialization values, the V CC rise must be monotonic, and the clock must be inactive until the reset delay time has elapsed.GLB Clock GeneratorEach ispMACH 4000ZE device has up to four clock pins that are also routed to the GRP to be used as inputs.These pins drive a clock generator in each GLB, as shown in Figure 6. The clock generator provides four clock sig-nals that can be used anywhere in the GLB. These four GLB clock signals can consist of a number of combinations of the true and complement edges of the global clock signals.Figure 6. GLB Clock GeneratorLattice Semiconductor ispMACH 4000ZE Family Data SheetOutput Routing Pool (ORP)The Output Routing Pool allows macrocell outputs to be connected to any of several I/O cells within an I/O block.This provides greater flexibility in determining the pinout and allows design changes to occur without affecting the pinout. The output routing pool also provides a parallel capability for routing macrocell-level OE product terms. This allows the OE product term to follow the macrocell output as it is switched between I/O cells. The enhanced ORP of the ispMACH 4000ZE family consists of the following elements:•Output Routing Multiplexers •OE Routing Multiplexers Figure 7 shows the structure of the ORP from the I/O cell perspective. This is referred to as an ORP slice. Each ORP has as many ORP slices as there are I/O cells in the corresponding I/O block. Figure 7. ORP SliceOutput Routing MultiplexersThe details of connections between the macrocells and the I/O cells vary across devices and within a device dependent on the maximum number of I/Os available. T ables 5-7 provide the connection details. Table 5. GLB/MC/ORP Combinations for ispMACH 4256ZEGLB/MC ORP Mux Input Macrocells[GLB] [MC 0]M0, M1, M2, M3, M4, M5, M6, M7[GLB] [MC 1]M2, M3, M4, M5, M6, M7, M8, M9[GLB] [MC 2]M4, M5, M6, M7, M8, M9, M10, M11[GLB] [MC 3]M6, M7, M8, M9, M10, M11, M12, M13[GLB] [MC 4]M8, M9, M10, M11, M12, M13, M14, M15[GLB] [MC 5]M10, M11, M12, M13, M14, M15, M0, M1[GLB] [MC 6]M12, M13, M14, M15, M0, M1, M2, M3[GLB] [MC 7]M14, M15, M0, M1, M2, M3, M4, M5元器件交易网元器件交易网Lattice Semiconductor ispMACH 4000ZE Family Data Sheet Table 6. GLB/MC/ORP Combinations for ispMACH 4128ZEGLB/MC ORP Mux Input Macrocells[GLB] [MC 0]M0, M1, M2, M3, M4, M5, M6, M7[GLB] [MC 1]M1, M2, M3, M4, M5, M6, M7, M8[GLB] [MC 2]M2, M3, M4, M5, M6, M7, M8, M9[GLB] [MC 3]M4, M5, M6, M7, M8, M9, M10, M11[GLB] [MC 4]M5, M6, M7, M8, M9, M10, M11, M12[GLB] [MC 5]M6, M7, M8, M9, M10, M11, M12, M13[GLB] [MC 6]M8, M9, M10, M11, M12, M13, M14, M15[GLB] [MC 7]M9, M10, M11, M12, M13, M14, M15, M0[GLB] [MC 8]M10, M11, M12, M13, M14, M15, M0, M1[GLB] [MC 9]M12, M13, M14, M15, M0, M1, M2, M3[GLB] [MC 10]M13, M14, M15, M0, M1, M2, M3, M4[GLB] [MC 11]M14, M15, M0, M1, M2, M3, M4, M5Table 7. GLB/MC/ORP Combinations for ispMACH 4032ZE and 4064ZEGLB/MC ORP Mux Input Macrocells[GLB] [MC 0]M0, M1, M2, M3, M4, M5, M6, M7[GLB] [MC 1]M1, M2, M3, M4, M5, M6, M7, M8[GLB] [MC 2]M2, M3, M4, M5, M6, M7, M8, M9[GLB] [MC 3]M3, M4, M5, M6, M7, M8, M9, M10[GLB] [MC 4]M4, M5, M6, M7, M8, M9, M10, M11[GLB] [MC 5]M5, M6, M7, M8, M9, M10, M11, M12[GLB] [MC 6]M6, M7, M8, M9, M10, M11, M12, M13[GLB] [MC 7]M7, M8, M9, M10, M11, M12, M13, M14[GLB] [MC 8]M8, M9, M10, M11, M12, M13, M14, M15[GLB] [MC 9]M9, M10, M11, M12, M13, M14, M15, M0[GLB] [MC 10]M10, M11, M12, M13, M14, M15, M0, M1[GLB] [MC 11]M11, M12, M13, M14, M15, M0, M1, M2[GLB] [MC 12]M12, M13, M14, M15, M0, M1, M2, M3[GLB] [MC 13]M13, M14, M15, M0, M1, M2, M3, M4[GLB] [MC 14]M14, M15, M0, M1, M2, M3, M4, M5[GLB] [MC 15]M15, M0, M1, M2, M3, M4, M5, M6Output Enable Routing MultiplexersThe OE Routing Pool provides the corresponding local output enable (OE) product term to the I/O cell.I/O CellThe I/O cell contains the following programmable elements: output buffer, input buffer, OE multiplexer, Power Guard and bus maintenance circuitry. Figure 8 details the I/O cell.