TSM3461CX5中文资料

阀控式密封铅酸蓄电池产品说明书宁波九洲圣豹电源有限责任公司目录1 引言 (1)2 主要用途 (1)2.1浮充使用 (1)2.2循环使用 (1)3 电池结构 (2)4 密封原理 (2)5 技术特点·························································· (4)6 技术规格 (5)7 电气性能 (9)7.1充电特性 (9)7.1.1浮充电特性 (9)7.1.2循环充电特性 (9)7.1.3均衡充电特性 (10)7.2放电特性 (10)7.2.1恒电流放电特性 (10)7.2.2放电容量温度特性 (13)7.2.3冲击放电特性 (13)7.2.4容量换算系数与时间关系曲线 (14)7.2.5容量换算系数比较 (15)7.2.6恒定终止电压放电特性 (15)7.2.7大电流放电特性 (15)7.3 容量保持特性·························································· (16)7.4 内阻特性 (16)7.5 寿命特性 (16)8 安装指南 (17)8.1 安装注意事项 (17)8.2 蓄电池安装 (17)8.3 电池柜安装 (18)9 验收 (22)9.1 验收标准 (22)9.2 验收规则 (22)9.3 容量校核 (22)10 使用与维护 (23)11 蓄电池常见故障及消除方法 (24)12 技术服务及质量信息反馈 (25)1 引言宁波九洲圣豹电源有限责任公司是哈尔滨九洲电气股份有限公司控股的子公司，是2010年9月哈尔滨九洲电气股份有限公司与圣豹电源有限责任公司合资成立的专业生产各类蓄电池的生产厂家。

南京拓品微电子有限公司NanJing Top Power ASIC Corp.数据手册DATASHEETTP4057(500mA线性锂离子电池充电器)概述、特点、典型应用-------------------------------------------------------------------------------------P2管脚、特性指标----------------------------------------------------------------------------------------------P3引脚功能说明-------------------------------------------------------------------------------------------------P5充电电流大小设置、电池反接保护功能----------------------------------------------------------------P7充电指示状态、无电池连接指示状态-------------------------------------------------------------------P8多种典型应用图、使用注意事项-------------------------------------------------------------------------P12采用SOT23封装500mA 防锂电池反接充电器Top Power ASIC拓品微电子特点·锂电池正负极反接保护； ·高达500mA 的可编程充电电流； ·无需MOSFET 、检测电阻器或隔离二极管； ·用于单节锂离子电池 ·恒定电流/恒定电压操作，并具有可在无过热危险的情况下实现充电速率最大化的热调节功能；·可直接从USB 端口给单节锂离子电池充电； ·精度达到±1%的4.2V 预设充电电压； ·最高输入可达9V ； ·自动再充电；·2个充电状态开漏输出引脚； ·C/10充电终止；·待机模式下的供电电流为40uA ； ·2.9V 涓流充电器件版本； ·软启动限制了浪涌电流； ·采用6引脚SOT-23封装。

User’s manual ENVCI07For variable speed compressors62 205 930 11 ed00 Applicable as of Version 1209/04Worthington-CreyssensacPage 262 205 930 11Table of contains1 - GENERAL INFORMATION ..........................................................................................................................3 2- USER INTERFACE ......................................................................................................................................3 2.1 D ISPLAYS ..................................................................................................................................................3 2.2 P USH BUTTONS ..........................................................................................................................................4 2.3 LED’S .......................................................................................................................................................4 3- MENUS AND FUNCTIONS ..........................................................................................................................4 3.1 M ENU CODE ENTRY / PARAMETER MODIFICATION .........................................................................................4 3.1.1 Entering menus................................................................................................................................4 3.1.2 Parameter modification....................................................................................................................5 3.2 M ENU STRUCTURE – QUICK REFERENCE .....................................................................................................6 3.3 M ENUS AND CHANGEABLE FEATURES ..........................................................................................................7 3.3.1 Status menu.....................................................................................................................................7 3.3.2 Error log menu..................................................................................................................................7 3.3.3 Maintenance interval menu..............................................................................................................7 3.3.4 Basic settings menu.........................................................................................................................8 3.3.5 Machine configuration......................................................................................................................9 3.3.6 Regulating settings...........................................................................................................................9 3.4 M ICRO POWER INTERRUPTIONS ................................................................................................................10 4 - CONTRAST ................................................................................................................................................11 5 - MAINTENANCE .........................................................................................................................................11 6- START UP AND OPTIMISING FINAL MACHINE ADJUSTMENTS (11)7 - MAIN OCCURRENCES .............................................................................................................................12 8 - DRYER MANAGEMENT ............................................................................................................................13 9 - SPECIFIC VARIABLE SPEED MOTOR . (13)Worthington-Creyssensac 09/0462 205 930 11Page 31 - General informationThe VCI07 controller has been developed for the control of medium to large size variable speed compressors, integrating “Variable Speed”.The VCI07 has a metal housing and can be mounted inside or outside the electrical cabinet of the compressor.Two 3-digit LCD displays and an alphanumeric display with 2 lines of 16 characters permanently show the behaviour of the compressor.We devoted special attention to the development of a simple user interface.2 - User interfaceThe VCI07 controller is equipped with three bottom-view-side-lighted displays, 8 push buttons and 4 LEDS.StartStop Display Reset2.1 DisplaysThe VCI07 is equipped with 3-bottom view - side lighted displays. Each display is dedicated for a specific purpose:The following messages can be displayed:Message Meaning3 digit seven segment (left display) e.g. 6.8- - -• Current pressure is constantly beingdisplayed• Indicating a pressure sensor error3 digit seven segment (right display) e.g. 86- - -• Current temperature is being constantlydisplayed• Indicating a pressure sensor error Alpha numeric 2 lines 16 character e.g. emergency stop e.g. standbye.g. oil service Error indications Status indications Service timersTable 109/04Worthington-CreyssensacPage 462 205 930 112.2 Push buttonsThe VCI07 is equipped with 8 tactile push buttons. In the standard software, each push button has its own specific function.Arrow up Select previous menu item Arrow down Select next menu item Minus Exit current menu (back to previous) Plus Entering the selected menu Enter Modifying / confirming variable settings Green rectangular Starting the compressor locally Red rectangular Stopping the compressor locally Reset Return to the basic menu orReset the controller whenever an alarm/warning occurred.Table 22.3 LED’sThe VCI07 is equipped with 4 LEDS. Each LED has its own specific function.BAR The pressure unit is set at BAR (see Table 7 on page 9) PSI The pressure unit is set at PSI (see Table 7 on page 9)°CThe temperature unit is set at Celsius (see Table 7 on page 9) °F The temperature unit is set at Fahrenheit (see Table 7 on page 9)Table 33 - Menus and functions3.1 Menu code entry / parameter modificationThis paragraph explains how to select a menu and how to scroll through the different parameters.3.1.1 Entering menusand/or returning to the basic menuWorthington-Creyssensac 09/0462 205 930 11Page 5How the different menus and sub-menus can be entered, is shown below:3.1.2 Parameter modificationa) Parameter modification without password protection•Within the entered menu, select the parameter to be changed by scrolling through the menu with the up and down arrow-button (step 1)• Push the enter-button and the parameter value will start blinking (step 2) • Change the blinking value with the “+” or “-“ button (step 3) • Confirm with the enter-button (step 4)09/04Worthington-CreyssensacPage 662 205 930 113.2 Menu structure – quick referenceCurrent time & date set-up Date 1+time+pressure 1 Date 1+time+pressure 2 Date 1+time+pressure 3 Date 1+time+pressure 4 etc. ( up to 32 )Note: Dr. alarm and Dryer Start are visible if the drier option is enabled in the factory or in the SAV menu.Worthington-Creyssensac 09/0462 205 930 11Page 73.3 Menus and changeable features 3.3.1 Status menuThe status menu can be considered as the default menu. It is shown at start-up of the controller and the VCI07 will revert to this menu after one minute when the keyboard activity stops while displaying a different menu. The following messages are displayed :• Machine status (e.g. standby, blowing down, onload, offload, etc.) • Time and day• Errors - active faults are blinking (e.g. air. Temp ----, Oil filt P warn, etc.)3.3.2 Error log menuThe VCI07 saves the 10 most recent occurred faults. By using the up and down arrow-button all the messages can de displayed. Below an example is given:Fault log nr. 1 High pressure fault Occurred fault number 1 is being displayed Fault log nr. 2 Emergency stop Occurred fault number 2 is being displayed Fault log nr. 3 Air filter P warning Occurred fault number 3 is being displayed Fault log nr. 4 Temperature probe fault Occurred fault number 4 is being displayed (See Table 1 on page 3) Etc.Table 4After a fault has been selected and the enter-button is pushed continuously, the date and time is displayed when the fault occurred.3.3.3 Maintenance interval menuIn the timer menu the following timers can be checked:Running hours Total running hours is being displayed Loaded hours Total loaded hours is being displayed Air filter time Remaining hours to air filter service is being displayed Oil filter time Remaining hours to oil filter service is being displayed Oil separator time Remaining hours to oil separator service is being displayed Oil change time Remaining hours to oil change is being displayed Lubrication Motor lubricationTable 5Note: Setting and resetting the displayed values can be done in the service setting menu.09/04Worthington-CreyssensacPage 862 205 930 113.3.4 Basic settings menuOffload PFrom this level the machine starts working offload (for max. value see also factory settings). After a timing(“slow down time”), the compressor stops except the pressure has reached the pressure load level.8 6 P.max On Load P Pressure target in Variable Speed Regulation 6.6bar P. minOffload P.P.scheduleEnabling or disabling the pressure schedule OFF OFFON Press. schedule The current time can be set as well as the configuration of the pressure schedule throughout theweek (see 3.3.4.1 below)Drainspit time Opening time of the drain to release the moisture of the after cooling process2sec 1sec20secDrain dwell time Opening interval of the drain30sec 10sec120sec Dr. alarmDryer high temperature alert threshold 0 °C 5 °C30 °C Dryer start temporization of drier starting before the compressor= time necessary to produce dry air. 0 015minTable 63.3.4.1 Pressure scheduleThe pressure time menu is used for programming over an entire week of up to 32 different pressure settings (e.g.: [REF] onload P. or 7 bar pressure required), associated with specific times. To modify the parameters in this menu, also see settings: pressure time Chap. (3.2).06Jun Fri 10 :291999Mon 06 :307.0BARMon 17 :30[OFF]Mon 19 :00[OFF]Required pressure [REF] = Onload pressureWorthington-Creyssensac 09/0462 205 930 11Page 93.3.5 Machine configurationIn the machine configuration menu, the following application specific parameters can be set:or possible values Auto restart Automatic restart of the machine after a power failure in case when the machine was running before the power failure.ARR ARR MARStart ctrl Select between local ON/OFF (on VCI07 box) or remote ON/OFF via the digital input 3.ON/OFF check can also be made via the RS 485 link For example with LeadairLOC LOC, EXT, 485Press. ctrl Selection between (no load / load) operation locally or via the RS 485 link (with Leadair)Remark: The DI 06 digital input has priority over this check function.DI 06 is the low-pressure switch input.Placing a relay in series with this pressure switch makes it possible to remotely control the (no load /load) operation.LOC LOC 485Machine number Address of the controller in an RS485 network 1 1 254 P unit Selection of the pressure unit BAR BAR PSI T unit Selection of the temperature unit °C °C °F Power unit Defines and activates instantaneous power display % - - - % Language Selection of the language in which the messages are displayed.EnglishMin temp Minimum oil temperature below which the machine does not start.2 °C -10 °C +10 °CRelay 6 It defines R 06 output as: Alarm and fault reportingR 06 changes state in the event of a machine alarm Machine safety or maintenance counters to 0 ….. - or in the event of a faultthe machine stops due to a safety problem - Fault report (only)Machine state: Output activated if the machine is operating (stand by) or if the motor is running Alarm Alarm / Error / StateTable 7Important note:It is always possible to stop the machine locally when remote start / stop function is enabled.3.3.6 Regulating settingsWhile the compressor is running loaded, a variable output signal is being generated by the PWM output. This signal is based on a PI control algorithm and can be used to drive an actuator (e.g. a proportional valve or a frequency inverter). The pressure regulation algorithm will control the actuator in order to maintain the load pressure at all time. If the actuator can not sufficiently cut back, the compressor will rise until it reaches the unload pressure. The compressor will then unload and the PI pressure control algorithm is disabled. As the pressure goes down and reaches the load level again, the compressor loads again and the PI control will take over. (see Table 6, Chap. 3.3.4)09/04Worthington-CreyssensacPage 1062 205 930 11ATTENTION :Do not adjust correctors P and I. They undergo in-factory configuration for compatibility with more than 95% of installations. During the setup, the installer checks the settings. If in doubt contact our after-sales service.Min. value It reflects the minimum output level of the control algorithm atwhich can be cut back. Below this value, the compressor will beput offload. The minimum value is expressed in %.0% 0% 100% P factor This proportional control factor determines how much thecontrol will react to differences between actual and targetpressure.40% 0% 100% I factor This integral control factor determines the “weight” of theintegral on the control action.10% 0% 100%Model Maximum frequency management model. Setting dependent uponmachine type (see VCI07 settings instructions)Unload Fr. The frequency at which the machine turns in no load operation 20Hz 0Hz 200Hz Max. Freq. Maximum frequency of variator. Setting dependent uponmachine type (see VCI07 settings instructions)Min Freq. Motor-compressor minimum frequency, set into the variable speed drive. This parameter is useful for displaying the instantaneous power10Hz 0Hz 200HzMax. Power Maximum power of machine. Setting dependent upon machine type (see VCI07settings instructions)Onload loss Defined for instantaneous power calculation 0 16 Safety fac.= Safety factor and proportional correction. Setting dependent upon machine type (see VCI07settings instructions)Ventil Stop. Ventilator stop.OFF OFF ONT Vent. STOP Time between shaft stop and ventilator stop = tempo at which the ventilator continues to turn after shaft stop.This safety feature prevents the oil temperature from rising after the machine has stopped.60 0 600Fan sp. entr Activates the ventilation speed variation: used to control the oiltemperature OFF ON OFFTH reg. Visible when ‘Var ventil ‘ is active, this parameter is the oiltemperature setpoint: it is the desired oil temperature 80 °C 70 °C 100 °CTable 83.4 Micro power interruptionsThe VCI07 is standard equipped with a micro power interruption detection of 40ms function. Every zero passage of the 24VAC main is detected. When 2 consecutive cycles or a power failure of 40ms is detected, the controller will automatically stop the machine. At the same time, all relays are released and 3 horizontal dashes are displayed on the LED display. By stopping the machine during a micro power interruption, sparks on the relay contacts are avoided which will extend the relay lifetime.4 - ContrastThe only possible adjustment is the visual angle of the alphanumeric display. In the factory this angle is already adjusted to its best position. When another angle is wanted it can be changed by removing the black cap at the bottom of the unit. Just behind the aperture a 270 degrees potentiometer is located. Use a screwdriver with a 25mm blade or less to make the adjustment. Do not forget to replace the black cap.5 - MaintenanceThe VCI07 does not need maintenance. When the front panel is dirty, it can be cleaned with a soft cloth drenched in soap water or methanol.6 - Start up and optimising final machine adjustmentsThe machine undergoes in-factory configuration in order to limit the need for adjustments during installation. Therefore, only the pressure thresholds need to be set :- “OnLoad P” = desired regulation pressure (in vari-speed)In order to conserve energy to the maximum, it is advised to lower the regulation pressure to thelowest possible level ( so as to optimize power)- “Offload P” = Delayed stop pressure of the machineFor energy consumption that is less than the minimum capacity , it is advised to set it at + 0,5 barabove the “P load”.In certain rare cases, it may prove useful to adjust the regulation settings (see chapter 7, main operational occurrences).7 -Main occurrencesOccurrences Solutions1. THE MACHINE STOPS AND STARTS AGAIN BUTONLY FOR A SHORT TIME Increase unloading time (for +5 to +20 s) so that the motor doesn’t stop so often (the compressor runs for longer before stopping). If this delay is insufficient, increase the “unloading time” and the minimum unloading time by the same amount (for example : +30s)2. THE MACHINE STOPS, DISPLAYING THE MESSAGE”MOTOR ERROR” Check that there is no mechanical blockage of the motor. See variator instructions : the fault comes from the variator. Identify the fault.Ne pas réinitialiser la machine sans chercher la source du problème.3. THE OIL TEMPERATURE IS TOO HIGH (THEMACHINE STOPS OR AN ALERT IS GIVEN) Lower the pressure to the min. level that the client will need. Decrease the “dry fact” setting by 2 to 10%In the event of failure, proceed more progressively : by consecutive steps of 1 to 2%, testing each time the rise in machine temperature.In this way, machine cooling is steady and total absorbed power is reduced (as is the case with the capacity)4. THERE ARE LARGE FLUCTUATIONS OF PRESSURE(MORE THAN 0,2 BARS) FOR FLOWS IN BETWEEN THE MAXIMUM AND MINIMUM CAPACITYI. Read the variator frequency (see variator instructions) Check that it is higher than the minimum frequency (the capacity is thus higher than the minimum capacity). If this is the case, reduce the integral factor (I factor) so as to reduce fluctuations.Attention : reducing it too much will slow the rise in pressure.5. THE PRESSURE DOES NOT RISE QUICKLYIncrease the P factor.6. THE MACHINE EQUIPPED WITH A DRIER DOESNOT START Wait or reduce the ‘dém séch‘ drier starting time to 0 min for machine starting.7. THE MACHINE STOPS AND ‘‘ERR T. MOTEUR’’ ISDISPLAYED The variable speed motor is overheating (RLR 220V). Check that the machine is not operating at an excessive ambient temperature (> 40 °C)8. THE MACHINE STOPS AND (DRYER FAULT) ISDISPLAYED The drier low temperature threshold has been reached Contact your After Sales Service to check that the drier is not frozen, (if the drier is not frozen, it is possible to maintain the drier low temperature threshold in the drier menu)8 - Dryer ManagementThis controller is compatible with the integral dryer and specific variable speed motor options. Dryer Management- The VCI07 may be configured in three manners to control the dryer:•- - - “no message”•Ale “Alert” (default setting)•ERR “Stop on FAULT”- - -Bottom Message/Top Message/Ale Dryer t. too low Dryer t. too highERR ERR : Dryer t. low ERR : Dryer t. highA start time before compressor starting can be indicated (see Chap. 3.2 “Base” settings).Dryer freezing- The VCI07 indicates a dryer alert when the dryer temperature is less than the bottom threshold value:It displays “Dryer t. too low” and the machine does not stop.The unit may be stopped following an error message by changing its mode with ERR: it displays“ ERR : Dryer t. low ”, the machine stops.Dryer and By-Pass replacementIf the dryer is replaced or has a direct connection (by-pass), it is necessary to disable the dryer functions in the drier menu-accessible through SAV code.The dryer “dew point” temperature acquisition is then disabled, as well as the ON/OFF control.9 - Specific variable speed motorIn certain applications, the motor is equipped with motor temperature control probes.A high motor temperature alarm is activated in order to alert the user about motor overheating.A machine fault – a complete compressor shutdown is triggered when the maximum temperature threshold of the winding is reached (see Operation Incidents).Check the compressor operation ambient temperature and the case internal temperature.____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ________________________________________________________________________________________________________________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________ ____________________________________________________________________________________________________。

