CXD2073S中文资料

SN74CBT3306CDUAL FET BUS SWITCH5ĆV BUS SWITCH WITH ć2ĆV UNDERSHOOT PROTECTIONSCDS127A − SEPTEMBER 2003 − REVISED OCTOBER 2003D Undershoot Protection for Off-Isolation on A and B Ports Up To −2 VD Bidirectional Data Flow, With Near-Zero Propagation DelayD Low ON-State Resistance (r on )Characteristics (r on = 3 Ω Typical)D Low Input/Output Capacitance Minimizes Loading and Signal Distortion (C io(OFF) = 5 pF Typical)D Data and Control Inputs Provide Undershoot Clamp Diodes D Low Power Consumption (I CC = 3 µA Max)D V CC Operating Range From 4 V to 5.5 V DData I/Os Support 0 to 5-V Signaling Levels (0.8-V, 1.2-V, 1.5-V, 1.8-V, 2.5-V, 3.3-V, 5-V)D Control Inputs Can Be Driven by TTL or 5-V/3.3-V CMOS OutputsD I off Supports Partial-Power-Down Mode OperationD Latch-Up Performance Exceeds 100 mA Per JESD 78, Class IIDESD Performance Tested Per JESD 22− 2000-V Human-Body Model (A114-B, Class II)− 1000-V Charged-Device Model (C101)DSupports Both Digital and AnalogApplications: USB Interface, Bus Isolation,Low-Distortion Signal GatingD OR PW PACKAGE(TOP VIEW)123487651OE 1A 1B GNDV CC 2OE 2B 2Adescription/ordering informationThe SN74CBT3306C is a high-speed TTL-compatible FET bus switch with low ON-state resistance (r on ),allowing for minimal propagation delay. Active Undershoot-Protection Circuitry on the A and B ports of the SN74CBT3306C provides protection for undershoot up to −2 V by sensing an undershoot event and ensuring that the switch remains in the proper OFF state.The SN74CBT3306C is organized as two 1-bit bus switches with separate output-enable (1OE, 2OE) inputs.It can be used as two 1-bit bus switches or as one 2-bit bus switch. When OE is low, the associated 1-bit bus switch is ON, and the A port is connected to the B port, allowing bidirectional data flow between ports. When OE is high, the associated 1-bit bus switch is OFF, and the high-impedance state exists between the A and B ports.ORDERING INFORMATIONT APACKAGE †ORDERABLE PART NUMBER TOP-SIDE MARKING Tube SN74CBT3306CD SOIC − DTape and reel SN74CBT3306CDR CU306C −40°C to 85°CTube SN74CBT3306CPW TSSOP − PWTape and reelSN74CBT3306CPWRCU306C†Package drawings, standard packing quantities, thermal data, symbolization, and PCB design guidelines are available at /sc/package.Copyright 2003, Texas Instruments IncorporatedPlease be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.PRODUCTION DATA information is current as of publication date.SN74CBT3306CDUAL FET BUS SWITCH5ĆV BUS SWITCH WITH ć2ĆV UNDERSHOOT PROTECTIONSCDS127A − SEPTEMBER 2003 − REVISED OCTOBER 2003description/ordering information (continued)This device is fully specified for partial-power-down applications using I off . The I off feature ensures that damaging current will not backflow through the device when it is powered down. The device has isolation during power off.To ensure the high-impedance state during power up or power down, OE should be tied to V CC through a pullup resistor; the minimum value of the resistor is determined by the current-sinking capability of the driver.FUNCTION TABLE (each bus switch)INPUT INPUT/OUTPUTOE AFUNCTION L B A port = B port HZDisconnectlogic diagram (positive logic)1A 1OESW1B2A 2OESW2B215736simplified schematic, each FET switch (SW)AEN †B†EN is the internal enable signal applied to the switch.Undershoot Protection CircuitSN74CBT3306CDUAL FET BUS SWITCH5ĆV BUS SWITCH WITH ć2ĆV UNDERSHOOT PROTECTIONSCDS127A − SEPTEMBER 2003 − REVISED OCTOBER 2003 absolute maximum ratings over operating free-air temperature range (unless otherwise noted)†. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Supply voltage range, V CC−0.5 V to 7 V Control input voltage range, V IN (see Notes 1 and 2) −0.5 V to 7 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Switch I/O voltage range, V I/O (see Notes 1, 2, and 3) −0.5 V to 7 V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Control input clamp current, I IK(V IN< 0) −50 mA. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .I/O port clamp current, I I/OK(V I/O< 0) −50 mA ON-state switch current, I I/O (see Note 4) ±128 mA. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Continuous current through V CC or GND terminals ±100 mA. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Package thermal impedance, θJA (see Note 5):D package 97°C/W. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .PW package 149°C/W Storage temperature range, T stg −65°C to 150°C. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .†Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.NOTES: 1.All voltages are with respect to ground unless otherwise specified.2.The input and output voltage ratings may be exceeded if the input and output clamp-current ratings are observed.3.V I and V O are used to denote specific conditions for V I/O.4.I I and I O are used to denote specific conditions for I I/O.5.The package thermal impedance is calculated in accordance with JESD 51-7.recommended operating conditions (see Note 6)MIN MAX UNITV CC Supply voltage4 5.5VV IH High-level control input voltage2 5.5VV IL Low-level control input voltage00.8VV I/O Data input/output voltage0 5.5VT A Operating free-air temperature−4085°C NOTE 6:All unused control inputs of the device must be held at V CC or GND to ensure proper device operation. Refer to the TI application report, Implications of Slow or Floating CMOS Inputs, literature number SCBA004.SN74CBT3306CDUAL FET BUS SWITCH5ĆV BUS SWITCH WITH ć2ĆV UNDERSHOOT PROTECTIONSCDS127A − SEPTEMBER 2003 − REVISED OCTOBER 2003electrical characteristics over recommended operating free-air temperature range (unless otherwise noted)PARAMETER TEST CONDITIONS MINTYP †MAX UNIT V IK Control inputs V CC = 4.5 V,I IN = −18 mA−1.8V V IKU Data inputs V CC = 5 V,0 mA > I I ≥ −50 mA,V IN = V CC or GND,Switch OFF−2V I IN Control inputsV CC = 5.5 V,V IN = V CC or GND ±1µA I OZ ‡V CC = 5.5 V,V O = 0 to 5.5 V,V I = 0,Switch OFF,V IN = V CC or GND ±10µA I off V CC = 0,V O = 0 to 5.5 V,V I = 010µA I CC V CC = 5.5 V,I I/O = 0,V IN = V CC or GND,Switch ON or OFF3µA ∆I CC §Control inputs V CC = 5.5 V,One input at 3.4 V,Other inputs at V CC or GND2.5mA C in Control inputs V IN = 3 V or 0 3.5pF C io(OFF)V I/O = 3 V or 0,Switch OFF,V IN = V CC or GND 5pF C io(ON)V I/O = 3 V or 0,Switch ON,V IN = V CC or GND 12.5pFV CC = 4 V,TYP at V CC = 4 VV I = 2.4 V,I O = −15 mA 812on ¶V I O = 64 mA 36r V I = 0I O = 30 mA36ΩCC = 4.5 VV I = 2.4 V,I O = −15 mA 510V IN and I IN refer to control inputs. V I , V O , I I , and I O refer to data pins.†All typical values are at V CC = 5 V (unless otherwise noted), T A = 25°C.‡For I/O ports, the parameter I OZ includes the input leakage current.§This is the increase in supply current for each input that is at the specified voltage level, rather than V CC or GND.¶Measured by the voltage drop between the A and B terminals at the indicated current through the switch. ON-state resistance is determined by the lower of the voltages of the two (A or B) terminals.switching characteristics over recommended operating free-air temperature range (unless otherwise noted) (see Figure 3)FROM TO V CC = 4 V V CC = 5 V ± 0.5 V PARAMETER(INPUT)(OUTPUT)MINMAX MINMAX UNITt pd # A or B B or A 0.240.15ns t en OE A or B 4.6 1.5 4.2ns t disOEA or B4.31.5 4.3ns #The propagation delay is the calculated RC time constant of the typical ON-state resistance of the switch and the specified load capacitance,when driven by an ideal voltage source (zero output impedance).SN74CBT3306CDUAL FET BUS SWITCH5ĆV BUS SWITCH WITH ć2ĆV UNDERSHOOT PROTECTIONSCDS127A − SEPTEMBER 2003 − REVISED OCTOBER 2003undershoot characteristics (see Figures 1 and 2)PARAMETERTEST CONDITIONSMIN TYP †MAXUNIT V OUTU V CC = 5.5 V,Switch OFF,V IN = V CC or GND2V OH −0.3V†All typical values are at V CC = 5 V (unless otherwise noted), T A = 25°C.Figure 1. Device Test Setup50 ΩV SV CC11 V 100 k Ω100 k Ω10 pFDUTInputGeneratorAxBxFigure 2. Transient Input Voltage (V I ) and OutputVoltage (V OUTU ) Waveforms(Switch OFF)−2 V5.5 V10 %20 ns10 %90 %90 %2 ns2 nsV OH − 0.3V OHOutput (V OUTU )Input (Open Socket)SN74CBT3306CDUAL FET BUS SWITCH5ĆV BUS SWITCH WITH ć2ĆV UNDERSHOOT PROTECTIONSCDS127A − SEPTEMBER 2003 − REVISED OCTOBER 2003PARAMETER MEASUREMENT INFORMATIONV OH V OLC L(see Note A)TEST CIRCUITS17 VOpen GNDR LR Lt PLH t PHLOutput Waveform 1S1 at 7 V (see Note B)Output Waveform 2S1 at Open (see Note B)t PZLt PZHt PLZt PHZ 3 V0 V V OH V OL0 VV OL + V ∆V OH − V ∆0 VOutput Control (V IN )3 V3.5 VVOLTAGE WAVEFORMSPROPAGATION DELAY TIMES (t pd(s))VOLTAGE WAVEFORMS ENABLE AND DISABLE TIMESOutputNOTES: A.C L includes probe and jig capacitance.B.Waveform 1 is for an output with internal conditions such that the output is low except when disabled by the output control.Waveform 2 is for an output with internal conditions such that the output is high except when disabled by the output control.C.All input pulses are supplied by generators having the following characteristics: PRR ≤10 MHz, Z O = 50 Ω, t r ≤2.5 ns, t f ≤2.5 ns.D.The outputs are measured one at a time with one transition per measurement.E.t PLZ and t PHZ are the same as t dis .F.t PZL and t PZH are the same as t en .G.t PLH and t PHL are the same as t pd(s). The tpd propagation delay is the calculated RC time constant of the typical ON-stateresistance of the switch and the specified load capacitance, when driven by an ideal voltage source (zero output impedance).H.All parameters and waveforms are not applicable to all devices.1.5 V1.5 V1.5 V1.5 V1.5 V 1.5 V1.5 V1.5 V50 ΩV G1V CCDUT50 ΩV IN50 ΩV G250 ΩV ITEST R L S1V ∆C L 5 V ±0.5 V4 V V CC V I t PHZ /t PZHt PLZ /t PZL t pd(s) 5 V ±0.5 V4 V5 V ±0.5 V4 VOpen Open 7 V 7 V Open Open500 Ω500 Ω500 Ω500 Ω500 Ω500 ΩV CC or GND V CC or GNDGND GND V CC V CC 50 pF 50 pF 50 pF 50 pF 50 pF 50 pF0.3 V 0.3 V 0.3 V 0.3 VOutput Control (V IN )Input GeneratorInput GeneratorV OFigure 3. Test Circuit and Voltage WaveformsPACKAGING INFORMATION(1) The marketing status values are defined as follows:ACTIVE: Product device recommended for new designs.LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.PREVIEW: Device has been announced but is not in production. Samples may or may not be available.OBSOLETE: TI has discontinued the production of the device.(2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may reference these types of products as "Pb-Free".RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based flame retardants must also meet the <=1000ppm threshold requirement.(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation of the previous line and the two combined represent the entire Device Marking for that device.(6) Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two lines if the finish value exceeds the maximum column width.Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken andAddendum-Page 1continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.Addendum-Page 2TAPE AND REEL INFORMATION*All dimensions are nominalDevicePackage Type Package Drawing Pins SPQReel Diameter (mm)Reel Width W1(mm)A0(mm)B0(mm)K0(mm)P1(mm)W (mm)Pin1Quadrant SN74CBT3306CDR SOIC D 82500330.012.4 6.4 5.2 2.18.012.0Q1SN74CBT3306CPWR TSSOP PW 82000330.012.47.0 3.6 1.68.012.0Q1SN74CBT3306CPWRTSSOPPW82000330.012.47.03.61.68.012.0Q1*All dimensions are nominalDevice Package Type Package Drawing Pins SPQ Length(mm)Width(mm)Height(mm) SN74CBT3306CDR SOIC D8*******.5336.125.0 SN74CBT3306CPWR TSSOP PW82000367.0367.035.0SN74CBT3306CPWR TSSOP PW82000364.0364.027.0TUBE*All dimensions are nominalDevice Package NamePackage TypePins SPQ L (mm)W (mm)T (µm)B (mm)SN74CBT3306CD D SOIC 87550783940 4.32SN74CBT3306CPWPWTSSOP815053010.236003.5PACKAGE MATERIALS INFORMATION5-Jan-2022PACKAGE OUTLINESOIC - 1.75 mm max heightD0008ASMALL OUTLINE INTEGRATED CIRCUITNOTES:1. Linear dimensions are in inches [millimeters]. Dimensions in parenthesis are for reference only. Controlling dimensions are in inches. Dimensioning and tolerancing per ASME Y14.5M.2. This drawing is subject to change without notice.3. This dimension does not include mold flash, protrusions, or gate burrs. Mold flash, protrusions, or gate burrs shall not exceed .006 [0.15] per side.4. This dimension does not include interlead flash.5. Reference JEDEC registration MS-012, variation AA.EXAMPLE BOARD LAYOUTSOIC - 1.75 mm max heightD0008ASMALL OUTLINE INTEGRATED CIRCUITNOTES: (continued)6. Publication IPC-7351 may have alternate designs.7. Solder mask tolerances between and around signal pads can vary based on board fabrication site.EXAMPLE STENCIL DESIGNSOIC - 1.75 mm max heightD0008ASMALL OUTLINE INTEGRATED CIRCUITNOTES: (continued)8. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate design recommendations.9. Board assembly site may have different recommendations for stencil design.PACKAGE OUTLINETSSOP - 1.2 mm max heightPW0008ASMALL OUTLINE PACKAGENOTES:1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing per ASME Y14.5M.2. This drawing is subject to change without notice.3. This dimension does not include mold flash, protrusions, or gate burrs. Mold flash, protrusions, or gate burrs shall not exceed 0.15 mm per side.4. This dimension does not include interlead flash. Interlead flash shall not exceed 0.25 mm per side.5. Reference JEDEC registration MO-153, variation AA.EXAMPLE BOARD LAYOUT PW0008ATSSOP - 1.2 mm max heightSMALL OUTLINE PACKAGE ArrayNOTES: (continued)6. Publication IPC-7351 may have alternate designs.7. Solder mask tolerances between and around signal pads can vary based on board fabrication site.EXAMPLE STENCIL DESIGN PW0008ATSSOP - 1.2 mm max heightSMALL OUTLINE PACKAGE ArrayNOTES: (continued)8. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternatedesign recommendations.9. Board assembly site may have different recommendations for stencil design.IMPORTANT NOTICE AND DISCLAIMERTI PROVIDES TECHNICAL AND RELIABILITY DATA (INCLUDING DATA SHEETS), DESIGN RESOURCES (INCLUDING REFERENCE DESIGNS), APPLICATION OR OTHER DESIGN ADVICE, WEB TOOLS, SAFETY INFORMATION, AND OTHER RESOURCES “AS IS” AND WITH ALL FAULTS, AND DISCLAIMS ALL WARRANTIES, EXPRESS AND IMPLIED, INCLUDING WITHOUT LIMITATION ANY IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT OF THIRD PARTY INTELLECTUAL PROPERTY RIGHTS.These resources are intended for skilled developers designing with TI products. You are solely responsible for (1) selecting the appropriate TI products for your application, (2) designing, validating and testing your application, and (3) ensuring your application meets applicable standards, and any other safety, security, regulatory or other requirements.These resources are subject to change without notice. TI grants you permission to use these resources only for development of an application that uses the TI products described in the resource. Other reproduction and display of these resources is prohibited. No license is granted to any other TI intellectual property right or to any third party intellectual property right. TI disclaims responsibility for, and you will fully indemnify TI and its representatives against, any claims, damages, costs, losses, and liabilities arising out of your use of these resources.TI’s products are provided subject to TI’s Terms of Sale or other applicable terms available either on or provided in conjunction with such TI products. TI’s provision of these resources does not expand or otherwise alter TI’s applicable warranties or warranty disclaimers for TI products.TI objects to and rejects any additional or different terms you may have proposed.Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265Copyright © 2022, Texas Instruments Incorporated。