元器件交易网Lattice Semiconductor ispMACH 4000ZE Family Data Sheet Figure 8. I/O CellEach output supports a variety of output standards dependent on the V CCO supplied to its I/O bank. Outputs can also be configured for open drain operation. Each input can be programmed to support a variety of standards, inde-pendent of the V CCO supplied to its I/O bank. The I/O standards supported are:•LVTTL•LVCMOS 1.8•LVCMOS 3.3•LVCMOS 1.5•LVCMOS 2.5• 3.3V PCI CompatibleAll of the I/Os and dedicated inputs have the capability to provide a bus-keeper latch, pull-up resistor or pull-down resistor selectable on a “per-pin” basis. A fourth option is to provide none of these. The default in both hardware and software is such that when the device is erased or if the user does not specify, the input structure is configured to be a Pull-down Resistor.Each ispMACH 4000ZE device I/O has an individually programmable output slew rate control bit. Each output can be individually configured for fast slew or slow slew. The typical edge rate difference between fast and slow slew setting is 20%. For high-speed designs with long, unterminated traces, the slow-slew rate will introduce fewer reflections, less noise and keep ground bounce to a minimum. For designs with short traces or well terminated lines, the fast slew rate can be used to achieve the highest speed.The ispMACH 4000ZE family has an always on, 200mV typical hysteresis for each input operational at 3.3V and2.5V. This provides improved noise immunity for slow transitioning signals.Power GuardPower Guard allows easier achievement of standby current in the system. As shown in Figure 9, this feature con-sists of an enabling multiplexer between an I/O pin and input buffer, and its associated circuitry inside the device.If the enable signal (E) is held low, all inputs (D) can be optionally isolated (guarded), such that, if any of these were toggled, it would not cause any toggle on internal pins (Q), thus, a toggling I/O pin will not cause any internal dynamic power consumption.Figure 9. Power GuardAll the I/O pins in a block share a common Power Guard Enable signal. For a block of I/Os, this signal is called a Block Input E nable (BIE) signal. BIE can be internally generated using MC logic, or could come from external sources using one of the user I/O or input pins.Any I/O pin in the block can be programmed to ignore the BIE signal. Thus, the feature can be enabled or disabled on a pin-by-pin basis.Figure 10 shows Power Guard and BIE across multiple I/Os in a block that has eight I/Os.Figure 10. Power Guard and BIE in a Block with 8 I/OsThe number of BIE inputs, thus the number of Power Guard “Blocks” that can exist in a device, depends on the device size. T able 8 shows the number of BIE signals available in the ispMACH 4000ZE family. The number of I/Os available in each block is shown in the Ordering Information section of this data sheet.Table 8. Number of BIE Signals Available in ispMACH 4000ZE DevicesPower Guard for Dedicated InputsPower Guard can optionally be applied to the dedicated inputs. The dedicated inputs and clocks are controlled by the BIE of the logic blocks shown in T ables 9 and 10.Table 10. Dedicated Inputs to BIE AssociationFor more information on the Power Guard function refer to TN1174, Advanced Features of the ispMACH 4000ZE .Global OE (GOE) and Block Input Enable (BIE) GenerationMost ispMACH 4000ZE family devices have a 4-bit wide Global OE (GOE) Bus (Figure 11), except the ispMACH 4032 device that has a 2-bit wide Global OE Bus (Figure 12). This bus is derived from a 4-bit internal global OE (GOE) PT bus and two dual purpose I/O or GOE pins. Each signal that drives the bus can optionally be inverted.Each GLB has a block-level OE PT that connects to all bits of the Global OE PT bus with four fuses. Hence, for a 