SPAD 346 CStabilized differential relayStabilized Differential Relay T ype SPAD 346 CFeatures•Integrated three-phase differential relay, three-phase overcurrent relay and multi-configurable earth-fault relay •Stabilized differential relay module providing winding short-circuit and interturn fault protection for two-winding power-trans-formers and generator-transformer units, and interwinding short-circuit protection for generators.•Earth-fault relay module providing protec-tion for the transformer HV and LV side according to the selected principle: stabilized differential current principle, high-imped-ance principle, residual current principle or neutral current principle•Three-stage overcurrent module providing protection for power transformers and generators and two-stage back-up earth-fault protection•Short operate time even at partial saturation of the current transformers•Operation characteristic of differential relay module easily adapted for different applica-tions•Stabilized against unwanted operations at faults occurring outside the protected area and at transformer inrush•Second harmonic restraint for prevention of unwanted relay operations at transformer inrush•Fifth harmonic restraint for prevention of unwanted relay operations at transformer overexcitation - The fifth harmonic restraint can be aborted if the ratio of the fifth har-monic and the basic frequency component rises too high at dangerous overvoltages •Wide CT ratio correction range - accurate correction through digital setting•No interposing current transformers needed for the protection of two-winding power transformers - numerical vector group matching on HV and LV side•Four heavy-duty output relays for circuit breaker tripping and five output relays for signalling•Five programmable external control inputs intended for alarm and trip signals from gas relays, oil temperature sensors and other sensors of transformer auxiliary devices •Integrated circuit breaker failure protection with adjustable operate time •Differential relay and earth-fault relay modules provided with integrated distur-bance recorder functions for analog and digital signals - signals to be used for trigger-ing selectable•Sensitive phase current and phase angle displays facilitate checking of energizing circuit connections and vector group matchings•High immunity to electrical and electromag-netic interference allows the relay to be used in severe environments•High availability and system reliability due to continuous supervision of hardware and software•Powerful software supports relay parametri-zation and reading of measured, recorded and event data•CE marking according to the EC directive for EMC.ApplicationThe stabilized differential relay SPAD 346 C is designed for protecting two-winding power transformers and generator-transformer units against winding short-circuit, interturn fault, earth fault and short circuit, and generators and motors against interwinding short-circuit and pole short circuit. In addition, the relay can be used for the protection of three-wind-ing power transformers, provided 75% of the short circuit power to the power transformer is supplied from the same direction, and for the protection of compensating chokes and short cable lines.No interposing transformers are needed for the protection of two-winding power transformers, as the relay allows the vector group matching, the elimination of the zero-sequence component of the phase currents and the CT ratio corrections to be carried out numerically.Earth faults outside the protected area can cause differential currents if the star point of the power transformer to be protected is earthed on the HV side or the LV side. Nor-mally, unwanted relay operations can be avoided by eliminating the zero-sequence components of the phase currents in the vector group matching. Should the LV side of a Y/D-connected transformer with earthed star point be earthed via a zig-zag connected earthing transformer, the zero-sequence components can be numerically eliminated in the relay.At single-phase or two-phase earth faults within the protected area the sensitivity of the normal, phase current measuring differential protection will not be sufficient, in particular, if the star point of the transformer is earthed via a resistor. The earth-fault relay module provides coverage for these situations as well.The combined overcurrent and earth-fault relay module provides phase overcurrent protection and back-up earth-fault protection for the protected object.The current transformer connections and the vector group matching are easily checked by means of a low-voltage test and the sensi-tive phase current and phase angle displays of the relay. The test includes the current trans-formers on both the HV side and the LV side of the power transformer.The disturbance recording functions integrated into the differential relay module and the earth-fault relay module can be started, for example, by an external control signal or the operate signals of the module. The disturbance record provides vital informa-tion about current magnitudes, curve forms and digital relay module signals, for instance, after a fault situation.The differential relay is provided with push-buttons and displays for local man-machine communication and a serial interface for remote communication with higher-level systems. The relay is a member of the SPACOM substation equipment system, which is part of ABB’s Distribution Automa-tion system and ABB’s Panorama concept.Relay module featuresDifferential relay module SPCD 3D53•Three-phase stabilized differential relay module for protecting two-winding power transformers and generator-transformers units againstinterwinding short circuit and interturn faults, and power-generatorsagainst winding short circuit and pole short circuit.•The operation of the module is based on measuring the fundamentalfrequency component of the phase currents; the DC components andthe harmonics of the phase currents are digitally filtered•Numerical setting of the power transformer vector group•The zero-sequence component of the phase currents can be separatelyeliminated from the phase currents•Numerical setting of the correction of the CT ratio•The operation characteristic of the stabilized differential current stagematchable to the requirements of the application•Adjustable start current value of the instantaneous differential currentstage•Adjustable second and fifth harmonic restraint•Software matrix for linking the trip, blocking and control signals todesired output relays•Local and remote numerical presentation of phase current amplitudesand phase differences•Integrated circuit-breaker failure protection with adjustable operatetime•Integrated disturbance recorder for phase currents and digital relaysignals•Local man-machine communication via push-buttons and display•Continuous self-supervision of electronic circuits and program execu-tionEarth-fault relay module SPCD 2D55 Array•Provides winding earth-fault protection for two-winding powertransformers•Four earth-fault protection principles available: high-impedance,numerical stabilized differential current, residual overcurrent, orneutral overcurrent principle•Basic setting and operate time to be separately adjusted for the HVside and the LV side•Adjustable second harmonic restraint•Software matrix for linking the start, trip, blocking and control signalsto the desired output relays•Integrated circuit-breaker failure protection with adjustable operatetime•Integrated disturbance recorder for phase currents, neutral currentsand digital relay signals•Local man-machine communication via push-buttons and display•Continuous self-supervision of electronic circuits and programexecutionCombined overcurrent and earth-fault relay module SPCJ 4D28ers, generators and generator-transformer units against short circuit•Low-set overcurrent stage with definite time or inverse time character-istic, high-set and superhigh-set overcurrent stage with definite timecharacteristic•T wo non-directional earth-fault stages for back-up protection of thepower transformers and the generator-transformer unit•Low-set earth-fault stage with definite time or inverse time character-istic, high-set stage with definite time characteristic•Sensitive phase unbalance unit providing protection against phasediscontinuity, single-phasing and generator unbalance•Software matrix for linking the start and trip signals to the desiredoutput relays•Integrated circuit-breaker failure protection with adjustable operatetime•Local man-machine communication via push-buttons and display•Continuous self-supervision of electronic circuits and program execu-tionBlock and connection diagramFig. 1. Block and connectiondiagram for the stabilizeddifferential relay SPAD 346 CTechnical dataEnergizing inputsRated current I n 1 A 5 A Terminal numbers X0/1-3,X0/1-2,4-6, 7-94-5, 7-8X0/13-15,X0/13-14,16-1816-17X0/19-21,X0/19-20,25-2725-26X037-39X0/ 37-38 Thermal current withstand– continuously 4 A20 A– for 10 s25 A100 A– for 1 s100 A500 A Dynamic current withstand– half-wave value250 A1250 A Input impedance<100 mΩ<20 mΩRated frequency f nacc. to order50 Hz or 60 HzOutput relaysT rip relaysTerminal numbers X1/11-12-13-14X1/15-16-17-18X2/3-4, 5-6Rated voltage250 V ac/dc Continuous currentcarrying capacity 5 AMake and carry for 0.5 s30 AMake and carry for 3 s15 ABreaking capacity for dcwhen the control circuittime constant L/R ≤40 msat the control voltage levels48/110/220 V dc 5 A/3 A/1 AContact material AgCdO2Signal relaysTerminal numbers X2/ 7-8, 9-10, 11-12-13X2/14-15, 16-17-18 Rated voltage250 V ac/dc Continuous currentcarrying capacity 5 AMake and carry for 0.5 s10 AMake and carry for 3 s8 ABreaking capacity for dcwhen the signal circuittime constant L/R ≤40 msat the signalling voltage levels48/110/220 V dc 1 A/0.25 A/0.15 A Contact material AgCdO2Control inputsTerminal numbers X1/1-2, 3-4, 5-6, 7-8, 9-10 Control voltage– operative range18...265 V dc or80...265 V acCurrent drain of activatedcontrol input 2...20 mAActive state of input– input active when energized– input active when non-energizedAuxiliary power supplyTerminal numbers X2/1-2Supply moduletype SPGU 240A1:– rated voltages U n = 110/120/230/240 V acU n = 110/125/220 V dc – operative range U = 80...265 V ac/dc Module type SPGU 48B2– rated voltages U n = 24/48/60 V ac– operative range U = 18...80 V dc Power consumption underquiescent/operationconditions12 W/18 WData communicationTransmission mode Fibre-optic serial bus Coding ASCIIData transfer rate, selectable4800 Bd or 9600 Bd Electrical/optical busconnection modulepowered from the host relay– for plastic core cables SPA-ZC 21BB– for glass fibre cables SPA-ZC 21 MM Electrical/optical busconnection module poweredfrom the host relay and/oran externalpower source– for plastic core cables SPA-ZC 17BB– for glass fibre cables SPA-ZC 17 MMSoftware supportSubstation monitoringprogram SMS 010Evaluation program fordisturbance records DR-COMTest voltagesDielectric test voltage(IEC 255-5) 2.0 kV, 50 Hz, 1 min Impulse test voltage(IEC 255-5) 5 kV, 1.2/50 µs, 0.5 J Insulation resistance(IEC 255-5)>100 MΩ, 500 V dcDisturbance testsHigh-frequencydisturbance test(IEC 255-22-1, class III)– common mode 2.5 kV, 1 MHz,– differential mode 1.0 kV, 1 MHz, Electrostatic discharge( IEC 255-22-2 andIEC 801-2, class III)– air discharge8 kV– contact discharge 6 kVFast transients(IEC 255-22-4, class III)and IEC 801-4, level IV– power supply inputs 4 kV– other inputs 2 kVEnvironmental conditionsService temperature range-10...+55°CT ransport and storagetemperature range(IEC 68-2-8)-40...+70°C Temperature influence0.1%/°CRelative humidity(IEC 68-2-30)93…95%, +55°C,6 cyclesDegree of protection byenclosure of flush mountingrelay case (IEC 529)IP 54Weight of fullyequipped relay 6 kg RELAY MODULE DATAStabilized differential relay module SPCD 3D53 Selectable rated frequency f n16 2/3...60 HzCT ratio correction rangeon power transformerHV side I1/I n0.40...1.50CT ratio correction rangeon power transformerLV side I2/I n0.40...1.50Stabilized differential current stage 3∆I>Basic start ratio P/I n 5...50%Starting ratio setting S10...50% Second turning point I2tp/I nof characteristic curve 1.0...3.0 Harmonics blocking ratioI d2f/I d1f>7...20% Harmonics blocking ratioI d5f/I d1f>10...50% Harmonics deblocking ratioI d5f/I d1f>>10...50% Operate time (includingheavy duty output relays)– at currents 1.5…4 x operatevalue<50 ms– at currents above 4 x operatevalue<45 ms Operation accuracy±4% of set value or±2% x I n Instantaneous differential current stage 3∆I>>Start ratio I d/I n>> 5 (30)Operate time (includingheavy-duty output relays)–at ratios in the range1.1...2.6 x I d/I n>><35 mm–at ratios above2.6 x I d/I n>><30 ms Operation accuracy±4% of set valueof 2% x I nCircuit breaker failure protectionOperate time0.1...1.0 sIntegrated disturbance recorderRecording length38 cycles Recording memory capacity 1 recording = 38 cyclesSampling frequency40 samples/cycle Signals to be recorded 6 analog signals11 digital signals T riggering–when the selecteddigital signal is activated–when the selecteddigital signal resetsLength of recordingpreceding triggering0...38 cyclesEarth-fault relay module SPCD 2D55Selectable rated frequency f n16 2/3...60 HzStabilized differential relay principleBasic start ratio onHV side P1/I n 5...50% Operate time on HV side t01>0.03...100 s Basic start ratio onLV side P2/I n 5...50% Operate time setting onLV side t02>0.03...100 s Correction range of HV sideneutral connection CT ratioI01/I n0.40...1.50 Setting of minimum ratio ofHV side neutral current andresidual current of phasecurrents I01/∑I10...20% Correction range of LV sideneutral connection CT ratioI02/I n0.40...1.50 Setting of minimum ratio ofLV side neutral current andresidual current of phasecurrents I02/∑I20...20%Second harmonics restraintratio I2f/I1f of HV sideneutral current I0110...50% Second harmonics restraintratio I2f/I1f of LV sideneutral current I0210...50% Correction range of HV sidephase CT ratio I1/I n0.40...1.50 Correction range of LV sidephase CT ratio I2/I n0.40...1.50 Operate time at minimumdelay (including heavy-duty output relays)30...40 ms Operation accuracy±4% of set value or±2% x I nPrinciple based on calculated residual currentBasic start ratio P1/I non HV side 5...50% Operate time t01>on HV side0.03...100 s Basic start ratio P2/I non LV side 5...50% Operate time t02> on LV side0.03...100 s Correction range of HV sidephase CT ratio I1/I n0.40...1.50 Correction range of LV sidephase CT ratio I2/I n0.40...1.50 Operate time at minimumdelay (including heavy-duty output relays)30...40 ms Operation accuracy±4% of set value or±2% x I n Principle based on measured residual current or neutral currentBasic start ratio P1/I n onHV side 5...50% Operate time t01> on HV side0.03...100 s Basic start ratio P2/I n on LV side 5...50% Operate time t02> on LV side0.03...100 s Correction range of HV sideneutral connection CT ratioI01/I n0.40...1.50 Correction range of LV sideneutral connection CT ratioI02/I n0.40...1.50 Second harmonics restraintratio I2f/I1f of HV sideneutral current I0110...50% Second harmonics restraintratio I2f/I1f of LV sideneutral current I0210...50% Operate time at minimumdelay (including heavy-duty output relays)30...40 ms Operation accuracy±4% of set value or±2% x I nRestricted earth-fault principle (high-impedancetype earth-fault protection)Basic start ratio P1/I n onHV side 5...50% Operate time t01> on HV side0.03...100 s Basic start ratio P2/I n on LV side 5...50% Operate time t02> setting onLV side0.03...100 s Correction range of HV sideneutral connection CT ratioI01/I n0.40...1.50 Correction range of LV sideneutral connection CT ratioI02/I n0.40...1.50 Operate time at minimumdelay (including heavy-duty output relays)30...40 ms Operation accuracy±4% of set value or±2% x I nCircuit-breaker failure protectionOperate time0.1...1.0 sIntegrated disturbance recorderRecording length30 cycles Recording memory capacity 1 recording =30 cycles Sampling frequency40 samples/cycle Signals to be recorded8 analog signals12 digital signals Triggering–when the selecteddigital signal is activated-when the selecteddigital signal resetsLength of recording precedingtriggering0...30 cyclesOvercurrent and earth-fault relay module SPCJ 4D28Low-set overcurrent stage I>Start current I>– definite time characteristic0.5...5.0 x I n– inverse time characteristic0.5…2.5 x I n * Start time, typ.70 msOperation characteristic– definite time characteristic– operate time0.05...300 s– inverse time characteristicacc. to BS 142 and IEC 255-4Extremely inverseVery inverseNormal inverseLong-time inverse – special characteristic acc.to ABB practice RI-type inverseRXIDG-type inverse – time multiplier k0.05...1.00Reset time, typ.40 ms Retardation time<30 msDrop-off/pick-up ratio, typ.0.96Operate time accuracy atdefinite time operationcharacteristic±2% of set timeor ±25 ms Operate time accuracyclass E at inverse timecharacteristic5Operation accuracy±3% of set currentHigh-set overcurrent stage I>>Start current I>>0.5...40.0 x I nor ∞, infiniteStart time, typ.40 msOperate time0.04...300 sReset time, typ.40 ms Retardation time<30 msDrop-off/pick-up ratio, typ.0.96Operate time accuracy±2% of set timeor ±25 ms Operation accuracy±3% of set current Superhigh-set overcurrent stage I>>>Start current I>>>0.5...40.0 x I nor ∞, infiniteStart time, typ.40 msOperate time0.04...30 sReset time, typ.40 ms Retardation time<30 msDrop-off/pick-up ratio, typ.0.96Operate time accuracy±2% of set timeor ±25 ms Operation accuracy±3% of set current Low-set residual earth-fault stage I0>Start current I0>0.1…0.8 x I nStart time, typ.70 msOperation characteristic– definite time characteristic– operate time0.05...300 s– inverse time characteristicacc. to BS 142 and IEC 255-4Extremely inverseVery inverseNormal inverseLong-time inverse– special characteristic acc.to ABB practice RI-type inverseRXIDG-type inverse – time multiplier k00.05...1.00Reset time, typ.40 ms Retardation time<30 msDrop-off/pick-up ratio, typ.0.96Operate time accuracy atdefinite time operationcharacteristic±2% of set timeor ±25 msOperate time accuracyclass E at inverse timecharacteristic5Operation accuracy±3% of set currentHigh-set residual earth-fault stage I0>>Start current I0>>0.1...10.0 x I nor ∞, infiniteStart time, typ.50 msOperate time0.05...300 sReset time, typ.40 msDrop-off/pick-up ratio, typ.0.96Operate time accuracy±2% of set timeor ±25 ms Operation accuracy±3% of set currentPhase discontinuity protection stage ∆I>Start current ∆I>10...100% x I nor ∞, infiniteStart time, typ.150 msOperate time 1...300 sReset time, typ.80 msDrop-off/pick-up ratio, typ.0.90Operate time accuracy±2% of set valueor ±25 ms Operation accuracy±1 unit ±3% ofset current*At inverse time characteristic the effective setting range is 0.5…2.5 x I n, although setting values greater than 2.5 x I n can be set on the relay.Mounting and DimensionsABB Oy, Distribution Automation P.O.Box 699FIN-65101 VAASA FinlandTel: +358 10 22 11Fax: +358 10 22 41094/substationautomation©Copyright21ABB.Allrightsreserved/1MRS7522-MDSFABB Limited, Distribution AutomationManeja, Vadodara - 390013, IndiaTel: +91 265 260 4386Fax: +91 265 263 8922/substationautomation。