CSA940PNP PLASTIC POWER TRANSISTOR CSC2073NPN PLASTIC POWER TRANSISTORPower Amplifier Applications and Vertical Output ApplicationsABSOLUTE MAXIMUM RATINGS Collector-base voltage (open emitter)V CBO max.150V Collector-emitter voltage (open base)V CEO max.150V Collector currentI C max. 1.5A Total power dissipation up to T C = 25°C P tot max.25W Junction temperatureT j max.150°CCollector-emitter saturation voltageI C = 500 mA; I B = 50 mA V CEsat max. 1.5V D.C. current gainI C = 500 mA; V CE = 10 Vh FEmin.40max.140RATINGS (at T A =25°C unless otherwise specified)Limiting valuesCollector-base voltage (open emitter)V CBO max.150V Collector-emitter voltage (open base)V CEO max.150V Emitter-base voltage (open collector)V EBOmax. 5.0VCSA940, CSC2073TO-220 Plastic Package Continental Device India LimitedAn ISO/TS16949 and ISO 9001 Certified CompanyCSA940, CSC2073 Collector current I C max. 1.5A Base current I B max.0.5A Total power dissipation up to T C = 25°C P tot max.25W Total power dissipation up to T A = 25°C P tot max. 1.5W Junction temperature T j max.150ºC Storage temperature T stg–65 to +150ºC CHARACTERISTICST a m b = 25°C unless otherwise specifiedCollector cutoff currentI E = 0; V CB = 120 V I CBO max.10µA Emitter cut-off currentI C = 0; V EB = 5 V I EBO max.10µA Breakdown voltagesI C = 1 mA; I B = 0V CEO min.150VI C = 1 mA; I E = 0V CBO min.150VI E = 1 mA; I C = 0V EBO min. 5.0V Saturation voltagesI C = 500 mA; I B = 50 mA V CEsat max. 1.5V Base emitter on voltageI C = 500 mA; V CE = 10 V V BE(on)min.0.65Vmax.0.85V D.C. current gainI C = 500 mA; V CE = 10 V h FE min.40max.140 Output capacitance at f = 1 MHzI E = 0; V CB = 10 V NPN C o typ.35pFPNP typ.55pF Transition frequencyI C = 500 mA; V CE = 10 V f T typ.4MHzCustomer NotesDisclaimerThe product information and the selection guides facilitate selection of the CDIL's Discrete Semiconductor Device(s) best suited for application in your product(s) as per your requirement. It is recommended that you completely review our Data Sheet(s) so as to confirm that the Device(s) meet functionality parameters for your application. The information furnished on the CDIL Web Site/ CD are believed to be accurate and reliable. CDIL however, does not assume responsibility for inaccuracies or incomplete information. Furthermore, CDIL does not assume liability whatsoever, arising out of the application or use of any CDIL product; neither does it convey any license under its patent rights nor rights of others. These products are not designed for use in life saving/support appliances or systems. CDIL customers selling these products (either as individual Discrete Semiconductor Devices or incorporated in their end products), in any life saving/support appliances or systems or applications do so at their own risk and CDIL will not be responsible for any damages resulting from such sale(s).CDIL strives for continuous improvement and reserves the right to change the specifications of its products without prior notice.CDIL is a registered Trademark ofContinental Device India LimitedC-120 Naraina Industrial Area, New Delhi 110 028, India.Telephone + 91-11-2579 6150, 5141 1112 Fax + 91-11-2579 5290, 5141 1119email@ 。

PhilipsCD机光头、DAC、IC机芯对照表PHILIPS CD100 2 x TDA1540D CDM-0PHILIPS CD200 2 x TDA1540D – SAA7030 CDM-0PHILIPS CD202 2 x TDA1540D – SAA7030 CDM-0PHILIPS CD300 2 x TDA1540D – SAA7030 CDM-0PHILIPS CD303 2 x TDA1540D – SAA7030 CDM-0PHILIPS LHH2000 2 x TDA1540P – SAA7030 CDM-0 / CDM-1PHILIPS CD101 2 x TDA1540D CDM-1PHILIPS CD104 2 x TDA1540P – SAA7030 CDM-1PHILIPS CD204 2 x TDA1540P – SAA7030 CDM-1PHILIPS CD304 2 x TDA1540P – SAA7030 CDM-1PHILIPS CD304 Mk II TDA1541-S1 (Single Crown) CDM-1PHILIPS CD960 TDA1541 – SAA7220 – SAA7210 CDM-1PHILIPS LHH1000 TDA1541A-S1 (Double Crown) CDM-1 PHILIPS CD-80 TDA1541A-S1 (Single Crown) CDM-1 Mk IIPHILIPS CD-85 TDA1541A-S1 (Single Crown) CDM-1 Mk IIPHILIPS CD880 TDA1541A-S1 (Single Crown) CDM-1 Mk IIPHILIPS CDD882 It’s a Transport – SAA7210P CDM-1 Mk II PHILIPS CD151 2 x TDA1540P – SAA7030 CDM-2PHILIPS CD207 TDA1541 CDM-2PHILIPS CD372 TDA1541 CDM-2PHILIPS CD450 TDA1541 – SAA7220P/A CDM-2PHILIPS CD640 TDA1541 – SAA7220P/A CDM-2PHILIPS CD350 2 x TDA1540P – SAA7030 CDM-2 / CDM-2/10PHILIPS CD782 TDA1541 – SAA7220P/A CDM-2 / CDM-4PHILIPS CD373 TDA1541 CDM-2 / CDM-4/11PHILIPS CD470 TDA1541 CDM-2 / CDM-4/11PHILIPS CD471 TDA1541 CDM-2 / CDM-4/11PHILIPS CD473 TDA1541 CDM-2 / CDM-4/11PHILIPS CD660 TDA1541 – SAA7220P/A CDM-2 / CDM-4/11PHILIPS CD771 TDA1541 – SAA7220P/A CDM-2 / CDM-4/11PHILIPS CD150 2 x TDA1540P – SAA7030 CDM-2/10PHILIPS CD160 TDA1541 – SAA7220P/A CDM-2/10PHILIPS CD350 Mk II TDA1541-S1 (Single Crown) CDM-2/10 / CDM-2/29PHILIPS CD360 TDA1541 CDM-2/10 / CDM-2/29PHILIPS CD670 TDA1541 –SAA7220P/A CDM-2/10 / CDM-4/11PHILIPS CD460 TDA1541 / TDA1543 – SAA7220P/A CDM-2/10 / CDM-4/25PHILIPS CD650 TDA1541 – SAA7220P/A – SAA7210 CDM-2/10 / CDM-4/25PHILIPS CD371 TDA1541 CDM-2/29 / CDM-4/11PHILIPS CD130 TDA1543 CDM-4PHILIPS LHH500 2 x SAA7321GP – SAA7220P/B CDM-4 MetallicPHILIPS LHH500R 1 x TDA1547 –SM5803AP CDM-4 MetallicPHILIPS LHH600 TDA1547 (DAC7) CDM-4 MetallicPHILIPS LHH700 2 x TDA1547 –SM5803APT CDM-4MetallicPHILIPS LHH800R 1 x TDA1547 (DAC7) –SM5803APT CDM-4 MetallicPHILIPS LHH900R 1 x TDA1547 (DAC7) CDM-4 Metallic PHILIPS CD472 TDA1541 – SAA7220P/A CDM-4/11PHILIPS AK 601 TDA1543A CDM-4/19PHILIPS AK 630 SAA7341 CDM-4/19PHILIPS CD115 TDA1543 CDM-4/19PHILIPS CD210 TDA1543 CDM-4/19PHILIPS CD230 TDA1543 CDM-4/19PHILIPS CD380 TDA1543 CDM-4/19PHILIPS CD480 TDA1541 / TDA1543 – SAA7220 CDM-4/19 PHILIPS CD482 TDA1543 – SAA7220P/A CDM-4/19PHILIPS CD500 TDA1543 CDM-4/19PHILIPS CD502 TDA1543 CDM-4/19PHILIPS CD581 TDA1541 CDM-4/19PHILIPS CD582 TDA1541 – SAA7220P/A CDM-4/19PHILIPS CD584 TDA1541A – SAA7220P/B CDM-4/19PHILIPS CD600 TDA1543 – SAA7220 CDM-4/19PHILIPS CD604 TDA1543 CDM-4/19PHILIPS CD605 SAA7321GP CDM-4/19PHILIPS CD610 TDA1543 – SAA7220 CDM-4/19PHILIPS CD614 TDA1543 CDM-4/19PHILIPS CD615 SAA7321GP CDM-4/19PHILIPS CD618 SAA7323 CDM-4/19PHILIPS CD620 TDA1541 CDM-4/19PHILIPS CD624 SAA7321GP CDM-4/19PHILIPS CD630 TDA1541A – SAA7220P/B CDM-4/19PHILIPS CD634 SAA7321 CDM-4/19PHILIPS CD780 TDA1541A – SAA7220 CDM-4/19PHILIPS CD820 TDA1541A – SAA7220P/B CDM-4/19PHILIPS CD824 SAA7321GP CDM-4/19PHILIPS CD834 SAA7321GP CDM-4/19PHILIPS CD840 2 x SAA7321GP – SAA7220P/B CDM-4/19 PHILIPS CD850 2 x SAA7321GP – SAA7220P/B CDM-4/19 PHILIPS CD850 Mk II SAA7350 CDM-4/19PHILIPS CDC875 TDA1541A CDM-4/19PHILIPS CDD461 TDA1543 CDM-4/19PHILIPS CD586 TDA1541A CDM-4/20PHILIPS CDC486 TDA1543 CDM-4/20PHILIPS CD830 TDA1541A-R1 –SAA7220P/B CDM-4/CompositePHILIPS LHH100M TDA1547 – SM5840 CDM-9PHILIPS LHH200R TDA1547 (DAC7) CDM-9PHILIPS LHH300 SAA7321 CDM-9PHILIPS LHH300R TDA1547 (DAC7) – SAA7350 CDM-9PHILIPS CD930 SAA7350 CDM-9/44PHILIPS CD940 SAA7350GP – SM5840AS CDM-9/44PHILIPS CD950 TDA1547 – SAA7350 CDM-9/44PHILIPS CD931 SAA7350 CDM-9/65PHILIPS CD951 TDA1547 – SAA7350 – SAA7310 CDM-9/65 PHILIPS DAC960 1 x TDA1541A It’s a DACPHILIPS CD722 TDA1545A VAM 1201PHILIPS CD723 TDA1545 – SAA7378 VAM 1201PHILIPS CD713 TDA1545A VAM 1202PHILIPS CD692 SAA7341GP CDM 12PHILIPS CD721 TDA1545A CDM 12PHILIPS CD732 SAA7341 CDM 12PHILIPS CD690 SAA7341 CDM 12.1PHILIPS CD710 TDA1545A – SAA7345 CDM 12.1PHILIPS CD720 TDA1545A CDM 12.1PHILIPS CD750 TDA1541A / TDA1549 CDM 12.1PHILIPS CD753 TDA1549 –SAA7378 CDM 12.1 / VAM 1201PHILIPS CD163 TDA1545A CDM 12.1/05PHILIPS CD751 TDA1549 – SAA7378 CDM 12.1/05PHILIPS CD910 SAA7341GP CDM 12.1/05PHILIPS CD911 SAA7341GP CDM 12.1/05PHILIPS CD920 SAA7341GP CDM 12.1/05PHILIPS CDC745 SAA7341GP CDM 12.1/05PHILIPS CD465 TDA1541PHILIPS CD580 TDA1541CDM-2CDM3CDM4普通板CDM4 工业版。