256-macrocell device (with 16 blocks), each line of the bus is driven from 16 OE product terms. Figures 9 and 10show a graphical representation of the global OE generation.The block-level OE PT of each GLB is also tied to Block Input Enable (BIE) of that block. Hence, for a 256-macro-cell device (with 16 blocks), each block's BIE signal is driven by block-level OE PT from each block.DeviceNumber of Logic Blocks, Power Guard Blocks and BIE Signals ispMACH 4032ZE T wo (Blocks: A and B)ispMACH 4064ZE Four (Blocks: A, B, C and D)ispMACH 4128ZE Eight (Blocks: A, B, C, …, H)ispMACH 4256ZESixteen (Blocks: A, B, C, …, P)Table 9. Dedicated Clock Inputs to BIE AssociationCLK/I 32 MC Block64MC Block128MC Block256MC BlockCLK0 / I A A A A CLK1 / I A B D H CLK2 / I B C E I CLK3 / IBDHPDedicated Input4064ZE Block4128ZE Block4256ZE Block0A B D 1B C E 2B D G 3C F G 4D G J 5D H L 6——M 7——O 8——O 9——BFigure 11. Global OE Generation for All Devices Except ispMACH 4032ZEFigure 12. Global OE Generation for ispMACH 4032ZEOn-Chip Oscillator and TimerAn internal oscillator is provided for use in miscellaneous housekeeping functions such as watchdog heartbeats, digital de-glitch circuits and control state machines. The oscillator is disabled by default to save power. Figure 13 shows the block diagram of the oscillator and timer block.Figure 13. On-Chip Oscillator and TimerTable 11. On-Chip Oscillator and Timer Signal NamesOSCTIMER has two outputs, OSCOUT and TIMEROUT . The outputs feed into the Global Routing Pool (GRP).From GRP , these signals can drive any macrocell input, as well as any output pin (with macrocell bypass). The out-put OSCOUT is the direct oscillator output with a typical frequency of 5MHz, whereas, the output TIMEROUT is the oscillator output divided by an attribute TIMER_DIV .The attribute TIMER_DIV can be: 128 (7 bits), 1024 (10 bits) or 1,048,576 (20 bits). The divided output is provided for those user situations, where a very slow clock is desired. If even a slower toggling clock is desired, then the pro-grammable macrocell resources can be used to further divide down the TIMEROUT output.Figure 14 shows the simplified relationship among OSCOUT , TIMERRES and TIMEROUT . In the diagram, the sig-nal “R” is an internal reset signal that is used to synchronize TIMERRES to OSCOUT . This adds one extra clock cycle delay for the first timer transition after TIMERRES.Figure 14. Relationship Among OSCOUT, TIMERRES and TIMEROUTSignal Name Input or Out-put Optional / Required DescriptionOSCOUT Output Optional Oscillator Output (Nominal Frequency: 5MHz)TIMEROUTOutput Optional Oscillator Frequency Divided by an integer TIMER_DIV (Default 128)TIMERRES Input Optional Reset the TimerDYNOSCDISInputOptionalDisables the Oscillator, resets the Timer and saves the power.Some Simple Use ScenariosThe following diagrams show a few simple examples that omit optional signals for the OSCTIMER block:A. An oscillator giving 5MHz nominal clockB. An oscillator that can be disabled with an external signal (5MHz nominal clock)C. An oscillator giving approximately 5 Hz nominal clock (TIMER_DIV = 220 (1,048,576))D. An oscillator giving two output clocks: ~5MHz and ~5KHz (TIMER_DIV= 210 (1,024))OSCTIMER Integration With CPLD FabricThe OSCTIMER is integrated into the CPLD fabric using the Global Routing Pool (GRP). The macrocell (MC) feed-back path for two macrocells is augmented with a programmable multiplexer, as shown in Figure 15. The OSC-TIMER outputs (OSCOUT and TIMEROUT) can optionally drive the GRP lines, whereas the macrocell outputs can drive the optional OSCTIMER inputs TIMERRES and DYNOSCDIS.Figure 15. OSCTIMER Integration With CPLD FabricT able 12 shows how these two MCs are designated in each of the ispMACH4000ZE device.Table 12. OSC and TIMER MC DesignationZero Power/Low Power and Power ManagementThe ispMACH 4000ZE family is designed with high