®VNQ05XSP16QUAD CHANNEL HIGH SIDE SOLID STATE RELAYMarch 20031/17VNQ05XSP16 BLOCK DIAGRAMVNQ05XSP16VNQ05XSP16VNQ05XSP16VNQ05XSP16VNQ05XSP16VNQ05XSP16 Figure 3: WaveformsVNQ05XSP16 APPLICATION SCHEMATICGND PROTECTION NETWORK AGAINST REVERSE BATTERYSolution 1: Resistor in the ground line (R GND only). This can be used with any type of load.The following is an indication on how to dimension the R GND resistor.1) R GND≤ 600mV / (I S(on)max).2) R GND≥ (-V CC) / (-I GND)where -I GND is the DC reverse ground pin current and can be found in the absolute maximum rating section of the device’s datasheet.Power Dissipation in R GND (when V CC<0: during reverse battery situations) is:P D= (-V CC)2/R GNDThis resistor can be shared amongst several different HSD. Please note that the value of this resistor should be calculated with formula (1) where I S(on)max becomes the sum of the maximum on-state currents of the different devices.Please note that if the microprocessor ground is not common with the device ground then the R GND will produce a shift (I S(on)max * R GND) in the input thresholds and the status output values. This shift will vary depending on how many devices are ON in the case of several high side drivers sharing the same R GND.If the calculated power dissipation leads to a large resistor or several devices have to share the same resistor then the ST suggests to utilize Solution 2 (see below).Solution 2: A diode (D GND) in the ground line.A resistor (R GND=1kΩ) should be inserted in parallel to D GND if the device will be driving an inductive load.This small signal diode can be safely shared amongst several different HSD. Also in this case, the presence of the ground network will produce a shift (≅600mV) in the input threshold and the status output values if the microprocessor ground is not common with the device ground. This shift will not vary if more than one HSD shares the same diode/resistor network.LOAD DUMP PROTECTIOND ld is necessary (Voltage Transient Suppressor) if the load dump peak voltage exceeds V CC max DC rating. The same applies if the device will be subject to transients on the V CC line that are greater than the ones shown in the ISO T/R 7637/1 table.µC I/Os PROTECTION:If a ground protection network is used and negative transients are present on the V CC line, the control pins will be pulled negative. ST suggests to insert a resistor (R prot) in line to prevent the µC I/Os pins to latch-up. The value of these resistors is a compromise between the leakage current of µC and the current required by the HSD I/Os (Input levels compatibility) with the latch-up limit of µC I/Os.-V CCpeak/I latchup≤ R prot ≤ (V OHµC-V IH-V GND) / I IHmax For V CCpeak= - 100V and I latchup≥ 20mA; V OHµC≥ 4.5V 5kΩ≤ R prot≤ 65kΩ.Recommended R prot value is 10kΩ.VNQ05XSP1616/17TAPE AND REEL SHIPMENT (suffix “13TR”)TAPE DIMENSIONSAccording to Electronic Industries Association (EIA) Standard 481 rev. A, Feb. 1986All dimensions are in mm.Tape widthW 24Tape Hole Spacing P0 (± 0.1)4Component Spacing P24Hole Diameter D (± 0.1/-0) 1.5Hole Diameter D1 (min) 1.5Hole PositionF (± 0.05)11.5Compartment Depth K (max) 6.5Hole SpacingP1 (± 0.1)2Top cover tapeEndStartNo componentsNo componentsComponents500mm min500mm minEmpty components pockets saled with cover er direction of feedInformation furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may results from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.The ST logo is a trademark of STMicroelectronics© 2003 STMicroelectronics - Printed in ITALY- All Rights Reserved.STMicroelectronics GROUP OF COMPANIESAustralia - Brazil - Canada - China - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan - Malaysia -Malta - Morocco - Singapore - Spain - Sweden - Switzerland - United Kingdom - U.S.A.。