三极管c2073参数1.引言1.1 概述概述部分的内容：在电子电路领域中，三极管是一种重要的器件，用于放大和控制电流。

而C2073型号的三极管是一种常见的PNP型三极管，广泛应用于各种电子设备中。

本文将深入分析三极管C2073的参数与特性，旨在帮助读者更好地了解和应用这一器件。

首先，我们将介绍该三极管的基本结构和工作原理，以便读者对其有一个整体的认识。

接下来，我们将详细探讨C2073三极管的参数。

这些参数包括最大集电极电流、最大耗散功率、最大封装温度等，在实际应用中起着至关重要的作用。

我们将逐一解释每个参数的意义和对电路性能的影响，以及如何根据需要选择合适的参数值。

除了参数的介绍，我们还将介绍一些常用的测试方法和技巧，以便读者能够准确地测量和评估C2073三极管的性能。

同时，我们将介绍一些典型的应用场景和电路设计示例，以便读者能够更好地理解如何将这一器件应用到实际项目中。

最后，我们将对本文进行总结，并对未来对C2073三极管的研究和应用进行展望。

随着电子技术的不断发展，我们相信C2073三极管在各个领域都有着广阔的应用前景，希望读者能够通过本文的学习和理解，更好地利用这一器件，推动电子技术的进步。

这篇文章旨在为对三极管C2073感兴趣的读者提供详尽而全面的信息，希望能够对读者的学习和实践有所帮助。

希望读者在阅读本文后能够对三极管C2073有更深入的了解，并能够灵活运用到自己的电子设计和实验中。

文章结构部分的内容应该包括文章的组织和章节划分。

在这篇文章中，正文部分有两个章节，分别是"2.1 三极管C2073的参数1"和"2.2 三极管C2073的参数2"。

这意味着文章将首先介绍三极管C2073的第一个参数，然后介绍第二个参数。

此外，在引言部分已经提到了概述、文章结构和目的这三个方面。

因此，在文章结构部分，可以将这三个方面再次提及，并简要解释它们的重要性和目的。

USER MANUALMODEL 2707C, DG.703 NTU with V.35, X.21InterfacesSALES OFFICE (301) 975-1000TECHNICAL SUPPORT Part# 07M2707-UMDoc# 08619U2-001,Rev. BRevised 10/27/06TABLE OF CONTENTS1.0Warranty Information (2)1.1FCC Information (2)1.2CE Notice (2)1.3Service (3)2.0General Information (4)2.1Features (4)2.2Description (4)3.0Configuration (5)3.1DIP Switch Configuration (5)Switch SW1-1 through SW1-8 (6)Switch SW1-1 Line Coding: HDB3 (default) (6)SW1-2 Local Loop: Inactive (default) (7)SW1-6 and SW1-7 Clock Modes (8)SW1-8: Enable/Disable Loop Tests from DTE (8)4.0Installation (9)4.1Connecting To The G.703 Network (9)Connecting the 2707/D (X.21 version) DualCoaxial Cable (75 Ohm) to the G.703 Network (9)Opening the Case (9)Connecting the Twisted Pair (120 Ohm) tothe G.703 Network (10)4.2Connecting The Serial Port (10)Connecting to a “DTE” Device (10)Connecting to a “DCE” Device (10)Configuring the X.21 Interface (2707/D) (10)4.3Power Connection (11)Universal AC Power (100-240VAC) (11)DC Power (12)5.0Operation (13)5.1Power-up (13)5.2LED Status Monitors (13)5.3Local Loop Diagnostics (14)Operating Local Loopback (LL) (14)A Model 2707, G.703 Specifications (15)B Model 2707, Interface Pin Assignment (16)C Model 2707, Interface Pin Assignment (18)D Model 2707, Factory Replacement PartsAnd Accessories (19)1.0 WARRANTY INFORMATIONPatton Electronics warrants all Model 2707 components to be free from defects, and will—at our option—repair or replace the product should it fail within one year from the first date of shipment.This warranty is limited to defects in workmanship or materials, and does not cover customer damage, abuse, or unauthorized modification. If this product fails or does not perform as warranted, your sole recourse shall be repair or replacement as described above. Under no condition shall Patton Electronics be liable for any damages incurred by the use of this product. These damages include, but are not limited to, the following: lost profits, lost savings and incidental or consequential damages arising from the use of or inability to use this product. Patton Electronics spe-cifically disclaims all other warranties, expressed or implied, and the installation or use of this product shall be deemed an acceptance of these terms by the user.1.1FCC INFORMATIONThis equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interfer-ence when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instruction manual, may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following measures:•Reorient or relocate the receiving antenna•Increase the separation between the equipment and receiver •Connect the equipment into an outlet on a circuit different from that to which the receiver is connected1.2CE NOTICEThe CE symbol on your Patton Electronics equipment indicates that it is in compliance with the Electromagnetic Compatibility (EMC) directive and the Low Voltage Directive (LVD) of the Union European (EU). A Cer-tificate of Compliance is available by contacting Technical Support.1.3SERVICEAll warranty and nonwarranty repairs must be returned freight prepaid and insured to Patton Electronics. All returns must have a Return Mate-rials Authorization number on the outside of the shipping container. This number may be obtained from Patton Electronics Technical Services at:T el: (301) 975-1007E-mail: ******************URL: Note Packages received without an RMA number will not beaccepted.Patton Electronics' technical staff is also available to answer any ques-tions that might arise concerning the installation or use of your Patton Model 2707. T echnical Service hours: 8AM to 5PM EST, Monday through Friday.2.0 GENERAL INFORMATIONThank you for your purchase of this Patton Electronics product. This product has been thoroughly inspected and tested and is warranted for One Y ear parts and labor. If any questions or problems arise during installation or use of this product, please do not hesitate to contact Pat-ton Electronics Technical Support at (301) 975-1007.2.1FEATURES•T erminates G.703 E1 service (2.048 Mbps)•Available in low-cost standalone or rack-mountable versions•X.21 and V.35•Switch-selectable AMI or HDB3 line encoding options•Switch-selectable DTE/DCE modes for X.21 version•75 Ohm dual coax and 120 Ohm twisted-pair G.703 connections •Local loopback diagnostics•Internal, External, and G.703 network timing•CE approval•100-240VAC & 48VDC power options•Conforms to ONP requirements CTR 12 for connection to international T elecom networks2.2DESCRIPTIONThe Model 2707 receives clear channel E1/G.703 (2.048 Mbps) data from the telco's digital data network. The Model 2707 terminates the G.703 telco interface and converts the data for transmission to a user-oriented serial (X.21 and V.35). The 2707 can connect to a Router, FRAD, P ABX or Multiplexer over its serial interface at 2.048 Mbps.3.0 CONFIGURATIONThe Model 2707 features configuration capability via hardware DIP switches. This section describes all possible DIP switch configurations of the Model 2707.3.1DIP SWITCH CONFIGURATIONThe Model 2707 has one internal DIP switch that allow configuration for a wide range of applications. The switch is accessed from the underside of the 2707. Figure 1 shows the location of the DIP switch on the bottom of the printed circuit board.Figure 1. Underside of Model 2707, Showing Location of DIP SwitchesThe Model 2707 DIP switch can be configured as either “ON” or “OFF”. Figure 2 shows the orientation of the DIP switch with respect to ON/OFF positions.Figure 2. Close up of configuration switchesSwitch SW1-1 through SW1-8Switch SW1-1 Line Coding: HDB3 (default)Use Switch SW1-1 to control the Network Line Coding options. Set these options to be the same as the Line Coding given to you by your Service Provider. If you are using two Model 2707s together as short range modems, set both units to HDB3.Table 1: Switch Set 1 SummaryPositionFunction Factory Default Selected Option SW1-1Line Code OFF HDB3SW1-2LLB OFF OFF SW1-3Reserved SW1-4Reserved SW1-5Reserved SW1-6Clock Mode OFF Received Recovered SW1-7Clock Mode OFF Received Recovered SW1-8TM from DTE OFF EnabledSW1-1Line Encoding OffHDB3On AMIOptions: HDB3, AMIHDB3: In this line coding, the transmitter substitutes a deliberate bipolar violation when excessive zeros in the data stream are detected. The receiver recognizes these special violations and decodes them as zeros. This method enables the network to meet minimum pulse density requirements. Unless AMI is required in your application, HDB3 should be used whenever possible.AMI: Alternate Mark Inversion defines a pulse as a “mark,” a binary one, as opposed to a zero. In an E1 network connection, signals are transmitted as a sequence of ones and zeros. Ones are sent as pulses, and zeros are sent as spaces, i.e., no pulse. Every other pulse is inverted from the previous pulse in polarity, so that the signal can be effectively transmitted. This means, however, that a long sequence of zeros in the data stream will cause problems, since the NTU receiving the signal relies on the signal to recover the 2.048 Mbps clock.If you must use AMI, you should ensure that the data terminal equipment connected to the unit provides a minimally acceptable pulse density. For this reason, there are advantages to using HDB3 instead. AMI coding does not inherently account for ones density. To meet this requirement, the user should ensure that the data inherently meets pulse density requirements.SW1-2 Local Loop: Inactive (default)Use SW1-2 to activate/deactivate local loopback test.Table 2: SW1-2 Local Loop SettingSW1-2SettingOff Local Loopback InactiveOn Local Loopback ActiveSW1-6 and SW1-7 Clock ModesUse Switches SW1-6 and SW1-7 to configure the 2707 for internal, external, or receive recover clock mode.Table 3: SW1-6 and SW1-7 Clock ModesSW1-6SW1-7Clock ModeON ON Network (Received Recovered)ON OFF InternalOFF ON ExternalOFF OFF Network (Received Recovered) Network Clock Transmitter timing is derived usingthe received line signal (receivedrecovered) from the network.Internal Clock Transmitter timing is derived froman internal clock source.External Clock Transmitter timing is derived fromDTE terminal timing.SW1-8: Enable/Disable Loop Tests from DTEUse Switch SW1-8 to allow Model 2707 to enter loopback tests when the DTE raises the appropriate loop request pin.SW1-8SettingOff Response to DTE Loopback Request EnabledOn Response to DTE Loopback Request Disabled4.0 INSTALLATIONOnce the Model 2707 is properly configured, it is ready to connect to the G.703 interface, to the serial port, and to the power source. This section describes how to make these connections.4.1CONNECTING TO THE G.703 NETWORKThe Power, G.703 and serial Line connections are located on the rear panel of the Model 2707. The following sections describe operation of these connections.Connecting the 2707/D (X.21 version) Dual Coaxial Cable (75 Ohm) to the G.703 NetworkThe Model 2707/D (X.21 version) is equipped with dual female BNCs (TX and RX) for connection to a 75 Ohm dual coax G.703 network inter-face. If your G.703 network terminates via dual coaxial cable, use the diagram below to make the proper connections. (SeeFigure 3).Figure 3. Rear Panel, Showing Location of ConnectorsNote The outer conductor of the coax cables are isolated from system earth ground.When using the 75 Ohm interface, jumper straps JP2, JP6, JP7, and JP5 must be installed over the jumpers. The jumpers are located next to the BNC connectors. Refer to the following section to open the case. Open the case and install jumper straps for JP2, JP6, JP7, and JP5. Opening the CaseOpen the case by inserting a screwdriver into the slots and twist the screwdriver head slightly. The top half of the case will separate from the lower half of the case. Take caution not to damage any of the PC board mounted components.Connecting the Twisted Pair (120 Ohm) to the G.703 NetworkThe Model 2707 is equipped with a single RJ-48C jack for connections to a 120 Ohm twisted pair G.703 network interface. If your G.703 network terminates via RJ-48C, use Figure 4 below to connect the 120 Ohm G.703 network channel.Figure 4. G.703 120 Ohm Connection4.2CONNECTING THE SERIAL PORTThe Model 2707/C and D supports V.35, X.21 serial port connections. This section describes how to connect the serial ports to your terminal equipment.Connecting to a “DTE” DeviceThe serial port on the 2707/C (V.35 version) is hard-wired as a DCE. Therefore these modules “want” to plug into a DTE such as a terminal, PC or host. When making the connection to your DTE device, use a straight through cable of the shortest possible length—we recommend 6 feet or less. When purchasing or constructing an interface cable, please refer to the pin diagrams in Appendix C as a guide.Connecting to a “DCE” DeviceIf the Model 2707 serial interface is hard-wired as a DCE (all except the X.21 version), you must use a null modem cable when connecting to a modem, multiplexer or other DCE device. This cable should be of the shortest possible length—we recommend 6 feet or less.Configuring the X.21 Interface (2707/D)The serial port on the X.21 interface is default wired as a DCE, but may be switched to a DTE. This is done by reversing the orientation of the DCE/DTE strap, as described below:T o reverse DCE/DTE orientation, remove the top case. Refer to “Open-ing the Case” on page 9.The DCE/DTE strap is located near the DB15 connector on the top side of the board. The arrows on the top of the strap indicate the configura-tion of the X.21 port (for example, if the DCE arrows are pointing toward the DB-15 connector, the X.21 port is wired as a DCE). Reverse the DCE/DTE orientation by pulling the strap out of its socket, rotating it 180º, then plugging the strap back into the socket. Y ou will see that the DCE/DTE arrows now point in the opposite directions, showing the new configuration of the X.21 port.Note If the 2707/D is configured as a DTE, the clocking mode must be set for external clock.4.3POWER CONNECTIONUniversal AC Power (100-240VAC)The Model 2707 uses a 5VDC, 2A universal input 100-240VAC, power supply (center pin is +5V). The universal input power supply has a male IEC-320 power entry connector. This power supply connects to the Model 2707 by means of a barrel jack on the rear panel. Many interna-tional power cords are available for the universal power supply.The Model 2707 powers up as soon as it is plugged into an AC outlet--there is no power switch.DC PowerThe 36-60 VDC DC to DC adapter is supplied with the DC version of the Model 2707. The black and red leads plug into a DC source (nominal 48VDC) and the barrel power connector plugs into the barrel power sup-ply jack on the 2707. (See Figure 5).Figure 5. Connecting DC Power to the 2707 DC Power SupplyWARNING There are no user-serviceable parts in the power supply section of the Model 2707. Contact Patton Electronics Technical support at +1 (301) 975-1007, via our web site at , or by **************************,formoreinfor-mation.5.0 OPERATIONWhen the Model 2707 has been properly configured and installed, it should operate transparently. This sections describes power-up, LED status monitors, and the built-in loopback test modes.5.1POWER-UPBefore applying power to the Model 2707, please read section 4.3, “Power Connection” on page 11 and ensure that the unit is properly connected to the appropriate power source.5.2LED STATUS MONITORSThe Model 2707 features six front panel LEDs that monitor connections on the G.703 and signaling, error and test modes. Figure 6 shows the front panel location of each LED. Descriptions of each LED follow Figure 6.Figure 6. 2707 Front PanelE1 Link(Active Green) Solid green (On) indicates thatthe end to end E1 Link is up, signifying that thelink is active. The E1 Link LED is Off when thelink is down.TD & RD Glows yellow to indicate an idle condition ofBinary “1” data on the respective terminal inter-face signals. Green indicates Binary “0” data.TM(Active Y ellow) Solid Y ellow indicates anActive Test Mode. The unit may be placedin test mode by the local user.5.3LOCAL LOOP DIAGNOSTICSThe Model 2707 offers V.54 loop diagnostics. Use these diagnostics to test the NTU and any communication links. This test can be activated via DIP switches or via signals on the Model 2707 serial port interface. Operating Local Loopback (LL)The Local Loopback (LL) test checks the operation of the local Model 2707, and is performed separately on each unit. Any data sent to the local Model 2707 in this test mode will be echoed (returned) to the user device (i.e., characters typed on the keyboard of a terminal will appear on the terminal screen).Figure 7. Local Loopback for a Network Termination ApplicationT o perform a LL test, follow these steps:1.Activate LL. This may be done in one of two ways:–Place the DIP switch SW1-2 to the “ON” position.–Activate the “LL” signal on the DTE (2707/C only). If you are notsure which lead is the “LL” signal, please refer to Appendix C.2.Verify that the data terminal equipment is operating properly and canbe used for a test.APPENDIX AMODEL 2707, G.703 SPECIFICATIONSNetwork Data Rate: 2.048 MbpsNetwork Connector:RJ-48C/Dual Coax BNC (2707/D)Nominal Impedance:75/120 OhmLine Coding:Selectable AMI or HDB3Line Framing:G.703 (Unframed)Clocking:Internal or Network (Receive Recover) Distance:Maximum 1.8 km (6,000 ft.) on 24 AWGCableConfiguration:One 8-Position DIP SwitchesPower Supply:+5VDC External power supply/100-240VAC,50-60Hz, 0.4A; or 48VDC Power Supply Humidity:Up to 90% non-condensingTemperature:0 to 50˚ CDimensions: 9.0 x 5.3 x 2.0 cm (3.5”L x 2.1”W x 0.78”H)APPENDIX BMODEL 2707, INTERFACE PIN ASSIGNMENTV.35 Interface(M/34F Female Connector)(DCE Configuration)Pin #SignalB SGND (Signal Ground)C RTS (Request to Send)D CTS (Clear to Send)E DSR (Data Set Ready)F CD (Carrier Detect)H DTR (Data Terminal Ready)L LLB (Local Line Loop)M TM (Test Mode)N RDL (Remote Digital Loop)P TD (Transmit Data)R RD (Receive Data)S TD/ (Transmit Data-B)T RD/ (Receive Data-B)U XTC (External Transmit Clock)V RC (Receive Timing)W XTC/ (External Transmit Clock)X RC/ (Receive Timing)Y TC (Transmit Clock-A)AA TC/ (Transmit Clock-B)APPENDIX B - ContinuedV.35 TO V.35 (STRAIGHT-THROUGH CABLE) PINOUT V.35 TO V.35 (CROSS OVER CABLE) PIN OUTPIN Function PIN Function PINA Frame Ground A Frame Ground AB Signal Ground B Signal Ground BC RTS C DCD FD NC D NC DE DSR E DTR HF DCD F RTS C H DTR H DSR E K NC K NC K L NC L NC L P TD (A)P RD (A)R R RD (A)R TD (A)P S TD (B)S RD (B)T T RD (B)T TD (B)S U SCTE (A)U RT (A)V V RT (A)V SCTE (A)U W SCTE (B)W RT (B)X X RT (B)X SCTE (B)W Y NC Y NC Y AA NC AA NC AAX.21 Interface(DB-15 Female Connector)(DTE/DCE Configuration)Pin #Signal1Frame Ground2T (T ransmit Data-A)3 C (Control-A)4R (Receive Data-A)5I (Indication-A)6S (Signal Element Timing-A)7BT (Byte Timing-A)8SGND (Signal Ground)9T/ (Transmit Data-B)10C/ (Control-B)11R/ (Receive Data-B)12I/ (Indication-B)13S/ (Signal Element Timing-B)14BT/ (Byte Timing-B)AND ACCESSORIESModel #Description 2707/C G.703 NTU with a V.35 interface 2707/D G.703 NTU with an X.21 interface2707/I G.703 NTU w/ 10Base-T EN interface 0805US American Power Cord0805EUR European Power Cord CEE 70805UK United Kingdom Power Cord0805AUS Australia/New Zealand Power Cord 0805DEN Denmark Power Cord0805FR France/Belgium Power Cord0805IN India Power Cord0805IS Israel Power Cord0805JAP Japan Power Cord0805SW Switzerland Power Cord08055DCUI Universal Input Power Supply07M2707User ManualCopyright © 2006Patton Electronics CompanyAll Rights Reserved.。