speed low power design techniques to offer both high speed and low power. With an advanced E 2 low power cell and non sense-amplifier design approach (full CMOS logic approach), the ispMACH 4000ZE family offers fast pin-to-pin speeds, while simultaneously delivering low standby power without needing any “turbo bits” or other power management schemes associated with a traditional sense-amplifier approach.The zero power ispMACH 4000ZE is based on the 1.8V ispMACH 4000Z family. With innovative circuit design changes, the ispMACH 4000ZE family is able to achieve the industry’s lowest static power.IEEE 1149.1-Compliant Boundary Scan TestabilityAll ispMACH 4000ZE devices have boundary scan cells and are compliant to the IE E E 1149.1 standard. This allows functional testing of the circuit board on which the device is mounted through a serial scan path that can access all critical logic notes. Internal registers are linked internally, allowing test data to be shifted in and loaded directly onto test nodes, or test node data to be captured and shifted out for verification. In addition, these devices can be linked into a board-level serial scan path for more board-level testing. The test access port operates with an LVCMOS interface that corresponds to the power supply voltage.I/O Quick ConfigurationT o facilitate the most efficient board test, the physical nature of the I/O cells must be set before running any continu-ity tests. As these tests are fast, by nature, the overhead and time that is required for configuration of the I/Os’physical nature should be minimal so that board test time is minimized. The ispMACH 4000ZE family of devices allows this by offering the user the ability to quickly configure the physical nature of the I/O cells. This quick config-uration takes milliseconds to complete, whereas it takes seconds for the entire device to be programmed. Lattice's ispVM™ System programming software can either perform the quick configuration through the PC parallel port, or can generate the A TE or test vectors necessary for a third-party test system.IEEE 1532-Compliant In-System ProgrammingProgramming devices in-system provides a number of significant benefits including: rapid prototyping, lower inven-tory levels, higher quality and the ability to make in-field modifications. All ispMACH 4000ZE devices provide In-System Programming (ISP™) capability through the Boundary Scan T est Access Port. This capability has been implemented in a manner that ensures that the port remains complaint to the IEEE 1149.1 standard. By using IEEE 1149.1 as the communication interface through which ISP is achieved, users get the benefit of a standard, well-defined interface. All ispMACH 4000ZE devices are also compliant with the IEEE 1532 standard.The ispMACH 4000ZE devices can be programmed across the commercial temperature and voltage range. The PC-based Lattice software facilitates in-system programming of ispMACH 4000ZE devices. The software takes the JEDEC file output produced by the design implementation software, along with information about the scan chain,and creates a set of vectors used to drive the scan chain. The software can use these vectors to drive a scan chain via the parallel port of a PC. Alternatively, the software can output files in formats understood by common auto-DeviceMacrocell Block NumberMC NumberispMACH 4032ZE OSC MC TIMER MC A B 1515ispMACH 4064ZE OSC MC TIMER MC A D 1515ispMACH 4128ZE OSC MC TIMER MC A G 1515ispMACH 4256ZEOSC MC TIMER MCC F1515。