镁合金定量出料机电器使用说明书一、主要规格及技术参数：1、交流输入电源：交流380V（三相4线制）额定功率：30.8KW额定电流：136A2、PLC：S7-200，AC/DC/继电器CPU224：14I/10O3、SSR：过零型：电压：<240V电流：250A，80A触发电流：>5mA开启电压：>4v二、工作原理：主要控制开关说明：SA1——总电源开关 QF1——加热器电源开关 SA4——温度显示开关 SA3——PLC电源开关整个电器控制系统主要由加热控制电路和气动阀控制电路组成。

1、加热控制部分由温控器（SDC15）和固态继电器（SSR）以及热电耦（K系列）组成。

温控器是日本三武公司的SDC15（SSR型）。

它具有PID温度调节，加热器断路报警输出，SSR驱动输出（V<24V,I<360mA）。

固态继电器采用杭州西子的过零型SSR。

触发电压3—32VDC，触发电流<50mA。

SDC15通过热电耦把加热丝的实际温度采样进来与事先设定的温度值比较后由事先设定PID值确定通过事件输出端口向SSR发出通或断的信号。

同时SDC15还设定了PV（现场温度值）低限报警值，一旦加热丝的温度低于此值就向PLC发出报警信号（PLC EM223 I1.6）。

PLC程序就会停止。

2、气动控制部分由传感器，电磁阀，PLC组成。

PLC采用西门子的S7-200，阀门位置传感器和液位传感器、旋转汽缸位置传感器共同组成反馈系统。

3、控制过程：在加热丝加热一段时间后，加热丝温度处于正常值，PLC上电，（此时坩锅内熔液已准备就绪），抽液/放液旋钮从中间位置拨到抽液位置，打开气路单向阀5YV（开始抽真空），真空泵抽管内空气同时二位五通气路换向阀1YV得电（抽液通道）打开，2YV失电（放液通道）断开，利用真空泵产生的负压将坩锅内熔液抽到定量筒中，当定量筒内镁液的液面到达指定位置S1（液面传感器）动作，此时立即关5YV（抽真空结束）关闭真空泵，同时1YV失电（抽液通道）关闭，2YV得电（放液通道）打开。

数码管3461as参数摘要：一、引言二、数码管简介1.数码管的定义2.数码管的分类三、3461as 参数1.显示段数2.段位选通方式3.驱动方式4.工作电压5.功耗四、3461as 参数的应用优势五、与其他型号数码管的比较六、结语正文：一、引言随着科技的不断发展，数码管这种显示器件被广泛应用于各种电子设备中。

数码管有许多种类，而3461as 参数的数码管在市场上颇受好评。

本文将详细介绍数码管3461as 参数的相关信息。

二、数码管简介数码管是一种用于显示数字信息的电子器件，具有高亮度、低功耗、长寿命等优点。

数码管可以根据其显示段数、段位选通方式、驱动方式等参数进行分类。

三、3461as 参数1.显示段数：3461as 参数的数码管具有8 个显示段，可以显示0-9 的十个数字，以及A、B、C、D、E、F 六个字母。

2.段位选通方式：3461as 参数的数码管采用动态扫描技术，通过段位选通电阻实现各段的选通。

3.驱动方式：3461as 参数的数码管采用共阳极驱动方式，即所有阳极共同连接，每个阴极分别连接到一个驱动管。

4.工作电压：3461as 参数的数码管的工作电压范围较宽，一般为5-24V。

5.功耗：3461as 参数的数码管具有低功耗的特性，单段静态功耗小于1mA。

四、3461as 参数的应用优势由于3461as 参数的数码管具有高亮度、低功耗、长寿命等优点，使其在各种电子设备中具有广泛的应用，如家电、通信、交通等领域。

五、与其他型号数码管的比较相较于其他型号的数码管，3461as 参数的数码管具有更高的显示效果和使用寿命。

然而，其价格略高于普通数码管，但考虑到其性能和使用寿命，3461as 参数的数码管具有较高的性价比。

六、结语综上所述，3461as 参数的数码管凭借其优越的性能、低功耗、高亮度等特性，在电子显示领域具有广泛的应用。

The Winning ForceThe Winning ForceAs a total supplier for sheet metal manufacturing with almost60 years of experience, Durma understands and recognizes thechallenges, requirements and expectations of the industry.We strive to satisfy the ever higher demands of our customers bycontinuously improving our products and processes whileresearching and implementing the latest technologies.In our three production plants with a total of 150.000 m²,we dedicate 1,000 employees to delivering high qualitymanufacturing solutions at the best performance-to-price ratioin the market.From the innovations developed at our Research & DevelopmentCenter to the technical support given by our worldwidedistributors, we all have one common mission: to be yourpreferred partner.Present Durmazlar machines with name to the world.High technology,modern productionlinesHigh qualitymachines designedin R&D CentreTop qualitycomponents123Now Production is More EffectiveThe future – as a result of rising energy costs and increasingly cost efficient speed-controlled drives offered on the market, variable-speed solutions are on the advance.AD-Servo Series Press BrakeEnergy-efficient Hydraulics with Variable Speed Pump DrivesEnergy consumption has a significant effect on Total Cost of Ownership of plant and machinery:even with standard machines, the energy consumption represents 30% of total costs, and with particularly energy-intensive applications, this share is remarkably higher.Cost Down Profit UpAdvantagesHigh energy-saving potential Decreased operating costs Clearly reduced cooling effort Operational reliability High availability Lower investment System safetyFuture-oriented technology Remarkable noise reduction Fewer secondary measuresEase of integration of flexible check functionsDecrease in the number of expensive machine failures Compliance with EU DirectivesPrecise bending result at fast speedMinimalized tool change and adjustment time Maximized speed and safetyHigh Capacity Winning ErgonomicRobust Body Perfect PrecisionHighCapacity Low Power ConsumptionEnergy Saver Accurate on each cycle Economy ProofHi-Speed & RepeatabilityComparison of EnergyConsumption of aPress BrakesMain componentsServomotorHydromotor-pump (4-quadr. oper.)Servo controller IndraDrive CSoftware-Technology functionParameterBell housing and couplingPower unit (Oil tank, accessories)Valve block, prefill valveCylinderPhysical characteristicsControl of positionControl of pressure/load pressureOpen/closed hydraulic circuit4-quadrant operationProductivity%60 more productivity with %72less energy consumption at work.AD-Servo positioningaccuracy Less Noise Levelat target positionFast Increase in Efficiency inProductionAD-Servo is high modularity of hydraulics also opens upeconomic options on existing plant and machinery bysubstituting fixed displacement power units byvariable-speed pump drives with little effort.0.000 2.000 4.000 6.0008.00010.00012.00014.000kWhRegular Press BrakesAD-Servo Press BrakesEnergy SavingCost Down Profit UpElectric ConsumptionDepending on cycle characteristicsand rating, variable-speed pumpdrives achieve energy savingsLess Noise LevelWhy DURMA Back Gauge ?Most important feature toachieve perfect bending is the stability and the design of the back gauge, which allows an impeccable and correct product to be produced.The high speed ballscrew back gauge system movement is also supported with linear guides,which helps the back gauge achieve long life, greater sensitivity and strengthens against any collisions.Special designed finger blocks with steps to achieve maximum stability can also be supplied for every kind of bending solution.High sensitivity, Stress relieved steel construction body, long life Mono Block Frame Automatic calibration and first start upDURMA designed and copyrighted guiding systemBall Screw and linear guide integrated perfect back gauge system Durable, long life and sensitive bending capable special hardened top tools Suitable for segmented tools special and fast tool holding system Sensitive solutions on long and deep bending High accuracy linear scales CE safety standardsBest quality world wide accepted hydraulic and electric componentsStrong Back Gauge SystemPrecise Reliable StrongFast and high accuracy Safe movement Resistance to crash Maintenance freeAdjustment availability at every pointFast, Efficient, ModernCNC optional back gauge X - RX - R - Z1, Z2X - R - Z1, Z2, Delta XXXZ1ZZ2RRCNC optional back gauge X1 - X2, R1 - R2, Z1 - Z2X2X1R1Z2R2Z12, 4, 5 or 6Axis Back GaugeCE Safety SystemModEva 15 T Control UnitTop BeamLED IlluminationCNC CrowningLinear Guided Front Support ArmsHydraulic SystemAD-Servo Series press brakes, designed with high technology to increase efficiency on precise part bending.Quality approved components used.Stress relieved made on bodies for long life and precise bending.General SpecificationsCNC back gauge X - R Z manuelTool Holders and ToolsBending performance increased using with high quality European clamping system and easy to use. Narrow table designed for European style tool holder and Z bending.DURMA is your solution partner with various tool options.European Clamping SystemWila Top Tool ClampingWila Bottom Tool ClampingEuropean Type Bottom Tool (4V Die)DURMA Multi V Bottom ToolDURMA Top ToolQuick Release ClampingManual or CNC-controlled motorized crowning system simplifies bending, by adjusting each point of the bending parts to acquire straight bends. The need for shimming is eliminated.Crowning SystemCNC Crowning SystemOur machines are designed in accordance with Ce-Norms to ensure your safety with hydraulic, electric, appropriate height covers and laser light curtains. CE safety in tandem machines are also provided with light barriers.CE Safety SystemsBy using long and planar guiding surfaces, all thedisadvantages of point guiding are eliminated 100% free bending space: guiding system that eliminates bending between frame has been moved to the outside of the frame.Stable Top Beam MovementLinear Guide Front Sheet SupportsRugged support arms with tilting stops are mountedon a linear guide rail system. This allows “finger-tip” lateral adjustment as required by the bend length of the part. They are also equipped with side gauges for the fast, easy, and accurate feeding of parts small or large.Linear Guide Front Sheet SupportsSafe and Accurate Bends with Top Quality EquipmentsFull 3D simulationMultiple view points while working3D collision detectionUser defined table for bend deduction Rapid solution computationImporting 3D models (MetaBEND, IGES) Automatic Tool Shape SelectionVideo-like bend simulation.Almost unlimited quantity of programs and sequences Higher grade of efficiency3D and 2D graphical touch screen programming mode 17" high resolution colour TFTMinimal set up timeDelem modusys compatabilitySensor bending correction interface1 GB memory capacityIntegrated OEM-Panel1280x1024 pixels, 16-bit colour3D graphics accelerationNow Bending is More Easier15" color Touch ScreenOn-screen finger profile drawingAutomatic bend listingVery simple and convenient data transferHigher productivity thanks to easy and rapidMulti-simulation capabilitySimulation criteria for better sheet management Windows XPe for multitasking and file management EC safety-cycle managementEthernet for easy communicationBundled Offline Software 2D graphical touch screen programming mode3D visualisation in simulation and production17" high resolution colour TFTFull Windows application suiteDelem modusys compatibilityUSB, peripheral interfacingUser specific application support within the controllers multitasking environmentSensor bending & correction interfaceModEva 15TModeva PremiumDA-69TDA-66T DURMA ANGLE MEASUREMENT AP3 - AP4 SHEET FOLLOWERROBOTIC SOLUTIONSStandard EquipmentY Y1, Y2, X, R (4-Axis) X=650mm X,R (AL - double gayt )DBEND 3D CAD/CAM Importing & Similation Program Control Unit - CNC ModEva15T or 66TCE BLVT safety – only for tandem machinesServo motor back gauge & linear guided & ballscrew system (X-R)CNC crowningEuropean style tool clamping systemSliding front arms (With T-Slot and stopper)World standards special design hydraulic block and valves World standard electric equipmentOptional EquipmentControl unit - ModEva Premium or 69TCE Manuel F. AKAS II M FPSC-B-C + safety covers with switch CE F. AKAS-LC II AKAS-3 M Motorized + FPSC (safety PLC)CE BLVT safety – only for tandem machines Z1, Z2 axis X1, X2 axis R1, R2 axisDelta X axis ± 125 mm with CNC Controlled X axis = 1000 mm – light barrier back protection AP3-AP4 sheet following systemHeight adjustable laser angle measurement system Quick release clamping systemHydraulic and pneumatic tool clamping systems Bottom and top toolsBottom tool separation system Parking areaCentral lubrication system Oil coolerAdditional back gauge finger and sliding front support arms Special packing for overseas shipmentsStandard & Optional EquipmentConsultancy Spare PartsR&D CenterServiceAgreementsTrainingAfter Sales ServiceSoftware Flexible SolutionSolution CenterDURMA provides the best level of service and spare parts with qualified personnel and spare parts in stock.Our experienced and professional service personnel are always ready at your service. Our professional training and application enriched courses will give you an advantage to use our machinery.Fast on Service and Spare PartsAD-Servo Serisi Teknik DetaylarS : Standard O : Option* 750 mm throat depth** 750 - 1000 - 1250 mm throat depthMachines set according to optimum values.Durmazlar Makina San. ve Tic. A.Ş.OSB 75. Yıl Bulvarı Nilüfer-Bursa / Türkiye P: +90 224 219 18 00 F: +90 224 242 75 80******************.tr .trEN_2018/04/V06。