—1—E90603F01Sony reserves the right to change products and specifications without prior notice. This information does not convey any license byany implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits.Absolute Maximum Ratings (Ta=25 °C)•Supply voltage AV DD , DV DD 7V •Input voltage (All pins)V IN V DD +0.5 to V SS –0.5V•Output current (Every each channel)I OUT 0 to 15mA •Storage temperature Tstg–55 to +150°CRecommended Operating Conditions•Supply voltage AV DD , AV SS 4.75 to 5.25VDV DD , DV SS 4.75 to 5.25V•Reference input voltageV REF 2.0V•Clock pulse widthT PW1, T PW011.2 ns (min.) to 1.1 µs (max.)•Operating temperatureTopr –40 to +85°CDescriptionThe CXD1178Q is an 8-bit high-speed D/A converter for video band use. It has an input/output equivalent to 3 channels of R, G and B. It is suitable for use of digital TV, graphic display, and others.Features•Resolution 8-bit•Maximum conversion speed 40MSPS •RGB 3-channel input/output•Differential linearity error ±0.3LSB •Low power consumption 240 mW (200 Ωload at 2 Vp-p output)•Single 5 V power supply •Low glitch noise •Stand-by function StructureSilicon gate CMOS IC8-bit 40MSPS RGB 3-channel D/A Converter48 pin QFP (Plastic)CXD1178Q—2—Block Diagram(LSB) R0(MSB) R7(LSB) G0(MSB) G7(LSB) B0B1B2B3B4B5B6(MSB) B7BLK CE R1R2R3R4R5R6G1G2G3G4G5G6DV DD DV DDRO RO RCKAV DD AV DD AV DD AV DD GOGOGCKAV SS DV SS DV SSBOBOBCKVG VREFIREFVBPin ConfigurationR 0R 1R 2R 3R 4R 5R 6R 7G 0G 1G 2G 3B7B6B5B4B3B2B1B0G7G6G5G4B C KR OI R E F V R E FA V S SV BD V S SD V S SG C KR C KC E B L K RO GO GO BO BO VG AV DD AV DD AV DD AV DD DV DD DV DDPin Description and I/O Pins Equivalent Circuit—5—(f CLK=40 MHz, AV DD=DV DD=5 V, R OUT=200 Ω, V REF=2.0 V, Ta=25 °C)Item ResolutionConversion speedIntegral non-linearity error Differential non-linearity error Output full-scale voltage Output full-scale ratio ∗1 Output full-scale current Output offset voltageGlitch energyCrosstalkSupply currentAnalog input resistance Input capacitanceDigital input voltageDigital input currentSetup timeHold timePropagation delay timeCE enable time ∗2CE disable time ∗2Symbolnf CLKE LE DV FSF SRI FSV OSGECTI DDI STBR INC IV IHV ILI IHI ILt st ht PDt Et DMeasurement conditionsAV DD=DV DD=4.75 to 5.25 VTa=–40 to 85 °CEndpointWhen “00000000” data inputR OUT=75 ΩWhen 1 MHz sine wave input14.3MHz color bar CE= “L”data input CE= “H”VREFAV DD=DV DD=4.75 to 5.25 VTa=–20 to 75 °CAV DD=DV DD=4.75 to 5.25 VTa=–20 to 75 °CR OUT=75 ΩR OUT=75 ΩCE= H→LCE= L→HMin.0.5–2.5–0.31.812.4–5510Typ.82.01.5103057421101.81.8Max.402.50.32.23.015148290.8544UnitbitMSPSLSBLSBV%mAmVpV•sdBmAMΩpFVµAnsnsnsmsms Full-scale voltage of channel∗1Full-scale output ratio =Average of the full-scale voltage of the channels–1×100 (%)∗2When the external capacitor for the VG pin is 0.1 µF.—6—Electrical Characteristics Measurement Circuit}Analog Input ResistanceMeasurement CircuitDigital Input Current+5.25V ArrayMaximum Conversion Velocity Measurement CircuitCLK40MHzSQUAREWAVE—7——8—Crosstalk Measurement CircuitSetup Time Hold Time Measurement CircuitGlitch EnergyCLK 1MHz SQUARE WAVE}DC Characteristics Measurement CircuitPropagation Delay Time Measurement CircuitCLK10MHzSQUAREWAVE—9——10—Description of Operation Timing ChartI/O Chart (when full scale output voltage at 2.00 V)Application CircuitCLKDATAD/A OUT100%50%0%B (Blue) INInput code MSB LSB 1 1 1 1 1 1 1 1:1 0 0 0 0 0 0 0:0 0 0 0 0 0 0 0Output voltage2.0 V 1.0 V 0 VApplication circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same.Notes on Operation•How to select the output resistanceThe CXD1178Q is a D/A converter of the current output type. To obtain the output voltage connect the resistance to current output pins (RO, GO and BO). For specifications we have;Output full scale voltage V FS=1.8 to 2.2 [V]Output full scale current I FS=less than 15 [mA]Calculate the output resistance value from the relation of V FS=I FS×R OUT. Also, 16 times resistance of the output resistance is connected to reference current pin IREF. In some cases, however, this turns out to be a value that does not actually exist. In such a case a value close to it can be used as a substitute.Here please note that V FS becomesV FS=V REF×16R OUT/R IR.V REF is the voltage set at the VREF pin and R OUT is the resistance connected to current output pins (RO, GO and BO) while R IR is connected to IREF.Increasing the resistance value can curb power consumption. On the other hand glitch energy and data settling time will inversely increase. Set the most suitable value according to the desired application.•Phase relation between data and clockTo obtain the expected performance as a D/A converter, it is necessary to set properly the phase relation between data and clock applied from the exterior. Be sure to satisfy the provisions of the setup time (t S) and hold time (t H) as stipulated in the Electrical Characteristics.•Power supply and groundTo reduce noise effects separate analog and digital systems in the device periphery. For power supply pins, both digital and analog, bypass respective grounds by using a ceramic capacitor of about 0.1 µF, as close as possible to the pin.•Latch upAnalog and digital power supply have to be common at the PCB power supply source. This is to prevent latch up due to voltage difference between AV DD and DV DD pins when power supply is turned ON.•On inverted current output pinsThe RO, GO and BO are the inverted current output terminal as described in the Pin Description.The sums shown below become the constant value for any input data.a) The sum of the currents output from the RO and RO pins.b) The sum of the currents output from the GO and GO pins.c) The sum of the currents output from the BO and BO pins.However, the output current from the RO, GO and BO pins is not guaranteed of its performances such as linearity errors, etc.•On output full-scale voltageWhen the output full-scale voltage is used without adjustment in the application that uses the RGB signal, the color balance may be broke.—11——12—Latch Up PreventionThe CXD1178Q is a CMOS IC which required latch up precautions. Latch up is mainly generated by the lag in the voltage rising time of AV DD (Pins 43 to 46) and DV DD (Pins 47 and 48), when power supply is ON.1.Correct usagea.When analog and digital supplies are from different sourcesb.When analog and digital supplies are from a common source(i)(ii)+5V+5V+5V—13—2.Example when latch up easily occursa.When analog and digital supplies are from different sourcesb.When analog and digital supplies are from common source(i)(ii)+5V+5V+5V—14—CXD1178QExample of Representative CharacteristicsOutput full scale voltage vs. Reference voltageReference voltage V REF [V]O u t p u t f u l l s c a l e v o l t a g e V F S [V ]100Glitch energy vs. Output resistanceOutput resistance R OUT [Ω]200C r o s s t a l k C T [d B ]Crosstalk vs. Output frequencyOutput frequency F OUT [Hz]2.01.01.02.0200100AV DD =DV DD =5V V REF =2.0V R IR ≈16R OUTTa=25°C605040100k1M10MAV DD =DV DD =5V R OUT =200ΩR IR =3.3k ΩTa=25°C–250255075–4085O u t p u t f u l l s c a l e V F S [V ]Output full scale voltage vs. Ambient temperatureAmbient temperature Ta [°C]G l i t c h e n e r g y G E [p V •s ]SONY CODE EIAJ CODEJEDEC CODEPACKAGE STRUCTUREPACKAGE MATERIALLEAD TREATMENT LEAD MATERIAL PACKAGE MASSEPOXY RESINSOLDER / PALLADIUM PLATING 42/COPPER ALLOY 48PIN QFP (PLASTIC)+ 0.1QFP-48P-L04QFP048-P-12120.7gPackage Outline Unit : mmCXD1178Q—15—。