W78C32C/W78C032C DATA SHEET8-BIT MICROCONTROLLER Table of Contents-1.GENERAL DESCRIPTION (2)2.FEATURES (2)3.PIN CONFIGURATIONS (3)4.PIN DESCRIPTION (4)5.FUNCTIONAL DESCRIPTION (6)5.1TIMERS 0, 1, AND 2 (6)5.2CLOCK (6)5.2.1CRYSTAL OSCILLATOR (6)5.2.2EXTERNAL CLOCK (6)5.3POWER MANAGEMENT (6)5.3.1IDLE MODE (6)5.3.2POWER-DOWN MODE (7)5.3.3RESET (7)6.ELECTRICAL CHARACTERISTICS (8)6.1ABSOLUTE MAXIMUM RATINGS (8)6.2 D.C. CHARACTERISTICS (8)6.3 A.C. CHARACTERISTICS (9)6.3.1CLOCK INPUT WAVEFORM (9)6.3.2PROGRAM FETCH CYCLE (10)6.3.3DATA READ CYCLE (10)6.3.4DATA WRITE CYCLE (11)6.3.5PORT ACCESS CYCLE (11)7.TIMING waveformS (12)7.1PROGRAM FETCH CYCLE (12)7.2DATA READ CYCLE (12)7.3DATA WRITE CYCLE (13)7.4PORT ACCESS CYCLE (13)8.TYPICAL APPLICATION CIRCUIT (14)8.1USING EXTERNAL PROGRAM MEMORY AND CRYSTAL (14)8.2EXPANDED EXTERNAL DATA MEMORY AND OSCILLATOR (15)9.PACKAGE DIMENSIONS (16)9.140-PIN DIP (16)9.244-PIN PLCC (16)9.344-PIN QFP (17)10.REVISION HISTORY (18)Publication Release Date: December 4, 2006full supply voltage ratchpad RAM ce ress space s ters x xPackages:− Lead Free (RoHS) DIP 40: W78C032C40DL − Lead Free (RoHS) PLCC 44: W78C032C40PL − Lead Free (RoHS) PQFP 44: W78C032C40FL1. GENERAL DESCRIPTIONThe W78C032C microcontroller supplies a wider frequency range than most 8-bit microcontrollers on the market. It is compatible with the industry standard 80C32 microcontroller series.The W78C032C contains four 8-bit bidirectional parallel ports, three 16-bit timer/counters, and a serial port. These peripherals are supported by a six-source, two-level interrupt capability. There are 256 bytes of RAM, and the device supports ROMless operation for application programs.The W78C032C microcontroller has two power reduction modes, idle mode and power-down mode, both of which are software selectable. The idle mode turns off the processor clock but allows for continued peripheral operation. The power-down mode stops the crystal oscillator for minimum power consumption. The external clock can be stopped at any time and in any state without affecting the 1.processor.2. FEATURESx 8-bit CMOS microcontroller x Fully static designx Low standby current at x DC-40 MHz operationx 256 bytes of on-chip sc x ROMless operationx 64K bytes program memory address spa x 64K bytes data memory add x Four 8-bit bidirectional port x Three 16-bit timer/coun x One full duplex serial port x Boolean processorx Six-source, two-level interrupt capability Built-in power management3. PIN CONFIGURATIONSPublication Release Date: December 4, 20064. PIN DESCRIPTIONP0.0−P0.7Port 0, Bits 0 through 7. Port 0 is a bidirectional I/O port. This port also provides a multiplexed low order address/data bus during accesses to external memory.P1.0−P1.7Port 1, Bits 0 through 7. Port 1 is a bidirectional I/O port with internal pull-ups. Pins P1.0 and P1.1 also serve as T2 (Timer 2 external input) and T2EX (Timer 2 capture/reload trigger), respectively.P2.0−P2.7Port 2, Bits 0 through 7. Port 2 is a bidirectional I/O port with internal pull-ups. This port also provides the upper address bits for accesses to external memory.P3.0−P3.7Port 3, Bits 0 through 7. Port 3 is a bidirectional I/O port with internal pull-ups. All bits have alternate functions, which are described below:EAExternal Address Input, active low. This pin forces the processor to execute out of external ROM. This pin should be kept low for all W78C032C operations.RSTReset Input, active high. This pin resets the processor. It must be kept high for at least two machine cycles in order to be recognized by the processor.ALEAddress Latch Enable Output, active high. ALE is used to enable the address latch that separates the address from the data on Port 0. ALE runs at 1/6th of the oscillator frequency. A single ALE pulse is skipped during external data memory accesses. ALE goes to a high state during reset with a weak pull-up.PSENProgram Store Enable Output, active low. PSEN enables the external ROM onto the Port 0 address/data bus during fetch and MOVC operations. PSEN goes to a high state during reset with a weak pull-up.XTAL1Crystal 1. This is the crystal oscillator input. This pin may be driven by an external clock.XTAL2Crystal 2. This is the crystal oscillator output. It is the