条码电子计价秤ACS–FB技术手册中航第一集团太原航空仪表有限公司AVIC Ⅰ TAIYUAN AERO-INSTRUMENTS CO.,LTD简介 (3)第1章设置1.1设置标签参数 (6)1.2设置条码及打印参数 (7)1.3设置条码秤工作方式 (9)1.4设置PLU库允许编辑内容 (11)1.5设置通讯参数 (13)1.6查看各项库长度 (14)第2章测试2.1硬件测试 (16)2.2软件测试 (19)2.3互传信息 (22)第3章编辑3.1 PLU库编辑 (28)3.2快捷键编辑 (32)3.3说明文编辑 (33)3.4汉字串编辑 (34)3.5打印格式编辑 (35)3.6日期时间编辑 (39)3.7单价修改 (40)3.8删除PLU库 (41)3.9删除快捷键 (42)3.10删除说明文 (43)第4章统计4.1全天金额统计 (46)4.2按商品号码统计 (47)4.3按部门统计 (48)4.4按柜组统计 (49)第5章文本编辑5.1文本输入 (52)第6章管理软件6.1系统要求 (54)6.2安装说明 (54)6.3主要功能 (54)第7章通讯方式7.1 232通讯方式 (56)7.2 TCP/IP通讯方式 (56)第8章故障维修8.1故障维修 (58)第9章打印格式9.1 30×43套印标签 (60)9.2 60×37套印标签 (61)9.3 60×33套印标签 (62)9.4 35×37 90°旋转套印标签 (63)9.5 35×37 270°旋转套印标签 (64)附录A 特殊字符库 (65)附录B 汉字区位码 (66)ACS-FB型条形码电子计价秤是中航第一集团太原航空仪表有限公司最新研制开发的新一代用于超市及连锁店使用的条形码电子计价秤。

目前，条码技术已成为国际流行的一种自动识别技术，广泛应用于物品管理、货物流通等领域，在发达国家和地区已经普遍使用条码技术，而且正在迅速向世界各地推广。

TSM346220V N-Channel MOSFETSOT-26Features● Advance Trench Process Technology● High Density Cell Design for Ultra Low On-resistanceApplication● Load Switch ● PA SwitchOrdering InformationPart No.PackagePackingTSM3462CX6 RFSOT-263Kpcs / 7” ReelAbsolute Maximum Rating (Ta = 25o C unless otherwise noted)ParameterSymbolLimitUnitDrain-Source Voltage V DS 20 V Gate-Source VoltageV GS ±8 V Continuous Drain Current, V GS @4.5V. I D 5 A Pulsed Drain Current, V GS @4.5VI DM 20 A Continuous Source Current (Diode Conduction)a,bI S 0.72 A Ta = 25oC 1.25 Maximum Power Dissipation Ta = 75o CP D 0.8 WOperating Junction TemperatureT J +150 o C Operating Junction and Storage Temperature RangeT J , T STG-55 to +150oCThermal PerformanceParameterSymbolLimitUnitJunction to Case Thermal ResistanceR ӨJF 30 o C/W Junction to Ambient Thermal Resistance (PCB mounted) R ӨJA110oC/WNotes:a. Pulse width limited by the Maximum junction temperatureb. Surface Mounted on FR4 Board, t ≤ 5 sec.PRODUCT SUMMARY V DS (V) R DS(on)(m Ω)I D (A)33 @ V GS = 4.5V5.0 40 @ V GS = 2.5V 4.5 2051 @ V GS = 1.8V4.0Pin Definition: 1. Drain 6. Drain 2. Drain 5, Drain 3. Gate 4. SourceBlock DiagramN-Channel MOSFETTSM346220V N-Channel MOSFETElectrical Specifications (Ta = 25o C unless otherwise noted)ParameterConditionsSymbolMinTypMaxUnitStaticDrain-Source Breakdown Voltage V GS = 0V, I D = 250uA BV DSS 20 -- -- V Gate Threshold Voltage V DS = V GS , I D = 250uA V GS(TH) 0.5 -- 1.0 V Gate Body LeakageV GS = ±8V, V DS = 0V I GSS -- -- ±100 nA Zero Gate Voltage Drain Current V DS = 20V, V GS = 0V I DSS -- -- 1.0 uA On-State Drain CurrentV DS ≥10V, V GS = 4.5V I D(ON) 15 -- -- A V GS = 4.5V, I D = 5.0A -- 27 33 V GS = 2.5V, I D = 4.5A -- 33 40 Drain-Source On-State Resistance V GS = 1.8V, I D = 4.0A R DS(ON) -- 42 51 m Ω Forward Transconductance V DS = 5V, I D = 5.0A g fs -- 20 -- S Diode Forward Voltage I S = 1.0A, V GS = 0VV SD -- 0.8 1.2 V Dynamic bTotal Gate Charge Q g -- 11 14 Gate-Source Charge Q gs -- 1.4 -- Gate-Drain Charge V DS = 10V, I D = 3.6A, V GS = 4.5VQ gd -- 2.2 -- nC Input Capacitance C iss -- 500 -- Output CapacitanceC oss -- 300 -- Reverse Transfer Capacitance V DS = 10V, V GS = 0V, f = 1.0MHzC rss--140-- pFSwitching cTurn-On Delay Time t d(on) -- 15 25 Turn-On Rise Time t r -- 40 60 Turn-Off Delay Timet d(off)-- 48 70 Turn-Off Fall Time V DD = 10V, R L = 10Ω, I D = 1A, V GEN = 4.5V,R G = 6Ωt f --3145nSNotes:a. pulse test: PW ≤300µS, duty cycle ≤2%b. For DESIGN AID ONLY, not subject to production testing.b. Switching time is essentially independent of operating temperature.TSM346220V N-Channel MOSFETElectrical Characteristics Curve (Ta = 25o C, unless otherwise noted)Output CharacteristicsTransfer CharacteristicsOn-Resistance vs. Drain CurrentGate ChargeOn-Resistance vs. Junction TemperatureSource-Drain Diode Forward VoltageTSM346220V N-Channel MOSFETElectrical Characteristics Curve (Ta = 25o C, unless otherwise noted)On-Resistance vs. Gate-Source VoltageThreshold VoltageSingle Pulse PowerNormalized Thermal Transient Impedance, Junction-to-AmbientTSM346220V N-Channel MOSFETSOT-26 Mechanical DrawingMarking Diagram62 = Device Code Y = Year Code M = Month Code(A =Jan, B =Feb, C =Mar, D =Apl, E =May, F =Jun, G =Jul, H =Aug, I =Sep, J =Oct, K =Nov, L =Dec) L = Lot CodeSOT-26 DIMENSIONMILLIMETERS INCHES DIM MIN TYP MAX MIN TYPMAXA 0.95 BSC 0.0374 BSCA1 1.9 BSC 0.0748 BSCB 2.60 2.80 3.00 0.1024 0.1102 0.1181C 1.40 1.50 1.70 0.0551 0.0591 0.0669D 2.80 2.90 3.10 0.1101 0.1142 0.1220E 1.00 1.10 1.20 0.0394 0.0433 0.0472F 0.00 -- 0.10 0.000.0039 G 0.35 0.40 0.50 0.0138 0.0157 0.0197 H 0.10 0.15 0.20 0.0039 0.0059 0.0079 I 0.30 -- 0.60 0.0118 -- 0.0236 J5º--10º5º--10ºTSM346220V N-Channel MOSFETNoticeSpecifications of the products displayed herein are subject to change without notice. TSC or anyone on its behalf, assumes no responsibility or liability for any errors or inaccuracies.Information contained herein is intended to provide a product description only. No license, express or implied, to any intellectual property rights is granted by this document. Except as provided in TSC’s terms and conditions of sale for such products, TSC assumes no liability whatsoever, and disclaims any express or implied warranty, relating to sale and/or use of TSC products including liability or warranties relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright, or other intellectual property right.The products shown herein are not designed for use in medical, life-saving, or life-sustaining applications. Customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify TSC for any damages resulting from such improper use or sale.。

低功耗电源监控数据保护节能芯片Low Power Smart Supervisory IC概述中慧低功耗电源管理数据保护芯片ZH17X6具有-40℃～85℃ 的工业级工作温度、1.8V-5.5V的超宽工作电压以及最大不超过 50 µA的工作电流； 在系统上电、复位按键按下的情况下，芯片能够保证输出准确可靠的复位信号；其内部的看门狗电路能监视微处理器的运行，当 1.6 s内输入信号的状态没有改变时将发出复位信号；更加可靠的掉电监测功能。

在检测到掉电信号时迅速通知MCU保存数据并且控制复位信号延时发出，可以防止数据因掉电而丢失。

超宽的工作电压以及超低的工作电流使芯片格外适合于要求低功耗系统或使用电池供电系统，使ZH17X6系列芯片可以广泛应用在医疗电子、工控仪表和消费类便携式电子等产品上；高达4.5KV 的ESD 防护以及监测供电电源异常抖动并提供强制复位功能，大大提高系统工作的稳定性；所有功能集中在一颗8引脚的SOP封装上(封装尺寸为5mm*5mm)，性价比极高。

特性 ● 工作电压范围1.8V～5.5V （按型号级别，可分1.8V-5.5V,3.0V-5.5V） ● 复位持续时间为200ms　● 具有干扰信号处理能力● 100mV（毫伏）以内的干扰信号不产生复位信号　● 具有电源抖动处理能力 ● 1.6s内产生单一复位信号 ● 复位信号低电平有效 ● 看门狗的喂狗时间为1.6s ● 端口兼容TTL/COMS电平　● 工作温度范围/极限工作温度范围: -40℃～85℃ ● 典型工作电流低于15µA（5V） ● 低功耗静态保持状态电流低于1µA ● ESD性能大于4500VZH17X6应用 医疗电子 仪器仪表 汽车电子便携式及手持设备控制装置 微控制器系统采购信息版本 温度范围 电压范围 封装ZH1706 -40℃～85℃ 1.8V-3.6V 8-SOP ZH1716 -40℃～85℃ 1.8V-5.5V 8-SOP ZH1726 -40℃～85℃2.5V-5.5V8-SOP11-2; Rev 2; 03/27/09低功耗电源监控数据保护节能芯片Low Power Smart Supervisory IC引脚配置 2Z H 17X 6引脚说明引脚 名称 功能说明1喂狗信号。

技术数据PowerFlex 755TM 非再生电源系列号 20J主题第 ⻚简介3产品目录号说明3NRS 模块额定值说明6NRS 模块选型与系统额定值9NRS 系统配置11认证12环境技术参数12保护技术参数14电气技术参数14冲击事件15设计考量因素15控制变压器16近似功率损耗16降额指南18分⽀电路短路保护19机柜选件19符合 EN 61800-5-1 标准的污染等级19所需的机柜空气流量20便于操作和维修的最⼩安装间距21近似重量21附件252罗克⻙尔⾃动化出版物 750-TD103A-ZH-P - 2022年3 月罗克⻙尔⾃动化出版物 750-TD103A-ZH-P - 2022 年3 月3PowerFlex® 755TM 非再生电源 (NRS) 技术可提供精确的公共⺟线系统配置。

该技术融合了多项功能，可帮助优化系统，保持生产率。

PowerFlex 755TM 非再生电源具有如下一系列特性，可帮助⽤⼾最⼤程度提⾼生产率：•PowerFlex 755TM 变频器系统 — 精选一系列配置，可优化系统设计，并降低功耗。