CX3000Cond/Resistivity/Salinity Transmitter/ControllerThank you for choosing the CX3000 Cond/Resistivity/TDS transmitter. This transmitter is a user-friendly microprocessor based transmitter for conductivity, resistivity and TDS measurement. As with all electronic instruments, it is essential to follow all directions for optimal performance. In particular, you must properly install, use and maintain the CX3000 to ensure that it will continue to operate within its specifications.• Follow all warnings, cautions and instructions supplied with the transmitter. Please contact Sensorex with any prod -uct questions or concerns.• Install the transmitter as specified in this manual, following all applicable local and national codes.• Do not attempt to repair your CX3000 transmitter or use any replacement parts from any other supplier.• If you find any errors in this manual, please report them to Sensorex.• Please complete the WARRANTY REGISTRATION located at the back of this manual and fax to SensorexCX3000 Cond/Resistivity/TDS Transmitter ESSENTIAL INSTRUCTIONSREAD THIS BEFORE USING YOUR CX3000 TRANSMITTER!About This DocumentThis manual contains instructions for the installation, operation and care of the CX3000 Cond/Resistivity/TDS transmitter. The following list provides notes concerning revisions of this document.Rev LevelDateNotesA10/20121st revision of manual.Table of Contents1. Specifications 12. Precautions for installation 33. Assembly and installation4installationTransmitter3.14. Overview of CX3000 Conductivity/Resistvity/Salinity transmitterpanelrear64.1ofIllustration4.2 General 74.3 Power 7function9terminalIllustration4.3of5. Configurationpanel 10frontIllustration5.1of10Description5.2FunctionKey5.3 LED indicators 12SecurityandDefault 13-14Codeicons5.4Display6. Operationmode 15 Measurement6.1mode 15 Set-up6.215mode6.3CalibrationReset 15 6.415reset6.4.1Masterreset 15 Calibration6.4.27. Settings7.1 Entry into set-up mode 167.2 Security code settings 167.3 Measurement Units 177.4 Temperature Settings 187.5 Temperature Compensation settings 197.6 Stand by Mode 207.7 Hi Alarm Relay (REL 1) 217.8 Lo point Alarm Relay (REL 2) 227.9 Wash time Relay 237.10 Analog output 1 (Cond/Res/Sal) 247.11 Analog output 2 (temperature) 257.12 Signal averaging of measurements 267.13 Power Supply Frequency Menu 277.14 Backlit LCD Menu 288. Calibration8.1 Calibration Flow Charts 298.1.1 Conductivity Calibration Flow Chart 298.1.2 Salinity Calibration Flow Chart 308.1.3 Resistivity Calibration Flow Chart 31Table of Contents8.2 Entry of calibration mode 328.2.1 Setting the CELL CONSTANT 328.2.2 Calibration using pre-set standards 339. Troubleshooting (Error Messages)9.1 Measurement Error Messages 349.2 Calibration Error Messages 34P roductRerturns Warranty10.and10.1 Warranty 3535 Items10.2ReturnofFigure 1-1Dimensional2SpecificationsFigure 3-1PanelMounting 4 Figure 3-2Pipe and Wall Mounting 5Figure 4-1 Rear6PanelFigure 4-2Power Schematic 7 Figure 4-3ESD Shield Removal 8Figure 5-1Front Panel View 10 Figure 5-2Display Icons 13 Figure 7-1Security Code Menu 16 Figure 7-2Measurement Unit Menu 17 Figure 7-3Temperature Measurement Menu 18 Figure 7-4Temperature Compensation Menu 19 Figure 7-5Standby Menu 20 Figure 7-6HI (Rel 1) Menu 21 Figure 7-7LO (Rel 2) Menu 22 Figure 7-8Wash Alarm Menu 23 Figure 7-9AnalogMenu 24Output1Figure 7-10Analog Output 2 Menu 25 Figure 7-11 Signal Averaging Menu 26 Figure 7-12 Power Supply Frequency Settings 27 Figure 7-13LCD Backlight Menu 28 Figure 8-1Conductivity Calibration Flow Chart 29 Figure 8-2Salinity Calibration Flow Chart 30 Figure 8-3Resistivity Calibration Flow Chart 31 Figure 8-4Setting Cell Constant 32 Figure 8-5Calibration using solution standards 33CX3000 SpecificationsMeasuring modes: Resistivity/Conductivity/Salinity/Temp.Ranges: Resistivity 0.00 -20.00MΩ/cmConductivity 0.000μS/cm-200.0 mS/cm in 6 ranges / Autoppt-70.0Salinity0.0-30.0to130.0°CTemp.Resolution: Resistivity 0.01 MΩ/cmμS/cmConductivity0.001pptSalinity0.10.1°CTemp.Accuracy: Resistivity ±1% (±1Digit)±1%(±1Digit)Conductivity(±1Digit)±1%Salinity(±1Digit)±0.2°CTemp.Measuring Unit 0.01, 0.1, 1.0, 10.00 cm-1 fixed, freely selectable 0.0050~19.99cm-1Temp Comp NTC30KΩ or PT1000 auto recognized or Manual adjustmentTemp Coeff Linear compensation from 0.00~20.00% Non-Linear compensation for natural water Ambient Temp. 0~50°CStorage Temp. -20~70°CDisplay: LCD display with illumination functionAnalog output 1: Isolated DC 0/4~20mA corresponding to main measurement, max. load 500ΩAnalog output 2 Isolated DC 0/4~20mA corresponding to Temp., max.load 500ΩSettings 1(HI) - Contact 240 V AC, 30V DC, 5.0A Max - programmable ON/OFF (SPST)2(LO) - Contact 240 V AC, 30V DC, 5.0A Max - programmable ON/OFF (SPST)WASH - Contact 240 V AC, 30V DC, 5.0A Max - programmable ON (0-9999 sec), OFF (0-999.9 hrs) Power Supply 100V~240VAC±10% 50/60Hz (software selectable)Mounting Installation Panel, or wallBox Dimensions: 144 mm × 144 mm × 115 mm (H×W×D)Panel Cut Out Dims: 138 mm × 138 mm (H×W)Weight :0.8 kgCertifications: IP 65 (NEMX 4X), CEpH / ORP Transmitter TX-3000(144mm)5.67”(144mm)5.67”(125mm)4.92”(98mm)3.74”Cord grip x3Panel mount ttings x4Front ViewSide ViewCX3000 Specifications - Dimensional SpecsWrong wiring will lead to breakdown or electrical shock of the instrument, please read this operation manual clearly before installation.Make sure to remove AC power from the controller before wiring input, output connections, and remove it before opening the transmitter housing.Install the transmitter in a well ventilated area and avoid direct sunlight.The material of signal cable should be special coaxial cable. Sensorex strongly recommend using our co-axial cable. Do not use normal wires instead.Avoid electrical surge when using power, especially when using three-phase power. Use ground wire cor-rectly.The internal realy contacts of the controller are designed for alarm and control function. Due to the safety and concern, please be sure to connect current with sufficient relay to load power, in order to ensure the operation safety of the instruments. (Please see chapter 4.3-Electrical connection diagram)3.1 Transmitter installation: This transmitter can be installed by panel mounting, wall mounting and pipe mounting.Panel Mounting : Cut a square hole of 5.4"(138mm) x 5.4"(138mm) on the panel, and then insert the trans -mitter directly into the panel. Attach the mounting bracket from the rear, so that it attaches to groove.Panel Cutout5.4"(138mm)5.4"(138m m )minimum distance between TX3000 panel cutouts = 1.7"(42mm)FIG 3-1Wall Mounting:Use 4 each M5 screws to attached to mounting holes shown below.Wall MountingFIG 3-24.1 Rear Panel:Figure 4.14.2 GeneralThe CX30000 requires 100-240V AC power (50/60 Hz selectable).Important Notes:1. Use wiring practices that conform to all national, state, and local electrical codes.2. DO NOT run sensor cables or instrument 4-20 mA output wiring in the same conduit that contains AC power wiring. AC power wiring should be run in a dedicated conduit to prevent electrical noise from coupling with the instrumentation signals.4.3 PowerFigure 4.24.3 Power (cont.)Power: Connect AC power to terminals 1 & 2. Power cord not included.Relays: Connect relays as shown. Relay 2 connects to terminals 5 & 6. Relay 1 connects to terminals 7 & 8. 240V AC, 30V DC, max 5.0A. Total current load should not exceed 5 amps at 240 VAC, 30V DC. Consider maximum in-rush current for devices connected to the CX3000 controller. If the current load can exceed 5 amps, please use and appropriate use a slave relay.4-20mA Outputs: Connect 10 & 11 to 4-20mA input (10 = -, 11 = +). This is the conductivity or resistivity or Salinity output. Connect 12 & 13 to 4-20mA input (12 = -, 13 = +). This is the temperature output. Sensor Connections:Remove ESD shield and install wires. Replace ESD shield after wires are connected .2 contact sensor - connect sensor wires to terminal 17 & 18. Place a jumper wire from 17 to 16 andfrom 18 to 19. Connect shield wire to terminal 20.4 contact sensor - connect sensor wires to terminal 16-19. Connect shield wire to terminal 20.Temperature sensor - connect temperature sensor wires to terminals 15 & 16.4-4 Description of terminal function:2-CONTACT Sensor WiringSHIELD (20) - Connected to the shield wire of the cable CELL 1 (19) - Jumper to #18CELL 2 (18) - Red wire of Sensorex cable (Cond)CELL 3 (17) - Black wire of Sensorex cable (Cond)CELL 4 (16) - Jumper to #17 + White wire Sensorex (TC)T/P - Green wire of Sensorex cable (TC)(11) 4~20mA(+)terminal : Master measurement current output terminal +, for external recorder or PLC control(12) 4~20mA(-)terminal : Master measurement current output terminal -, for external recorderor PLC control(13) 4~20mA(+)terminal: Temperature current output terminal +, for external recorder or PLC control (14) 4~20mA(-)terminal: Temperature current output terminal -, for external recorder or PLC control (7,8)REL 1 : External relay terminal High Point control(5,6)REL 2 : External relay terminal Low Point control External wash relay terminal (3,4)WASH : External wash relay terminal (1,2) 100~240AC: Power supply terminal4-CONTACT Sensor Wiring(20) - Connected to the shield wire of the cable(19) - CELL 1(18) - CELL 2(17) - CELL 3(16) - CELL 4 & TC (15) - TC5.1 Front PanelThe CX30000 keypad is designed for ease-of-use. See graphic below for keypad function.Figure 5-1In the parameter set-up mode, pressing this key allows you exit parameter set-up mode andback to Measurement mode.SetupIn the Calibration mode, pressing this key allows you exit Calibration mode and back to Mea -surement mode.5.2 Function Keys:In the parameter set-up mode and Calibration mode, pressing this key to increase the value or to scroll to other function.In the parameter set-up mode and Calibration mode, pressing this key to decrease the value or to scroll to other function.ModeKey for confirmation; pressing this key is essential when modifying data value or selecting the parameter setting items in the window.EnterIn the Measurement mode, pressing these two keys simultaneously allows you enter Calibration mode.ModeIn the Measurement mode, pressing these two keys simultaneously allows you to enter parameter set-up mode.ModeSetupIn the Measurement mode, press the "SETUP" and "MODE" keyssimultaneously for five seconds, and then press ENTER until you see a clock signal appearing on the display then stop pressing all keys to restore factory default settings.ModeSetup+EnterRestore factory default calibration’s settings. In the Measurement mode, press the "CAL " and "MODE" keys simultaneously for five seconds, and then press "ENTER" until you see a clock signal ap-pearing on the display; then stop pressing all keys to restore factory default settings.ModeEnter5.2 Function Keys:++5.3 LED indicators:HI: High set point indicator light; when the high set point is reached, the REL1 indicator will light. B.L.: Light sensor; in the automatic display backlit mode, the lamp will light or go out depending onenvironmental brightness.WASH: Washing device indicator light; when the washing device is started up, the indicator will light. LO: Low set point indicator light; when the low set point is reached, the REL2 indicator will light.5-4 Display Icons:Set-up mode:In the measurement mode, pressing the SETUP and MODE keys simultaneously allows you enter the parameter set-up mode. You can return to the measure -ment mode at any time by pressing the "SETUP" key .ModeSetupSecurity Code Settings:In the set-up mode, you can set up the code by following the steps below The original code is 1111. You can change the code to any 4-digit code you desire by following the same procedure as you used to enter the "1111" code.