inversion of XTAL1.V SS, V CCPower Supplies. These are the chip ground and positive supplies.Publication Release Date: December 4, 20065.2.1 5.2.2 5.3.1 5. FUNCTIONAL DESCRIPTIONThe W78C032C architecture consists of a core controller surrounded by various registers, four general purpose I/O ports, 256 bytes of RAM, three timer/counters, and a serial port. The processor supports 111 different instruction and references both a 64K program address space and a 64K data storage space.5.1 Timers 0, 1, and 2Timers 0, 1, and 2 each consist of two 8-bit data registers. These are called TL0 and TH0 for Timer 0, TL1 and TH1 for Timer 1, and TL2 and TH2 for Timer 2. The TCON and TMOD registers provide control functions for timers 0, 1. The T2CON register provides control functions for Timer 2. RCAP2H and RCAP2L are used as reload/capture registers for Timer 2.The operations of Timer 0 and Timer 1 are the same as in the W78C31. Timer 2 is a special feature of the W78C032C: it is a 16-bit timer/counter that is configured and controlled by the T2CON register. Like Timers 0 and 1, Timer 2 can operate as either an external event counter or as an internal timer, depending on the setting of bit C/T2 in T2CON. Timer 2 has three operating modes: capture, auto-reload, and baud rate generator. The clock speed at capture or auto-reload mode is the same as that of Timers 0 and 1.5.2 ClockThe W78C032C is designed to be used with either a crystal oscillator or an external clock. Internally, the clock is divided by two before it is used. This makes the W78C032C relatively insensitive to duty cycle variations in the clock.Crystal OscillatorThe W78C032C incorporates a built-in crystal oscillator. To make the oscillator work, a crystal must be connected across pins XTAL1 and XTAL2. In addition, a load capacitor must be connected from each pin to ground, and a resistor must also be connected from XTAL1 to XTAL2 to provide a DC bias when the crystal frequency is above 24 MHz.External ClockAn external clock should be connected to pin XTAL1. Pin XTAL2 should be left unconnected. The XTAL1 input is a CMOS-type input, as required by the crystal oscillator. As a result, the external clock signal should have an input one level of greater than 3.5 volts.5.3 Power ManagementIdle ModeThe idle mode is entered by setting the IDL bit in the PCON register. In the idle mode, the internal clock to the processor is stopped. The peripherals and the interrupt logic continue to be clocked. The processor will exit idle mode when either an interrupt or a reset occurs.Publication Release Date: December 4, 20065.3.2 5.3.3 ResetPower-down ModeWhen the PD bit of the PCON register is set, the processor enters the power-down mode. In this mode all of the clocks, including the oscillator are stopped. The only way to exit power-down mode is by a reset.The external RESET signal is sampled at S5P2. To take effect, it must be held high for at least two machine cycles while the oscillator is running.An internal trigger circuit in the reset line is used to deglitch the reset line when the W78C032C is used with an external RC network. The reset logic also has a special glitch removal circuit that ignores glitches on the reset line.During reset, the ports are initialized to FFH, the stack pointer to 07H, PCON (with the exception of bit 4) to 00H, and all of the other SFR registers except SBUF to 00H. SBUF is not reset.6. ELECTRICAL CHARACTERISTICS6.1 Absolute Maximum RatingsUNITMAX.MIN.PARAMETER SYMBOLDC Power Supply V CC−V SS -0.3 +7.0 VInput Voltage V IN V SS -0.3 V CC +0.3 V70Operating Temperature T A 0°C+150Storage Temperature T ST -55°CNote: Exposure to conditions beyond those listed under Absolute Maximum Ratings may adversely affect the life and reliability of the device.6.2 D.C. CharacteristicsV CC−V SS = 5V ±10%, T A = 25° C, F OSC = 20 MHz unless otherwise specified.Publication