NRS 系统具有设计灵活和安装成本低等优点。

•腐蚀性气体防护 (XT) — PowerFlex 755TM 产品目前均标配腐蚀性气体防护(XT)。

带 XT 的 NRS 产品将敷形涂覆与多项额外设计增强特性相结合，旨在提升在腐蚀性气体工况（例如轮胎和橡胶、废⽔处理、纸浆和纸张以及⾦属⾏业等）下的性能表现。

•NRS 模块推入、拉出式设计 — 使 NRS 系统易于安装和维修。

产品目录号说明本节介绍了基本 NRS 模块功率模块柜的产品目录号。

一个完整版 NRS 系统可以是单个功率模块柜，也可以是配备一个或多个接线柜的并联功率模块柜系统，如果采⽤了背靠背配置，还可以是两个直流电压平衡电源柜。

并联系统中的每个功率模块柜都有各⾃对应的产品目录号。

整个并联系统没有产品目录号。

产品目录号的第 1…7 位标识产品类型和电压等级。

Keysight TechnologiesCXA X-Series Signal Analyzer, Multi-touch N9000B9 kHz to 3.0, 7.5, 13.6, or 26.5 GHzData SheetThe CXA is today’s leading low-cost tool for essential signal characterization. Its capabilities provide a solid foundation for cost-effective testing in general-purpose and educational applications.Definitions and Conditions .................................................................3Frequency and Time Specifications ...................................................4Amplitude Accuracy and Range Specifications .................................6Dynamic Range Specifications ...........................................................8PowerSuite Measurement Specifications ........................................12Tracking Generator Specifications ...................................................1375 Ω Input Specifications .................................................................14General Specifications ......................................................................15Inputs and Outputs ...........................................................................16I/Q Analyzer ......................................................................................18Related Literature .. (18)Table of ContentsThis data sheet is a summary of the specifications and conditions for CXA signal analyzers. For the complete specifications guide, visit /find/cxa_specificationsFor more informationThis CXA signal analyzer data sheet is a summary of the complete specifications andconditions for N9000B CXA signal analyzers, which are available in the CXA Signal Analyzer Specification Guide. The CXA Signal Analyzer Specification Guide can be obtained on the web at:(w /find/cxa_specificationsDefinitions and ConditionsSpecifications describe the performance of parameters covered by the product warranty and apply to temperature ranges 0 to 55 °C, unless otherwise noted.95th percentile values indicate the breadth of the population (approx. 2s ) of performance tolerances expected to be met in 95 percent of the cases with a 95 percent confidence, for any ambient temperature in the range of 20 to 30 °C. In addition to the statistical observations of a sample of instruments, these values include the effects of theuncertainties of external calibration references. These values are not warranted. These values are updated occasionally if a significant change in the statistically observed behavior of production instruments is observed.Typical describes additional product performance information that is not covered by the product warranty. It is performance beyond specifications that 80 percent of the units exhibit with a 95 percent confidence level over the temperature range 20 to 30 °C. Typical performance does not include measurement uncertainty.Nominal values indicate expected performance, or describe product performance that is useful in the application of the product, but are not covered by the product warranty.The analyzer will meet its specifications when:–It is within its calibration cycle–Under auto couple control, except when Auto Sweep Time Rules = Accy–The analyzer has been stored at an ambient temperature within the allowedoperating range for at least two hours before being turned on; if it had previously been stored at a temperature range inside the allowed storage range, but outside the allowed operating range–The analyzer has been turned on at least 30 minutes with Auto Align set to Normal, or, if Auto Align is set to Off or Partial, alignments must have been run recently enough to prevent an Alert message. If the Alert condition is changed from “Time and Temperature” to one of the disabled duration choices, the analyzer may fail to meet specifications without informing the user. If Auto Align is set to Light, performance is not warranted, and nominal performance will degrade to become a factor of 1.4 wider for any specification subject to alignment, such as amplitude tolerances.For ordering information, refer to the CXA Signal Analyzer Configuration Guide (5992-1275EN).Frequency and Time SpecificationsDelta counter accuracy± (delta frequency x frequency reference accuracy + 0.141 Hz) Counter resolution0.001 Hz1. Horizontal resolution is span/(sweep points – 1).Frequency and Time Specifications (continued)Remote measurement and LAN transfer rate 6 ms (167/s) nominalMarker peak search 5 ms nominalCenter frequency tune and transfer22 ms nominalMeasurement/mode switching75 ms nominal1. Analysis bandwidth is the instantaneous bandwidth available around a center frequency over which the input signal can be digitized for further analysis orprocessing in the time, frequency, or modulation domain.2. Sweep points = 101.(P03, P07) 3 to 5.25 GHz± 0.85 dB5.25 to 7.5 GHz± 1.35 dBMW (Option 513, 526) (P03, P07, P13, P26)100 kHz to 3 GHz± 0.7 dB 3 to 13.6 GHz± 1.0 dB 13.6 to 19 GHz± 1.1 dB 19 to 26.5 GHz± 2.5 dBAmplitude Accuracy and Range SpecificationsAmplitude Accuracy and Range Specifications (continued)Option P07100 kHz to 7.5 GHzOption P13100 kHz to 13.6 GHzOption P26100 kHz to 26.5 GHz Gain100 kHz to 26.5 GHz+20 dB nominalNoise figure100 kHz to 26.5 GHz DANL + 176.24 dB nominalDynamic Range SpecificationsMW (Option 513, 526) 3.75 to 13.25 GHz+54 dBmThird-order intermodulation distortion (TOI) Parentheses indicate typical performanceRF (Option 503, 507)Preamp off(Two –20 dBm tones at input mixer spaced by100 kHz, 0 dB attenuation, 20 to 30 °C)10 to 400 MHz+10 (+14) dBm 400 MHz to 3 GHz+13 (+17) dBm 3 to 7.5 GHz+13 (+15) dBmMW (Option 513/526)Preamp off(Two –20 dBm tones at input mixer spaced by100 kHz, 0 dB attenuation, 20 to 30 °C)10 to 500 MHz+11 dBm, (+15) dBm 500 MHz to 2 GHz+12 dBm, (+15) dBm2 to3 GHz+11 dBm, (+15) dBm3 to 7.5 GHz+12 dBm, (+17) dBm 7.5 to 13.6 GHz+11 dBm, (+15) dBm 13.6 to 26.5 GHz+10 dBm, (+14) dBmOption P03/P07/P13/ P26Preamp on(Two –45 dBm tones at the preamp input, spaced by100 kHz, 0 dB attenuation, 20 to 30 °C)10 MHz to 26.5 GHz–8 dBm nominalDynamic Range Specifications (continued)Phase noise Offset Specification Typical Noise sidebands (20 to 30 °C, CF = 1 GHz)1 kHz 10 kHz 100 kHz 1 MHz 10 MHz –98 dBc/Hz–106 dBc/Hz–108 dBc/Hz–130 dBc/Hz–103 dBc/Hz–110 dBc/Hz–110 dBc/Hz–130 dBc/Hz–145 dBc/Hz nominalFigure 1. Nominal phase noise at different center frequencies for CXAPowerSuite Measurement SpecificationsRelative dynamic range (30 kHz RBW) 67.4 dB(72.7 dB typical) Absolute sensitivity−93.7 dBm(−99.7 dBm typical) Relative accuracy± 0.11 dB3GPP W-CDMA (2.515 MHz offset)Relative dynamic range (30 kHz RBW)73.4 dB(80.2 dB typical) Absolute sensitivity−91.7 dBm(−97.7 dBm typical) Relative accuracy± 0.11 dBTracking Generator Specifications1. Not available on microwave CXA (Option 513 or 526).Preamp on (Option P03/P07) (0 dB attenuation)1 MHz to 1.5 GHz < 1.4:1 nominal 1. Not available on microwave CXA (Option 513 or 526).75 Ω Input SpecificationsGeneral SpecificationsConnectorOutput amplitude Frequency BNC female, 50 Ω nominal≥ 0 dBm nominal10 MHz ± (10 MHz x frequency reference accuracy)Ext Ref InConnectorInput amplitude range Input frequencyFrequency lock range BNC female, 50 Ω nominal–5 to 10 dBm nominal10 MHz ± nominal± 5 x 10–6 of specified external reference input frequencyTrigger 1 inputConnectorImpedanceTrigger level range BNC female> 10 kΩ nominal –5 to 5 VTrigger 1 outputConnector Impedance Level BNC female 50 Ω nominal 5 V TTL nominalMonitor outputConnector FormatResolution VGA compatible, 15-pin mini D-SUBXGA (60 Hz vertical sync rates, non-interlaced) Analog RGB 1024 x 768Noise source drive +28 V (pulsed)Connector BNC female SNS Series noise sourceAnalog outConnector BNC female Inputs and OutputsUSB portsHost, super speed Standard Connector Output current HostStandard Connector Output current Device Standard Connector 2 ports (stacked with each other)Compatible with USB 3.0USB Type-A female 0.9 A1 port (stacked with LAN)USB 2.0USB Type-A female 0.5 ACompatible with USB 3.0USB Type-B femaleGPIB interface Connector GPIB codes IEEE-488 bus connectorSH1, AH1, T6, SR1, RL1, PP0, DC1, C1, C2, C3, C28, DT1, L4, C0 SA mode or I/Q analyzer 322.5 MHzConversion gain –4 to +7 dB (nominal) plus RF frequency response Bandwidth Low band High bandUp to 120 MHz (nominal)Up to 40 MHz (nominal)1. Not available on microwave CXA (Option 513 or 526).Inputs and Outputs (continued)I/Q Analyzer3.0 < f ≤ 7.510 to ≤ 254.7 ° 2.2 ° 7.5 < f ≤ 26.510 to ≤ 25 3.5 ° 1.0 °Data acquisition (B25 IF path)Time record lengthIQ analyzer4,000,000 IQ sample pairsSample rate90 MSa/sADC resolution14 BitsRelated LiteratureLiterature Pub number CXA Signal Analyzer N9000B - Configuration Guide5992-1275EN X-Series Signal Analyzers - Brochure5992-1316EN For more information or literature resources please visit the web:/find/cxaWebProduct page:/find/N9000BX-Series measurement applications:/find/X-Series_AppsX-Series signal analyzers:/find/X-SeriesThis information is subject to change without notice.© Keysight Technologies, 2016Published in USA, January 26, 20165992-1274ENFrom Hewlett-Packard through Agilent to KeysightFor more than 75 years, we‘ve been helping you unlock measurement insights. Our unique combination of hardware, software and people can help you reach your next breakthrough.Unlocking measurement insights since 1939.1939 THE FUTUREFor more information on KeysightTechnologies’ products, applications or services, please contact your local Keysight office. The complete list is available at:/find/contactus Americas Canada (877) 894 4414Brazil 55 11 3351 7010Mexico001 800 254 2440United States (800) 829 4444Asia Pacific Australia 1 800 629 485China800 810 0189Hong Kong 800 938 693India 1 800 11 2626Japan 0120 (421) 345Korea 080 769 0800Malaysia 1 800 888 848Singapore 180****8100Taiwan0800 047 866Other AP Countries (65) 6375 8100Europe & Middle East Austria 0800 001122Belgium 0800 58580Finland 0800 523252France 0805 980333Germany ***********Ireland 1800 832700Israel 1 809 343051Italy800 599100Luxembourg +32 800 58580Netherlands 0800 0233200Russia 8800 5009286Spain 800 000154Sweden 0200 882255Switzerland0800 805353Opt. 1 (DE)Opt. 2 (FR)Opt. 3 (IT)United Kingdom0800 0260637For other unlisted countries:/find/contactus(BP-01-01-16)/go/quality Keysight Technologies, Inc.DEKRA Certified ISO 9001:2008 Quality Management SystemmyKeysight/find/mykeysightA personalized view into the information most relevant to you.Three-Year Warranty/find/ThreeYearWarrantyKeysight’s committed to superior product quality and lower total cost of ownership. Keysight is the only test and measurement company with athree-year warranty standard on all instruments, worldwide. And, we provide a one-year warranty on many accessories, calibration devices, systems and custom products.Keysight Assurance Plans/find/AssurancePlansUp to ten years of protection and no budgetary surprises to ensure your instruments are operating to specification, so you can rely on accurate measurements.Keysight Infoline/find/serviceKeysight’s insight to best in class information management. Free access to your Keysight equipment company reports and e-library.Keysight Channel Partners/find/channelpartnersGet the best of both worlds: Keysight’s measurement expertise and product breadth, combined with channel partner convenience.cdma2000 is a US registered certification mark of the Telecommunications Industry Association.。