+6.1 Measurement mode:After all electrical connections are finished and tested, connect the transmitter to the power supply and turn it on. The transmitter will automatically enter measurement mode with the factory default settings or the last settings from user.6.2 Set-up mode:PRESS "SET UP" AND "MODE" SIMULTANEOUSLYPlease refer to the set-up instructions in Chapter 7, and press "SETUP" key to return to measurement mode.6.3 Calibration mode:PRESS "CAL" AND "MODE" SIMULTANEOUSLYPlease refer to the calibration instruction in Chapter 8, and press "CAL" key to return to measurement mode.6.4 Reset:6.4.1 Master reset:In the Measurement mode, press the "SETUP" and "MODE" keys simultaneously for five seconds, and then press the "ENTER" key until you see a clock signal appearing on the display. Release all keys and then factory default settings will be restored.Factory defaults:Measurement mode: Cond TemperatureTemperature compensation: NTCHigh point alarm: AUTO, SP1= 100.0 mSpH, db1= 0.10 mS/cmLow point alarm: AUTO, SP2 =00.10 uS/cm, db2= 00.10 uS/cmWash time: ON = 0 sec, OFF0.0 hrs, db = 0 secCond current output: 4~20 mA, 0.000uS/cm~199.9mS/cmTP current output: 4~20 mA, 000.0~100.0˚CBacklit Display: AUTO, b.L =0, SEnS=0Code set-up: OFF6.4.2 Calibration reset:In the Measurement mode, press the "CAL" and "MODE" keys simultaneously for five seconds, and then press the "ENTER" key until you see a clock signal appearing on the display. Release all keys and then factory default calibration settings will be restored.Factory defaults:Cell Constant: 1.0000Standard Solution: 1413uS/cmCalibration mode: Single-Point Calibration7.1 Set-up modeIn the measurement mode, pressing the "SETUP" and "MODE" keyssimultaneously allows you enter the parameter set-up mode. You can return to the measurement mode at any time by pressing the key "SETUP" key.SetupMode+7.2 SecurityIn the set-up mode, you can set up the code by pressing the key "MODE" , and confirm by pressing the "ENTER" key . The original code is 1111.EnterModeGO TO "MEASUREMENT7.3 Measurement Unit ModeIn the measurement unit mode, you can choose units for conductivity (Cond), resisitivity (RES) or salinity (SALT).EnterPress "ENTER" to enter measurement setup mode.ModePress "MODE" or "RIGHT ARROW" to select measurement mode.CONDUCTIVITY TDSRESISTIVITY SALINITYEnte r Ente r ** Press Mode button until desired range is on screen then press "ENTER".Auto range 2.000μS/cm 20.00μS/cm 200.0μS/cm 2000μS/cm 20.00mS/cm 200.0mS/cmEnte rEnte r Ente rEnte r** Press Mode button until desired range is on screen then press "ENTER".2000ppm 20.00ppt 200.0pptGO TO "TEMPERATURE SETUP ,SECTION 7.4Temperature(Celsius)Mode ORModeORModeTo enter correct temperature Compare with standard temp. meter7.4 Temperature measurement modeIn the Temperature measurement unit mode, you can choose the type of temperature sensor (NTC 30K) or PTC (1000 Ω RTD)7.5 Temperature Compensation ModeIn the temperature compensation mode, you can choose linear compensation range from 0.00% to 20.00% or non-linear for resistivity compensation.Non-Linear temp. compensationEnterModeTo choose temp comp methodPress confirm method To set temp compcoefficient.EnterGO TO "HI ALARM SETPOINT MODE"SECTION 7.67.5 Standby ModeIn the standby mode, you can choose Auto or ON for standby. Auto will set the return to MEASUREMENT mode to 3 minutes if no keys are touched. Choosing ON for standby requires you to press "SETUP" key to return to MEASUREMENT mode.EnterModeauto return or manually returnSETUPand return to theMEASUREMENTFIG 7-57.7 HI POINT SETTINGSet Hi (REL1) setpoint threshold(TH) and dead band value (DB). The range of threshold and deadband are: Resistivity:0.00MΩ~19.99MΩ Deadband:0.00MΩ~19.99MΩConductivity: 0.000μs~199.9mS Deadband: 00.00μs ~199.9 mS Salinity: 0.0ppt~70.0ppt Deadband: 0.0ppt~7.0pptEnterto enter the Hi point relay.Enterto exit Relay 17.8 LO POINT SETTINGSet Lo (REL2) setpoint threshold(TH) and dead band value (DB). The range of threshold and deadband are:Resistivity: 0.00MΩ~19.99MΩ Deadband: 0.00MΩ~2.00MΩConductivity: 0.000μs~199.9mS Deadband: 00.00μs ~199.9 mS Salinity: 0.0ppt~70.0ppt Deadband: 0.0ppt~7.0pptTo activate relay 2 or not.EnterModeand the units (μS/cm or mS/cm) also can be set.Enter7.9 WASH Alarm -Set the automatic starting time and turnoff time of the washing function. If any value is set to be 0, the transmitter will automatically stop this function.to activate the auto clean device to input clean device OFF duration.Modeto activate the auto clean device ModeOROROR7.10 Analog Output 1 (Conductivity/Resistivity/Salinity)This mode allows you to set the analog output as 4-20mA or 0-20mA for Conductivity/Resistivity/Salinity.ORto select current range (4-20mA or 0-20mA)Press "MODE" or "RIGHT ARROW"lower limit of Conductiv-ity value relative to the 4.0mA signal. If you set ModeGO TO ANALOG OUTPUT 2(TEMPERATURE)SECTION 7.11EnterEnterFIG 7-97.11 Analog Output 2 (Temperature)This mode allows you to set the analog output as 4-20mA or 0-20mA for temperature (deg C only).ORto select current range(4-20mA or 0-20mA)ORORModeof temperature value forthe 20mA signalORModeto select output testingEnterGO TO SIGNAL AVERAGING TIME7.12 Signal AveragingThis mode allows you to set the signal averaging time (0-60 seconds) to increase stability of displayed signal ArrayFIG 7-117.13 Power Supply Frequency ModeThis mode allows you to set the power supply frequency (U.S. 60HZ, Others 50Hz)ORModeEnterFIG 7-127.14 Backlit LCD ModeThis mode allows you to set the Backlit LCD to AUTO, On or OFF. In the AUTO mode it allows for setting of the LCD brightness and light sensor sensitivity.ORModeORGO TO SECURITY SETTINGSSECTION 7.28.1 Calibration Flow Charts8.11 Calibration Flow Chart for ConductivityEnter"ENTER"8.1 Calibration Flow Charts8.12 Calibration Flow Chart for Salinity1.08.1 Calibration Flow Charts8.13 Calibration Flow Chart for ResistivityIn the Measurement mode, pressing these two keys simultaneously allows you enter Calibration mode.Mode+8.2 Entry of Calibration Mode8.2.1 Setting the CELL CONSTANTIn the Measurement mode, pressing these two keys simultaneously allows you enter Calibration mode.Mode+or press "CAL " key to return to measuring mode at any time8.2.2 Standard Solution CalibrationMode OREnterThese symbols will flash"ENTER" for confirmation.9.1 Measurement ErrorsMessageReasonActionIn resistivity measuring mode when the value is over the measuring range, the following figure will be appear (Measuring range:00.00-19.99MΩ)Please check the sensor’s cable to see if it is broken. If it is ok, please check if the solution’s resisitivity is over range.In conductivity measuring mode whenthe value is over measuring range, the follow-ing figure will be appear:(Measuring range:00.00us-199.9msPlease check the sensor’s cable to see if it is shorted electrically. If it is OK, please check if the solution’s conductivity is over range.In salinity measuring mode when the value is over the measuring range, the follow figure will be appear:(Measuring range:0.0ppt~70.0ppt)Please check the sensor’s cable to see if it is broken. If it is OK, please check if the solu-tion’s salinity is over range.When temperature value is out of the display range, then the following figure will be ap-pear:(Measuring range:-30°C -130°C)Please check the sensor’s temp cable to see if it is broken. If it is still normal, please check if the solution’s temperature is over range.9.2 Calibration Errors10.1 WarrantyThe CX3000 Conductivity/Resistivity/Salinity transmitter/controller is supplied with a one-year warranty for material and workmanship from date marked on the product. No warranty, either expressed or implied, as to the useful life of the product is given. There are no implied warranties of merchantability or fitness for a particular purpose given in connection with the sale of any goods. In no event shall the seller be liable for consequential, incidental or special damages. The buyer’s sole and exclusive remedy and the limit of the seller’s liability for any loss whatsoever shall not exceed the purchase price paid by the purchaser for the product to which claim is made.10.2 Return of ItemsIf repair is necessary and is not the result of misuse, contact Sensorex for a Return Material Authorization Number (RMA#). No product returns will be accepted without prior authorization. You will be asked for the serial number of the transmitter/controller and a description of the failure. Customers are responsible for incoming freight charges on returned products. Sensorex will pay all outgoing freight charges on warranted returns. If, after evaluation, the product is deemed damaged due to misuse, you will be contacted regarding repair charges.Page 36 of 36Warranty Terms and Conditions********************************************************************************************* of purchase.2. The Warranty shall become void if any unauthorized repair, tampering or alteration is done on to the product.3. Do not remove or alter the serial number on the product. This will again void the warranty.4. The owner of the product must present a copy of this warranty card to request RGA service.5. The Warranty does not cover: a) Accessories, consumable items, wear and tear parts, corrosion, rusting or stains b) Incoming shipping cost when sending product in for repair c) Use of wrong electrical supply/voltage d) Dropping or other impact e) Use not in accordance with product manual 6. SENSOREX warrants all products to be free of defects in materials and workmanship for one year from date marked on the product or based on the serial number. However, SENSOREX offers no warranty, either expressed or implied, as to the useful life of these products. There are no implied warranties of merchantability of fitness for a particular purpose given in connection with the sale of any goods. In no event shall SENSOREX be liable for con sequential, incidental or special damages. All responsibilities for items not provided in this box (software, monitors, electrodes or power supplies) are not the responsibilty of Sensorex. The buyer’s sole and exclusive remedy and the limit of SENSOREX’s liability for any loss whatsoever shall not exceed the purchase price paid by 11751 Markon Drive Garden Grove, CA. 92841 USA tel: 714-895-4344 fax: A HALMA COM PA NY。