Release Date: December 4, 2006DC Characteristics, continuedSPECIFICATIONPARAMETER SYM. TEST CONDITIONS MIN. TYP. MAX.UNITInput Low Voltage XTAL1, RST (*3)V IL2 V DD = 4.5V 0 - 0.8 V Input High Voltage P1, P3V IH1V DD = 5.5V 2.4 - V DD +0.2 V Input High Voltage XTAL1, RST (*3)V IH2V DD = 5.5V3.5-V DD +0.2VNotes: 1. P0 and P2 are in external access mode. 2. RST pin has an internal pull-down resistor of about 30K Ω. 3. XTAL1 is a CMOS input and RST is a Schmitt trigger input.6.3 A.C. CharacteristicsThe AC specifications are a function of the particular process used to manufacture the part, the ratings of the I/O buffers, the capacitive load, and the internal routing capacitance. Most of the specifications can be expressed in terms of multiple input clock periods (T CP ), and actual parts will usually experience less than a ±20 nS variation. The numbers below represent the performance expected from a 0.5 micron CMOS process when using 2 and 4 mA output buffers.6.3.1 Clock Input WaveformPARAMETER SYMBOL MIN. TYP. MAX.UNIT NOTESOperating Speed F OP 0 - 40 MHz 1 Clock Period T CP 25 - - nS 2 Clock High T CH 10 - - nS 3 Clock LowT CL 10 - - nS 3Notes:1. The clock may be stopped indefinitely in either state.2. The T CP specification is used as a reference in other specifications.3. There are no duty cycle requirements on the XTAL1 input.6.3.2 Program Fetch CycleNotes:1.P0.0−P0.7, P2.0−P2.7 remain stable throughout entire memory cycle.2. Memory access time is 3 T CP.3. Data have been latched internally prior to PSEN going high.4."Δ" ( due to buffer driving delay and wire loading) is 20 nS.6.3.3 Data Read CycleNotes:1. Data memory access time is 8 T CP."Δ" (due to buffer driving delay and wire loading) is 20 nS.2.Publication Release Date: December 4, 20066.3.4 Data Write CycleNote: "Δ" ( due to buffer driving delay and wire loading) is 20 nS.6.3.5 Port Access CyclePARAMETER SYMBOL MIN. TYP. MAX. UNITPort Input Setup to ALE Low T PDS 1 T CP - - nS Port Input Hold from ALE Low T PDH 0 - - nS Port Output to ALET PDA 1 T CP - - nSNote: Ports are read during S5P2, and output data becomes available at the end of S6P2. The timing data are referenced toALE, since it provides a convenient reference.7. TIMING WAVEFORMS 7.1 Program Fetch Cycle7.2 Data Read CycleTiming Waveforms, continued7.3 Data Write Cycle7.4 Port Access CyclePublication Release Date: December 4, 20068. TYPICAL APPLICATION CIRCUIT8.1 Using External Program Memory and CrystalFigure ARC2CRYSTAL C116 MHz 30P 30P -24 MHz 15P 15P -33 MHz 10P 10P 6.8K40 MHz 5P 5P 6.8KAbove table shows the reference values for crystal applications.Note: C1, C2, R components refer to Figure A.8.2 Expanded External Data Memory and OscillatorFigure BPublication Release Date: December 4, 20069. PACKAGE DIMENSIONS 9.1 40-pin DIP9.2 44-pin PLCCPackage Dimensions, continued9.3 44-pin QFPPublication Release Date: December 4, 200610. REVISION HISTORYVERSION DATE PAGE DESCRIPTION A2 July 1999 - Initial IssuedA3 June, 2004 2 Revise part number in the item of packagesA4 April 19, 2005 17 Add Important NoticeA5 June 7, 2005 2 Add Lead Free (RoHS) partsRemove block diagramA6 December 4, 20062 Remove all Leaded package partsImportant NoticeWinbond products are not designed, intended, authorized or warranted for use as components in systems or equipment intended for surgical implantation, atomic energy control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion control instruments, or for other applications intended to support or sustain life. Further more, Winbond products are not intended for applications wherein failure of Winbond products could result or lead to a situation wherein personal injury, death or severe property or environmental damage could occur.Winbond customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Winbond for any damages resulting from such improper use or sales.。