—1—E93512A78-TESony 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 V DD –0.5 to +7.0V •Input voltage V I –0.5 to V DD +0.5V •Output voltage V O –0.5 to V DD +0.5V •Operating temperature Topr –20 to +75°C •Storage temperature Tstg –55 to +150°C Recommended Operating Conditions •Supply voltage V DD +4.5 to +5.5V(standard +5.0)•Operating temperature Topr –20 to +75°CDescriptionThe CXD1186C is a CD-ROM decoder LSI.Features•Corresponds to CD-ROM, CD-I and CD-ROM XA formats.•Real time error correction. (Erasure correction using C2 pointer from CD player.)•Double speed playback.•Connection to standard SRAM up to 64 K bytes, as buffer memory, possible.Applications CD-ROM driver StructureSilicon gate CMOS ICCD-ROM DecoderCXD1186CQ CXD1186CR80 pin QFP (Plastic)80 pin LQFP (Plastic)CXD1186CQ/CRFor the availability of this product, please contact the sales office.—2—Block DiagramDATA BCLK C2PO LRCKH C L KX T L 2X T L 1H D B 0-7, PH M D SA D R QX A A CH A 0, 1X T CH I N T DB0–7A0–3INTV DDGNDBDB0–7, PBA0–15XRSTXWR XRD XCS H D B P X H W R X H R D X H C S X D R Q X H A CXMWR XMOE—3—Pin No.Symbol I/O Description CXD1186CQ CXD1186CR1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 2526 2728 29 30 31 32 33 34 35 36 37 38 39798012345678910111213141516171819202122232425262728293031323334353637INTGNDA0A1A2A3HMDSHA0HA1XHCSHINTGNDXHRDXHWRHDB0HDB1HDB2HDB3HDB4HDB5HDB6HDB7GNDHDBPXRSTHDRQXHACXTCADRQXAACBA0BA1V DDBA2BA3BA4BA5BA8BA7O—IIIIIIIIO—I/OI/OI/OI/OI/OI/OI/OI/OI/OI/O—I/OIOIIIOOO—OOOOOOInterrupt request signal to CPUGND pinCPU address signalCPU address signalCPU address signalCPU address signalHost mode select signalHost address signalHost address signalChip select negative logic signal from hostInterrupt request negative logic signal to hostGND pinData read strobe signal from host or to SCSI control ICData write strobe signal from host or to SCSI control ICHost data busHost data busHost data busHost data busHost data busHost data busHost data busHost data busGND pinError flag, Host data busReset negative logic signalData request positive logic signal to host. Or DMAacknowledge negative logic signal to SCSI control ICDMA acknowledge negative logic signal from host.Or data request positive logic signal from SCSI control ICTerminal count negative logic signalDMA request positive logic signal from ADPDMA acknowledge negative logic signal to ADPBuffer memory addressBuffer memory addressPower (+5 V) supply pinBuffer memory addressBuffer memory addressBuffer memory addressBuffer memory addressBuffer memory addressBuffer memory address—4—Pin No.Symbol I/O Description CXD1186CQ CXD1186CR40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 7879 803839404142434445464748495051525354555657585960616263646566676869707172737475767778BA8BA9GNDBA10BA11BA12BA13BA14BA15XMOEXMWRBDB0GNDBDB1BDB2BDB3BDB4BDB5BDB6BDB7BDBPXTL2XTL1GNDHCLKLRCKDATABCLKC2PODB0DB1DB2DB3V DDDB4DB5DB6DB7XCSXRDXWROO—OOOOOOOOI/O—I/OI/OI/OI/OI/OI/OI/OI/OOI—OIIIII/OI/OI/OI/O—I/OI/OI/OI/OIIIBuffer memory addressBuffer memory addressGND pinBuffer memory addressBuffer memory addressBuffer memory addressBuffer memory addressBuffer memory addressBuffer memory addressBuffer memory output enable negative logic signalBuffer memory write negative logic signalBuffer memory data busGND pinBuffer memory data busBuffer memory data busBuffer memory data busBuffer memory data busBuffer memory data busBuffer memory data busBuffer memory data busBuffer memory pointer data busCrystal oscillation circuit output pinCrystal oscillation circuit input pinGND pin1/2 frequency divided clock signal of XTL1LR clock from CD playerSerial data from CD playerBit clock from CD playerC2 pointer from CD playerCPU data busCPU data busCPU data busCPU data busPower (+5 V) supply pinCPU data busCPU data busCPU data busCPU data busChip select negative logic signal from CPUCPU strobe negative logic signal to read out this IC internalregisterCPU strobe negative logic signal to write in this IC internalregister—5—Electrical CharacteristicsDC characteristics(V DD=5 V±10 %, V SS=0 V, Topr=–20 to +75 °C) ItemInput voltage H level L levelTTL Schmitt hysterisisInput current of pull up input Input current of pull down inputOutput voltage H level L levelOpen drain output L level Oscillation cell H level input voltage L level Logic threshold valueFeedback resistanceOutput voltage H levelL levelSymbolV IH1V IL1(V t+)–(V t–)I ILI IHV OH1V OL1V OL2V IHV ILLV thR FBV OHV OLConditionsV IL=0 VV IH=V DDI OH=–2 mAI OL=4 mAI OL=4 mAV IN=V SS or V DDI OH=–1 mAI OL=1 mAMin.Typ.Max.Unit2.2V0.8V0.20.4V–40–100–240µA40100240µAV DD–0.8V0.4V0.4V0.7 V DD V0.3 V DD VV DD/2V250 k 1 M 2.5 MΩV DD/2VV DD/2V•Input pin with pull up resistance:XHCS, HA0, HA1, XTC•Input pin with pull down resistance:C2PO, HMDS, ADRQ•TTL Schmitt input pin:XRST•Open drain output pin:HINT•Two-way data bus always pulled up.•Oscillation cellInput:XTL1Output:XTL2I/O capacitance V DD=V I=0 V, f=1 MHzItem Input pin Output pin I/O pin SymbolC INC OUTC I/OMin.Typ.Max.91111UnitpFpFpF—6—AC characteristics(Ta=–20 to +75 °C, V DD=5 V±10 %, Output Load=50 pF, f≤24.576 MHz)1.CPU interface(1)Read(2)WriteA0 to 3XCSXRDDB0 to 7ItemAddress setup time (vs. XCS & XRD ↓)Address hold time (vs. XCS & XRD ↑)Data delay time (vs. XCS & XRD ↓)Data float time (vs. XCS & XRD ↑)Low level XRD pulse widthSymbolt SARt HRAt DRDt FRDt RRLMin.3020100Typ.Max.6010UnitnnnnnA0 to 3XCSXWRDB0 to 7ItemAddress setup time (vs. XCS & XWR ↓)Address hold time (vs. XCS & XWR ↑)Data setup time (vs. XCS & XWR ↑)Data hold time (vs. XCS & XWR ↑)Low level XWR pulse widthSymbolt SAWt HWAt SDWt HWDt WWLMin.3020401050Typ.Max.UnitnnnnnWhere & in the chart indicates logical multiplication.—7—2.Memory interface(1)Read(2)WriteBA0 to 15XMOEBDB0 to 7, PItemAddress setup time (vs. XMOE ↓)Address hold time (vs. XMOE ↑)Data setup time (vs. XMOE ↑)Data hold time (vs. XMOE ↑)Low level XMOE pulse widthSymbolt SAOt HOAt SDOt HODt RRLMin.Tw–22Tw–9452 • TwTyp.Max.2•Tw+16UnitnnnnnBA0 to 15XMWRBDB0 to 7, PItemAddress setup time (vs. XMWR ↓)Address hold time (vs. XMWR ↑)Data delay time (vs. XMWR ↓)Data float time (vs. XMWR ↑)Low level XMWR pulse widthSymbolt SAWt HWAt DWDt FWDt WWLMin.Tw–29Tw–9102 • TwTyp.Max.UnitnnnnnWhere Tw=1/f.Usually, when f=16.9344 MHz, use a RAM with access time within 120 ns.—8—3.Host interface(1)Read(2)WriteHA0 to 1XHCSXHRDHDB0 to 7, PItemAddress setup time (vs. XHCS & XHRD ↓)Address hold time (vs. XHCS & XHRD ↑)Data delay time (vs. XHCS & XHRD ↓)Data float time (vs. XHCS & XHRD ↑)Low level XHRD pulse widthSymbolt SARt HRAt DRDt FRDt RRLMin.3020100Typ.Max.6010UnitnnnnnHA0 to 1XHCSXHWRHDB0 to 7, PItemAddress setup time (vs. XHCS & XHWR ↓)Address hold time (vs. XHCS & XHWR ↑)Data setup time (vs. XHCS & XHWR ↑)Data hold time (vs. XHCS & XHWR ↑)Low level XHWR pulse widthSymbolt SAWt HWAt SDWt HWDt WWLMin.3020401050Typ.Max.Unitnnnnn—9——10—4.HOST DMA cycle (80 type bus)(1)Read(2)WriteHDRQXHACXHRDHDB0 to 7, PItemHDRQ fall time (vs. XHAC ↓)HDRQ rise time (vs. XHAC ↑)XHAC setup time (vs. XHRD ↓)XHAC hold time (vs. XHRD ↑)Low level XHRD pulse width Data delay time (vs. XHRD ↓)Data float time (vs. XHRD ↑)Symbol t DAR1t DAR2t SAR t HRA t RRL t DRD t FRDMin.501000Typ.Max.35486010Unit n n n n n n nHDRQXHACXHWRHDB0 to 7, PItemHDRQ fall time (vs. XHAC ↓)HDRQ rise time (vs. XHAC ↑)XHAC setup time (vs. XHWR ↓)XHAC hold time (vs. XHWR ↑)Low level XHWR pulse width Data setup time (vs. XHWR ↑)Data hold time (vs. XHWR ↑)Symbol t DAR1t DAR2t SAW t HWA t WWL t SDW t HWDMin.50504010Typ.Max.3548Unit n n n n n n n5.HOST DMA cycle (SCSI bus)(1)Read(2)WriteSDRQXSACXHRDHDB0 to 7, PItemXSAC fall time (vs. SDRQ ↑)XSAC delay time (vs. XHRD ↓)XSAC delay time (vs. XHRD ↑)Low level XHRD pulse widthData delay time (vs. XHRD ↓)Data hold time (vs. XHRD ↑)Symbolt DDAt DARt DRAt RRLt DRDt HRDMin.T+59Typ.Max.TwTw90UnitnnnnnnSDRQXSACXHWRHDB0 to 7, PItemXSAC fall time (vs. SDRQ ↑)XHWR delay time (vs. XSAC ↓)XSAC delay time (vs. XHWR ↑)Low level XHWR pulse widthData setup time (vs. XHWR ↓)Data float time (vs. XHWR ↓)Symbolt DDAt DAWt DWAt WWLt SDWt FWDMin.TT+2427Typ.Max.TwTwTwUnitnnnnnnWhere T in the chart indicates :Tw for 3 cycle mode2 • Tw for 4 cycle mode3 • Tw for 5 cycle modeHere Tw=1/f—11——12—6.ADPCM DMA cycleWhere T in the chart indicates :Tw for 3 cycle mode 2 • Tw for 4 cycle mode 3 • Tw for 5 cycle modeHere Tw=1/f 7.XTL1 and XTL2 pins (1)For self oscillation(Topr=–20 to +75 °C, V DD =5.0 V±10 %)(2)When a pulse is input to XTL1(Topr=–20 to +75 °C, V DD=5.0 V±10 %)ADRQ XAAC XHWR ItemXAAC fall time (vs. ADRQ ↑)XHWR delay time (vs. XAAC ↓)XAAC delay time (vs. XHWR ↑)Low level XHWR pulse width Data setup time (vs. XHWR ↓)Data float time (vs. XHWR ↓)Symbol t DDA t DAW t DWA t WWL t SDW tFWDMin.T T+2427Typ.Max.Tw Tw TwUnit n n n n n nt ILXV IHX V IHX X0.9V IHX X0.1V DD/2XTL1Item“H” level pulse width “L” level pulse width Pulse period Input “H” level Input “L” levelRise time, Fall timeSymbol t WHX t WLX t W V IHX V ILX t R , t FMin.151540.7V DD —1.0Typ.Max.0.815Unit ns ns ns V V nsItemOscillation frequencySymbol f MAXMin.16.9344Typ.Max.24.576Unit MHzDescription of Function1.Pin descriptionBelow is a description of pins by function.1.1CD player interface (4 pins)(1)DATA (input)Serial data from CIRC LSI (digital signal processing LSI for CD)(2)BCLK (input)Bit clock. Clock for DATA Strobe.(3)LRCK (input)LR clock. Indicates L CH and R CH of DATA input.(4)C2PO (positive logic input)C2 pointer signal from CIRC. Indicates an error is included in the DATA input.Interface mode with the CD player is controlled at DRVIF register.1.2Buffer memory interface (27 pins)(1)XMWR (memory write, negative logic output)Data write strobe signal of the buffer memory.(2)XMOE (memory output enable, negative logic output)Data read strobe signal of the buffer memory.(3)BA0 to 15 (Buffer memory address, output)Address signal of the buffer memory.(4)BDB0 to 7 (Buffer data bus, I/O)Data bus signal of the buffer memory.(5)BDBP (Buffer data bus, I/O)Buffer memory data bus signal for error pointer.1.3CPU interface (16 pins)(1)XWR (CPU write, negative logic input)Write strobe signal of the CPU register.(2)XRD (CPU read, negative logic input)Read out strobe signal of the CPU register.(3)XCS (CPU chip select, negative logic input)Chip select negative logic signal from the CPU.(4)A0 to 3 (CPU address, input)Address signal for the CPU selection of the IC internal register.(5)DB0 to 7 (CPU data bus, I/O)CPU data bus signal.(6)INT (CPU interrupt, output)Interrupt request output to the CPU. This pin polarity is controlled at the CONFIG register.1.4Host interface (19 pins)(1)HMDS (Host mode select, input)Signal for the host mode selection. This pin is pulled down inside the IC by means of a resistor at a standard 50 kΩ.“L” or open:connected to Intel 80 type host Bus.“H”:connected to SCSI controller IC.