DescriptionThe Power-One Xscend™ Controller System (XCS) provides comprehensive monitoring and control for Power-One’s Xscend DC power systems. This digital controller monitors total system conditions including DC voltage, rectifier current, rectifier temperature,system capacity, battery parameters and circuit breaker status.The XCS enables data storage of system configuration information such as battery type,installation date and system commission date. Visual notification of alarm and warning conditions are indicated by front panel LEDs, while descriptions of the alarms are provided through an LCD, or as an option, may be accessed remotely through a modem or a Network Interface (PNI)module.To meet individual site requirements, the XCS contains a logic operator that can be programmed to monitor and control specified requirements. This allows actions to be set,alarms to be triggered, and outputs to be activated based on internal and external signal monitoring, comparing and processing.FeaturesUser controls and interfaces:•Simple menu-guided operation using frontpanel mounted pushbuttons and an LCD•User-selectable alarm parameters •40 event data logging•Password controlled environment •Multiple language options •RS232 Interface and Form “C” dryalarm contactsXCSControllerIntelligent battery management:•Temperature compensation withprogrammable compensation factor•Automatic and manual load testing •Battery voltage and symmetry monitoring •Capacity testing •Low voltage disconnect •Monthly data loggingBatteryOther Technical DataAlarmsInterface11V0005-061 XCS V3.0ControllerXCS。

2 OverviewTable 2: Digital input modules3 Order dataX20SLX210/ X20SLX410X20SLX811X20SLX910Short descriptionIntelligent programmable modulessafe digital input module, safety controller, openSAFETY,SafeMOTION axes, 2 safe digital inputs, configurable input filter, 2 pulse outputs, 24 VDCsafe digital input module, safety controller, openSAFETY,SafeMOTION axes, 4 safe digital inputs, configurable input filter, 4 pulse outputs, 24 VDCX20 safe digital input module, coated, safety controller, openSAFETY, 11 openSAFETY nodes,4 SafeMOTION axes, 4 safe digital inputs, configurable input filter, 4 pulse outputs, 24 VDCsafe digital input module, safety controller, openSAFETY,SafeMOTION axes, 8 safe digital inputs, configurable input filter, 4 pulse outputs, 24 VDC, sin-safe digital input module, safety controller, openSAFETY,SafeMOTION axes, 20 safe digital inputs, configurable input filter, 4 pulse outputs, 24 VDCX20 safe digital input module, coated, safety controller, openSAFETY, 11 openSAFETY nodes,4 SafeMOTION axes, 20 safe digital inputs, configurable input filter, 4 pulse outputs, 24 VDCRequired accessoriesBus modulesX20 bus module, for X20 SafeIO modules, internal I/O power supply continuous, single-widthX20 bus module, for X20 SafeIO modules, internal I/O power supply continuousX20 bus module, for X20 SafeIO modules, with node number switch, internal I/O power supplycontinuousX20 bus module, coated, for X20 SafeIO modules, internal I/O power supply continuousTerminal blocksX20 terminal block, 12-pin, safety-keyedTable 3: X20SLX210, X20SLX410, X20cSLX410, X20SLX811, X20SLX910, X20cSLX910 - Order data4 Technical dataTable 4: X20SLX210, X20SLX410, X20cSLX410, X20SLX811, X20SLX910, X20cSLX910 - Technical data1)It is also important to take note of the danger warnings in the technical data sheet.2)If multiple SafeLOGIC-X controllers exist in the AS hardware tree, all but 1 must be disabled.3)Keep in mind that 8 BOOL count as 1 data point.4)Protection is provided for max. 30 minutes for continuous short circuits.Danger!Operating outside of technical data specifications is not permitted and can result in dangerous situ-ations.Information:For additional information about installation, see chapter "Installation notes for X20 safety modules"on page 67.X20SLXx10 - DeratingThe number of inputs that should be used at the same time depends on the operating temperature and the mounting orientation. The resulting amount can be looked up in the following table.The derating curve refers to operation at 28.8 VDC. When operated at 24 VDC and mounted horizontally, the derating curve is shifted to the right by the derating bonus specified in the technical data.If a dummy module is installed on the left, right or left and right next to the module, then the derating curve is shifted to the right by the derating bonus specified in the technical data (with horizontal mounting).X20SLX410X20SLX811X20SLX910Table 5: Derating in relation to operating temperature and mounting orientationInformation:Regardless of the values specified in the derating curve, the module cannot be operated above thevalues specified in the technical data.5 LED status indicatorsX20SLX210X20SLX410X20SLX811X20SLX910Table 6: Status displayDanger!Constantly lit "SE" LEDs indicate a defective module that must be replaced immediately.It is your responsibility to ensure that all necessary repair measures are initiated after an error occurs since subsequent errors can result in dangerous situations!6 PinoutsSI 1SI 2r 12e 000CSEX 20 S L X 210Pulse 1Pulse 2Figure 1: X20SLX210 - Pinout SI 1SI 2r 12e 000C SEX 20 S L X 410Pulse 1Pulse 234000CSI 3SI 4Pulse 3Pulse 4Figure 2: X20SLX410 - PinoutSI 1SI 2r 13e 24SEX 20 S L X 811Pulse 1Pulse 25768SI 3SI 4Pulse 3Pulse 4SI 7SI 5SI 8SI 6Figure 3: X20SLX811 - Pinout r 13e 14SEX 20 S L X 91015161718SI 9SI 10SI 11SI 12SI 5SI 6SI 7SI 8SI 1SI 2SI 3SI 4Pulse 1Pulse 3SI 151920123456789101112SI 16SI 14SI 13SI 20SI 19SI 18SI 17Pulse 4Pulse 2Figure 4: X20SLX910 - Pinout。

P1為希科技Sparatn3XC3S200-PQ208ST3實驗板使用手冊2006.Jan.15 .V1.0使用手冊Introduction ……………………….page 3 Chapter 1 : Power ………………..page 5 Chapter 2 : InterfaceRS232 ………………..page 6 LED …………………..page 8 PUSH_BUTTOM …..page 9 DIP_SWITCH………..page 10 7_SEGMENT………...page 11 Chapter 3 : Clock ………………….page 13 Chapter 4 : User ConnectorJC1 ………………….page 14 JC2 ………………….page 16 JC3 ………………….page 18 JC4 ………………….page 20 Chapter 5 : Download …………….page 22 Chapter 6 : FPGA ………………….page 24Ulinx Corp .P2目錄為希科技有限公司的UBD-Spartan3-ST3實驗板提供FPGA使用者一個完整且容易上手的實驗平 台.這份實驗手冊將會含括這片實驗板上所有元件的設定及特性說明.主要元件及功能圖 1-1 是這片板子的照片,裡面包含了這些主要元件● 20萬邏輯閘的Xilinx Spartan-3 XC3S200 FPGA 包裝為PQFP208 隻腳位 (XC3S200-4-PQ208). 內含12個 18K-bit 的Block RAMs (共216K bits). 內含12個 18x18 硬體乘法器. 內含4 個 Digital Clock Managers (DCMs). 內含141 個可用腳位● RS-232 界面● PROM XCF01S-VO20● 4 個DIP switch 與4個LED界面● 4 個 7段顯示器● 單一電源輸入( +5V/ 3A ).提供板子上三組電源使用 ( 1.2V , 2.5V , 3.3V )● JTAG 界面. 提供多種燒錄程式的界面產品外觀P4電源插頭 : J4 , 5 V 輸入(中間為正電壓+5V)D11 : 板子上 有5V的電壓時 , 綠色 LED經由電壓轉換IC將電源轉為1.2V,1.5V,2.5V,3.3V 五組電壓供板子使用,並有LED 燈顯示.(1-A) 3.3V電壓 : 主要提供給FPGA IO 電壓 及USER IO 使用包含 : 區段顯示器,Push button , Switch ,LED燈 ,RS232 ;U4 : LM1117MPX_3. 3V ,包裝為 SOT-223 ,將5V電壓轉為 3.3VD9 : 板子上 有3.3V的電壓時 , 綠色LED為亮(1-B) 2.5V電壓 :主要提供給FPGA download 電路電壓 及Platform Flash XCF01S-V020使用. U3 : LM1117MPX_2.5 ,包裝為 SOT-223 ,將5V電壓轉為 2.5VD10 : 板子上 有2.5V的電壓時 , 綠色 LED為亮(1-C)1.5V電壓 : U12 : LM1117MPX_1.5 ,包裝為 SOT-223 ,將5V電壓轉為 1.5VD7 : 板子上 有1.5V的電壓時 , 綠色 LED為亮(1-D)1.2V電壓 :主要提供給 FPGA核心電壓U5: APL5912 ( 1.2V),包裝為 SOP-8-P,將1.5V電壓轉為 1.2V2-1. RS232介面RS232 Pin Connection1 NC2 Max3221, Pin13 , DOUT3 Max3221 , Pin8 , RIN4 NC5 GND6 NC7 NC8 NC9 NCMAX3221 Pin Connection1 (EN) GND2 (C1+) C1-3 (V+) GND4 (C1-) C1+5 (C2+) C2-6 (C2-) C2+7 (V-) GND8 (RIN) RS232 Pin39 (ROUT) FPGA P16 ( IO_109)10 (INVALID) NC11 (ON) FPGA P18 (IO_108)12 (FORCEON) GND13 (DOUT) RS232 Pin214 (GND) GND15 (VCC) 3.3V16 (FORCEFF) 3.3VU6(2-A) FPGA Jatg 下載的界面(J3 ) : DB25 公座 (稍後在討論)(2-B) RS232 界面 (J1) :DB9母座 , 經由MAXIM 的MAX3221CDB (U2) SSOP16 , 連接到 FPGA .813 11 9P4 P3Spartan 3 FPGA MAX32212-2. LED 介面LED 燈 : D1~D4為使用者LED 燈號 D1: 紅色LED 燈, D2 : 紅色LED 燈 D3 : 紅色LED 燈D4 : 紅色LED 燈D8燈 : D8為FPGA Download 成功顯示的燈號.D8D1 D2 D3 D4 Done pin LED1 LED2 LED3 LED4 P103P10P11P12P13Symbol FPGA PINPush Button switch : S5 : Program pin , S2: FPGA P203 ,BOT1 S3: FPGA P204 ,BOT2 S4: FPGA P205 ,BOT32-3. PUSH_BUTTON 介面S5 S2 S3 S4 Symbol PROGRAMBOT1 BOT2 BOT3 FPGA PINP207P203P204P205DIP_SWITCH : S1-1 : DP_SW1 S1-2 : DP_SW2 S1-3 : DP_SW3 S1-4 : DP_SW42-4. DIP_SWITCH 介面S1-1S1-2 S1-3 S1-4 Symbol DP-SW1DP-SW2DP_SW3DP_SW4FPGA PINP2P5P7P9SEG_1(P183)SEG_2(P184)SEG_3(P185)SEG_4(P186)HH H H1 1 0 1 1 0 1 0P189P190P194P196 P197P198P199P191HSeven Segment :SEG_4: DIGIT_4 SEG_3: DIGIT_3 SEG_2: DIGIT_2 SEG_1 : DIGIT_1SEG_A : 7_SEGEMNT_A SEG_B : 7_SEGMENT_B SEG_C : 7_SEGMENT_C SEG_D : 7_SEGMENT_D SEG_E : 7_SEGMENT_E SEG_F : 7_SEGMENT_F SEG_G : 7_SEGMENT_G SEG_H : 7_SEGMENT_HSEG x4 pin D1 D2D3 D4 A B C D E F G HSEG x4 Pin No Pin 12 Pin 9 Pin 8 Pin 6 Pin 11 Pin 7 Pin 4 Pin 2 Pin 1 Pin 10 Pin 5 Pin 3 FPGA pinP183P184P185P187P189P190P191P194P196P197P198P199SYMBOL SEG_1 SEG_2 SEG_3 SEG_4 SEG_A SEG_B SEG_C SEG_D SEG_E SEG_F SEG_G SEG_H Example : 如果需要顯示2這個數字2-5. 7_SEGMENT 介面2-5. 7_SEGMENT介面40 Mhz Oscillator (Y1)提供 FPGA 的clock 來源 , 接FPGA 的 P77 腳位.3-1.CLOCKP166 P162 P156 P154 P150 P148 P146 P1434-1. USER_CONNECTOR : JC1JC1SYMBOL FPGA_PIN JC1SYMBOL FPGA_PIN 1GND2+5V3GND4+3.3V5P182P1826P181P1817P180P1808P178P1789P176P17610P175P17511P172P17212P171P17113P169P16914P168P16815P167P16716P166P16617P165P16518P162P16219P161P16120P156P15621P155P15522P154P15423P152P15224P150P15025P149P14926P148P14827P147P14728P146P14629P144P14430P143P14331P141P14132P140P14033P139P13934P138P13835P137P13736P135P13537P133P13338P132P13239GND40+3.3V4-2. USER_CONNECTOR : JC2JC2提供使用者擴充功能的接頭之用,JC2為20X2的接頭,其相對位置如下圖所示,第一腳位於JC2的左下角,而JC2的定義如下表所示.4-2. USER_CONNECTOR : JC2JC2SYMBOL FPGA_PIN JC2SYMBOL FPGA_PIN 1GND2+5V3GND4+3.3V5P131P1316P130P1307P128P1288P126P1269P125P12510P124P12411P123P12312P122P12213P120P12014P119P11915P117P11716P116P11617P115P11518P114P11419P113P11320P111P11121P109P10922P108P10823P107P10724P106P10625P102P10226P101P10127P100P10028P97P9729P96P9630P95P9531P94P9432P93P9333P85P8534P80P8035P79P7936P78P7837+2.5V+2.5V38P76P7639GND40+3.3V4-3. USER_CONNECTOR : JC3JC3提供使用者擴充功能的接頭之用,JC3為20X2的接頭,其相對位置如下圖所示,第一腳位於JC3的左上角,而JC3的定義如下表所示.4-3. USER_CONNECTOR : JC3JC3SYMBOL FPGA_PIN JC3SYMBOL FPGA_PIN 1GND2+5V3GND4+3.3V5P92P926P90P907P87P878P86P869P83P8310P81P8111P74P7412P72P7213P71P7114P68P6815P67P6716P65P6517P64P6418P63P6319P62P6220P61P6121P58P5822P57P5723P52P5224P51P5125P50P5026P48P4827P46P4628P45P4529P44P4430P43P4331P42P4232P40P4033P39P3934P37P3735P36P3636P35P3537GND GND38+3.3V39+2.5V+2.5V40+2.5V4-4. USER_CONNECTOR : JC4JC4提供使用者擴充功能的接頭之用,JC4為10X2的接頭,其相對位置如下圖所示,第一腳位於JC4的左上角,而JC4的定義如下表所示.4-4. USER_CONNECTOR : JC4JC4SYMBOL FPGA_PIN JC4SYMBOL FPGA_PIN 1GND2+5V3GND4+3.3V5P34P346+2.5V7P33P338P31P319P29P2910P28P2811P27P2712P26P2613P24P2414P22P2215P21P2116P20P2017P19P1918P18P1819P16P1620P15P15本實驗板有7種download的方式 :Download 界面 DownloadModeM0/M1/M2(JP4) 設定ConfigdeviceJP1/JP2/JP3設定J 1JTAG101open : close:openProm , FPGA Close :close : closeJ 1JTAG101open : close:open FPGA JP1 close:TDI_PORT連接TDI_FPGAJ1JTAG101open : close:open Prom JP3 Close : TDO_PORT 連接TDO_PROMJ 9JTAG101open : close:openProm ,FPGA Close :close : closeJ 9JTAG101open : close:open FPGA JP1 close:TDI_PORT連接TDI_FPGAJ9JTAG101open : close:open Prom JP3 Close : TDO_PORT 連接TDO_PROMProm到FPGA Master Series 000close : close:close FPGA Close :close : close4-1. DOWNLOADDownload 電路 :J1U1XC3S200PQ208U7XCF02SVO206-1. XILINX FPGAFPGA(U1) : 20萬邏輯閘的Xilinx Spartan-3 XC3S200 FPGA 包裝為PQFP 208 隻腳位 (XC3S400PQ208)內含12個 18K-bit 的Block RAMs (共216K bits) , 12個 18x18 硬體乘法器 ,4 個 Digital Clock Managers (DCMs) ,141 個 可用腳位 .FPGA pin No FPGA pin Name Layout Name Device Device pin no Device Pin name1GND2DCI DP_SW1SW_DIP4S-1S1-1 3DCI RXD MAX322111ON 4VREF TXD MAX32219ROUT 5I/O DP_SW2SW_DIP4S1-2S1-2 6VCC7I/O DP_SW3SW_DIP4S1-3S1-3 8GND9I/O DP_SW4SW_DIP4S1-4S1-4 10I/O LED1 LED1LED1-2LED1-2 11I/O LED2LED2LED2-2LED2-2 12I/O LED3LED3LED3-4LED3-3 13I/O LED4LED4LED4-4LED4-4 14GND15I/O P15JC4JC4-20P15 16I/O P16JC4JC4-19P16 17VCCAUX18I/O P18JC4JC4-18P18 19I/O P19JC4JC4-17P19 20I/O P20JC4JC4-16P20 21I/O P21JC4JC4-15P21 22I/O P22JC4JC4-14P22 23VCC24VREF P24JC4JC4-13DQ15 25GND26I/O P26JC4JC4-12P26 27VREF P27JC4JC4-11P27 28VREF P28JC4JC4-10P28 29I/O P29JC4JC4-9P29 30GND31I/O P31JC4JC4-8P31 32VCC33I/O P33JC4JC4-7P33 34I/O P34JC4JC4-5P34 35VREF P35JC3JC3-36P35 36I/O P36JC3JC3-35P36 37I/O P37JC3JC3-34P37 38VCCAUX39I/O P39JC3JC4-33P39FPGA pin No FPGA pin Name Layout Name Device Device pin no Device Pin name40I/O P40JC3JC3-32P40 41GND42I/O P42JC3JC3-31P42 43I/O P43JC3JC3-30P43 44I/O P44JC3JC3-29P44 45I/O P45JC3JC3-28P45 46I/O P46JC3JC3-27P46 47GND48I/O P48JC3JC3-26P48 49VCC50VREF P50JC3JC3-25P50 51DCI P51JC3JC3-24P51 52DCI P52JC3JC3-23P52 53GND54M1P54JP1JP1-0M0 55M0P55JP1JP1-1M1 56M2P56JP1JP1-2M2 57DUAL P57JC3JC3-22P57 58DAUL P58JC3JC3-21P58 59GND60VCC61DCI P61JC3JC3-20P61 62DCI P62JC3JC3-19P62 63I/O P63JC3JC3-18P63 64I/O P64JC3JC3-17P64 65VREF P65JC3JC3-16P65 66GND67DUAL P67JC3JC3-15P67 68DUAL P68JC3JC3-14P68 69VCCAUX70VCCINT71I/O P71JC3JC3-13P71 72VREF P72JC3JC3-12P72 73VCC74DAUL P74JC3JC3-11P74 75GND76GCLK P76JC2JC2-38P76 77GCLK EGCLK Y1Y1-3EGCLK 78DAUL P78JC2JC2-26P78FPGA pin No FPGA pin Name Layout Name Device Device pin no Device Pin name79DUAL P79JC2JC2-35P79 80DUAL P80JC2JC2-34P80 81DUAL P82JC3JC3-10P81 82GND83DAUL P83JC3JC3-9P83 84VCC85DAUL P84JC2JC2-33P85 86DAUL P86JC3JC3-8P86 87GCLK P87JC3JC3-7P87 88VCCINT89VCCAUX90GCLK P90JC3JC3-6P90 91GND92VREF P90JC3JC3-5P92 93I/O P93JC2JC2-32P93 94I/O P94JC2JC2-31P94 95I/O P95JC2JC2-30P95 96VREF P96JC2JC2-29P96 97I/O P97JC2JC2-28P97 98VCC99GND100DCI P100JC2JC2-27P100 101DCI P101JC2JC2-26P101 102VREF P102JC2JC2-25P102 103DONE DONE104CCLK FPGA_CCLK U7CLK FPGA_CCLK 105GND106DCI P106JC2JC2-24P106 107DCI P107JC2JC2-23P107 108VREF P108JC2JC2-22P108 109I/O P109JC2JC2-21P109 110VCC111I/O P111JC2JC2-20P111 112GND113I/O P113JC2JC2-19P113 114I/O P114JC2JC2-18P114 115I/O P115JC2JC2-17P115 116I/O P116JC2JC2-16P116 117I/O P117JC2JC2-15P117FPGA pin No FPGA pin Name Layout Name Device Device pin no Device Pin name 118GND119I/O P119JC2JC2-14P119 120I/O P120JC2JC2-13P120 121VCCAUX122VREF P122JC2JC2-12P122 123I/O P123JC2JC2-11P123 124I/O P124JC2JC2-10P124 125I/O P125JC2JC2-9P125 126I/O P126JC2JC2-8P126 127VCC128I/O P128JC2JC2-7P128 129GND130I/O P130JC2JC2-6P130 131VREF P131JC2JC2-5P131 132VREF P132JC1JC1-38P132 133I/O P133JC1JC1-37P133 134GND135I/O P135JC1JC1-36P135 136VCC137I/O P137JC1JC1-35P137 138I/O P138JC1JC1-34P138 139I/O P139JC1JC1-33P139 140I/O P140JC1JC1-32P140 141VREF P141JC1JC1-31P141 142VCCAUX143I/O P143JC1JC1-30P143 144I/O P144JC1JC1-29P144 145GND146I/O P146JC1JC1-28P146 147I/O P147JC1JC1-27P147 148I/O P148JC1JC1-26P148 149I/O P149JC1JC1-25P149 150I/O P150JC1JC1-24P150 151GND152I/O P152JC1JC1-23P150 153VCC154VREF P154JC1JC1-22P154 155DCI P155JC1JC1-21P155 156DCI P156JC1JC1-20P156FPGA pin No FPGA pin Name Layout Name Device Device pin no Device Pin name 157GND158TDO TDO_FPGA159TCK TCK160TMS TMS161DCI P161JC1JC1-19P161 162DCI P162JC1JC1-18P162 163GND164VCC165I/O P165JC1JC1-17P165 166VREF P166JC1JC1-16P166 167I/O P167JC1JC1-15P167 168I/O P168JC1JC1-14P168 169I/O P169JC1JC1-13P169 170GND171I/O P171JC1JC1-12P171 172I/O P172JC1JC1-11P172 173VCCAUX174VCCINT175I/O P175JC1JC1-10P175 176I/O P176JC1JC1-9P176 177VCC178VREF P178JC1JC1-8P178 179GND180GCLK P180JC1JC1-7P180 181GCLK P181JC1JC1-6P181 182I/O P182JC1JC1-5P182 183GCLK SEG_1SEGX412SEG_1 184GCLK SEG_2SEGX49SEG_2 185I/O SEG_3SEGX48SEG_3 186GND187I/O SEG_4SEGX46SEG_4 188VCC189I/O SEG-A SEGX411SEG_A 190I/O SEG_B SEGX47SEG_B 191I/O SEG_C SEGX44SEG_C 192VCCINT193VCCAUX194I/O SEG_D SEGX42SEG_D 195GNDUlinx Corp.FPGA pin No FPGA pin NameLayout NameDeviceDevice pin noDevice Pin name196 I/O SEG_E SEGX4 1 SEG_E 197 I/O SEG_F SEGX4 10 SEG_F 198 I/O SEG_G SEGX4 5 SEG_G 199 I/O SEG_H SEGX43 SEG_H 200 VREF SEG_DOGSEG_DOG201 VCC 202 GND 203 DCI BOT1 S2 S2-2 BOT1 204 DCI BOT2 S3 S3-2 BOT2 205 VREFBOT3S4 S4-2BOT3206 HWWAP_EN207 PROG_BPROGRAM S5 S5-2PROGRAM208TDITDI_FPGA。