(2)HDRQ/XSAC (Host data request/SCSI acknowledge, output)When HMDS is at “L”, DMA data request positive logic signal to host.When HMDS is at “H”, DMA acknowledge negative logic signal to SCSI control IC.—13—(3)XHAC/SDRQ (Host DMA acknowledge/SCSI data request, input)When HMDS is at “L”, DMA acknowledge negative logic signal from host.When HMDS is at “H”, DMA data request positive logic signal from SCSI control IC.(4)XHWR (Host write, negative logic I/O)When HMDS is at “L” and ADMAEN (DMACTL register, bit4) also at “L”, data write strobe input from host.When HMDS is at “H” and ADMAEN at “L”, data write strobe output to SCSI control IC.When ADMAEN is at “H”, data write strobe output to audio processor (ADP).(5)XHRD (Host read, negative logic I/O)When HMDS is at “L” and ADMAEN also at “L”, data read strobe input from host.When HMDS is at “H” and ADMAEN at “L”, data read strobe output to SCSI control IC.When ADMAEN is at “H”, data read strobe output to ADP.(6)XHCS (Host chip select, negative logic input)This pin is pulled up inside the IC by means of a resistor at a standard 50 kΩ.When HMDS is at “L”, chip select input from host.When HMDS is at “H”, this signal is not used. Either fix to “H” or keep open.(7)HA0 and 1 (Host address, input)These pins are pulled up inside the IC by means of a resistor at a standard 50 kΩ.When HMDS is at “L”, address input from the host.When HMDS is at “H”, these signals are not used. Either fix to “H” or keep open.(8)HDB0 to 7 (Host data bus, I/O)Host data bus signal.(9)HDBP (Host data bus, I/O)Host data bus signal for error pointer.(10)HINT (HOST interrupt, output)This pin is an open drain output.When HMDS is at “L”, interrupt request negative logic output to host.When HMDS is at “H”, this signal is not used.(11)XTC (Terminal count, negative logic output)This is pulled up inside the IC by means of a resistor at a standard 50 kΩ.When HMDS is at “L”, data transfer complete instruction negative logic input from the host.When HMDS is at “H”, this signal is not used. Either fix to “H” or keep open.1.5Audio processor (ADP) interface (2 pins)(1)ADRQ (audio processor DMA request, positive logic input)This pin is pulled down inside the IC by means of a resistor at a standard 50 kΩ.DMA data request signal to ADP. When not connected to ADP and CXD1186Q, either fix to “L” or keep open.(2)XAAC (audio processor DMA acknowledge, negative logic output)DMA acknowledge signal from ADP.1.6Others (4 pins)(1)XTL1 (Crystal1, input)(2)XTL2 (Crystal2, output)Crystal oscillator connecting pin for master clock oscillation.(3)HCLK (halfclock, output)Half frequency divided clock of the master clock.(4)XRST (Reset, negative logic input)Chip reset signal.Pins BDB0 to 7, BDBP, DB0 to 7, HDB0 to 7 and HDBP are pulled up inside the IC by means of a resistor at a standard 25 kΩ.—14—2.Register functionThis IC is controlled from the CPU by means of 19 registers for each of write and read, respectively.2.1Write register2.1.1Drive Interface (DRVIF) registerbit0:DIGIN (Digital IN)“H”;When Digital In (See fig. 2.1.1) is connected, this bit is set to “H”.“L”;When connected to CIRC LSI, this bit is set to “L”.bits 2 to 5 are effective only when DIGIN is at “L”.bit1:LSB1ST (LSB First)“H”;When data is connected to CIRC LSI output through LSB first, this bit is set to “H”.“L”;When data is connected to CIRC LSI output through MSB first, this bit is set to “L”.bits2 and 3:BCKMD 0, 1 (BCLK mode 0, 1)These bits are set according to the number of BCLK clocks output during one word by CIRC LSI.BCKMD 1BCKMD 0“L”“L”16BCLKs/Word“L”“H”24BCLKs/Word“H”“X”32BCLKs/WordMoreover, when there are 24 or 32 clocks within 1 word, the 16 bits of data before LRCK edge, become effective.bit4:BCKRED (BCLK Rising Edge)“H”;Data is strobed with BCLK rise.“L”;Data is strobed with BCLK fall.bit5:LCHLOW (LCH LOW)“H”;When LRCK is at “L”, it is determined to be L CH data.“L”;When LRCK is at “H”, it is determined to be L CH data.∗1.When DIGIN=“H”, We automatically have LSBIST=BCKMD1=“H”, BCKRED=LCHLOW=“L”.bit6:DBLSPD (Double Speed)“H”;At double speed PB, this bit is set to “H”.“L”;At normal speed PB, this bit is set to “L”.bit7:C2PLIST (C2PO Lower-byte 1st)“H”;When 2 bytes of data are input to C2PO, the Lower-byte and the upper-byte are input in the order.“L”;When 2 bytes of data are input to C2PO, the Upper-byte and the lower-byte are input in the order. Table 2.1.1 indicates the setting value of bits 0 to 7 when Sony-made CIRC LSI is connected. Fig. 2.1.1 (1) to (4) indicates the input timing chart.Here, the upper byte means the upper 8 bits including MSB from CIRC LSI, Lower byte indicates the lower 8 bits including LSB from CIRC LSI.Changes in value for the respective bits in this register have to be executed in the decoder disable condition.—15——16—CXD1186CQ/CRLRCKBCLK DATARch Validity FLAGRch LSB Rch • MSBL0RVR15R14R13R12R11R10R9R8R7R6R5R4R3R2R1R0LV1234567891011121314151617181920212223242526272829303132Fig. 2.1.1 (1) Digital In Timing Chart (C2PO don’t care, no need for connection)LRCKBCLK DATAC2PORch LSBLch MSBLch • LSBC2 Pointer for Upper byteC2 Pointer for Lower byteR0L15L14L13L12L11L10L9L8L7L6L5L4L3L2L1L0123456789101112131415161718192021222324Fig. 2.1.1 (2) CDL30, 35 Series, Timing Chart—17—CXD1186CQ/CRLRCKBCLK DATAC2PORch LSBLch MSBLch LSBC2 Pointer for Upper byteC2 Pointer for Lower byteR1R0L15L14L13L12L11L10L9L8L7L6L5L4L3L2L1L0123456789101112131415161718192021222324Fig. 2.1.1 (3) CXD2500Q, 48 bit Slot Mode Timing Chart1234567891011121314151617181920212223242526272829303132LRCKBCLK DATAC2PO Lch MSBRch LSBRch MSBL14L15R0R1R2R3R4R5R6R7R8R9R10R11R12R13R14R15C2 Pointer for Upper byte C2 Pointer for Lower byteFig. 2.1.1 (4) CXD2500Q, 64 bit Slot Mode Timing Chart—18—Table 2.1.1 DRVIF Register setting value(Note 1)∗at normal speed PB set to “L”, at double speed PB set to “H”.(Note 2)2.1.2Decoder Control (DECCTL) register bits0 to 2:DECMDSL2, 1, 0(Decoder Mode Select 2, 1, 0)DECMDSL210“L”“L”“X”Decoder disable “L”“H”“X”Monitor only mode “H”“L”“L”Write only mode “H”“L”“H”Real time correction mode “H”“H”“L”Repeat correction mode “H”“H”“H”CD-DA modebit3:AUTODIST (Auto Distinction)“H”;Error Correction performed according to the Mode byte and FORM bit read from Drive.“L”;Error Correction is performed according to the following MODESEL and FORMSEL bits.bit4:FORMSEL (Form Select)bit5:MODESEL (Mode Select)When AUTODIST is at “L” the sector is corrected as the following MODE or FORM.MODESEL FORMSEL“L”“L”MODE1“H”“L”MODE2, FORM1“H”“H”MODE2, FORM2bit6:ECCSTR (ECC Strategy)“H”;Error Correction is performed with consideration to respective data error flag.“L”;Error Correction is performed without consideration to respective data error flag. When an 8bit/Word RAM is connected, turn this bit to “L”.bit7:ENDLADR (Enable DLADR)“H”;When this bit is set to “H”, DLADR is enabled.When, either write only mode, real time correction, or CD-DA mode is being executed, the decoder stops the buffer write as DADRC and DLADR turn equal.“L”;When this bit is set to “L”, DLADR is disabled.During the execution of write only mode or real time correction, even if DADRC and DLADR turn equal, the decoder does not stop buffer write.(See paragraph 4 for details)Sony-made CIRC LSI CDL30 series CDL35 series CDL40 series (48 bit slot mode)CDL40 series (64 bit slot mode)DRV IF Register bit7bit6bit5bit4bit3bit2bit1bit0L ∗L L L H L L L ∗L H L H L L L∗HLHXHLTiming chart Fig. 2.1.1 (2)Fig. 2.1.1 (3)Fig. 2.1.1 (4)CDL30 seriesCDL35 series CDL40 seriesCXD1125Q/QZ, CXD1130Q/QZ, CXD1135Q/QZ,CXD1241Q/QZ, CXD1245Q, CXD1246Q/QZ,CXD1247Q/QZ/R and others.CXD1165Q, CXD1167Q/QZ/R and others.CXD2500Q/QZ and others.2.1.3DMA Control (DMACTL) registerbit0:HSRC (Host Source)“H”;Data is transferred from the host to the buffer memory.“L”;Data is transferred from the buffer memory to the host.bit1:HDMAEN (HOST DMA Enable)“H”;DMA of the host port is enabled.“L”;DMA of the host port is prohibited.bit2:ENXTC (Enable XTC)“H”;DMA completion of the host port through XTC pin input is enabled.“L”;DMA completion of the host port through XTC pin input is disabled.bit3:ENHXFRC (Enable XHFRC)“H”;DMA completion of the host port through HXFRC is enabled.“L”;DMA completion of the host port through HXFRC is disabled.bit4:ADMAEN (ADP DMA Enable)“H”;DMA of the audio processor port is enabled.“L”;DMA of the audio processor port is prohibited.Also, prohibits turning HDMAEN and ADMAEN simultaneously to “H”.bit5:CSRC (CPU Source)“H”;Data is transferred from the CPU to the buffer memory.“L”;Data is transferred from the buffer memory to the CPU.bit6:CDMAEN (CPU DMA Enable)“H”;DMA of the CPU port is enable.“L”;DMA of the CPU port is prohibited.bit7:RESERVEDUnused, Keep set to “L”.2.1.4Configuration (CONFIG) registerbit0:RESERVEDUnused, Keep set to “L”.bits1 and 2:SDMACYC1, 0 (SCSI DMA CYCLE)DMA transfer between this IC, SCSI control IC and ADPCM processor is executed in thefollowing cycle.SDMACYC10“L”“L” 3 cycle.“L”“H” 4 cycle.“H”“X” 5 cycle.bit3:SBSCTL (SCSI Bus Control)Setting this bit to “H” forces XHWR, XHRD, HDB0 to 7 and HDBP into high impedance condition. bit4:CINTPOSI (CPU Interrupt Positive)“H”;INT pin turns to High active.“L”;INT pin turns to Low active.bit5:9 BITRAM“H”;When a 9 bit/word RAM is connected, this bit is turned to “H”.“L”;When a 8 bit/word RAM is connected, this bit is turned to “L”.bits6 and 7:RESERVEDUnused, Keep set to “L”.—19—2.1.5Interrupt Mask (INTMSK) registerTurning the respective bits of the register to “H” enables interrupt request from this IC to the CPU by means of the corresponding interrupt status. (That is, when interrupt status is turned on, INT pin is activated) The value of the respective bits in this register does not affect the corresponding interrupt status.bit0:DECINT (Decoder interrupt)When the Decoder is executing one of the respective modes, write only, monitor, or real timecorrection, if Sync mark is detected or introduced, DECINT status is turned on. However, WhenSync detection window is open, if sync interval is less than 2352 bytes, Decint status is notturned on.Also, when Decoder repeat correction mode is being executed, everytime one correction iscompleted DECINT status is turned on.bit1:HDMACMP (Host DMA Complete)When DMA of the host port is completed through HXFRC or XTC pins, HDMACMP status isturned on.bit2:DRVOVRN (Drive Over Run)When ENDLADR bit (bit7) of DECCTL register is set to “H”, and the DECODER has executedwrite only, real time correction mode or CD-DA mode, as DADRC and DLADR become equal,DRVOVRN status is turned on.However, in CD-DA mode, even when ENDLADR bit is turned to “L”, DRVOVRN status is turnedon.bit3:HSTCMND (Host Command)As the host writes a command in the Command register, HSTCMND status is turned on.bit4:HCRISD (Host Chip Reset Issued)By having the host write “H” in CHPRST bit (bit7) of the Control register, this IC is reset andHCRISD status is turned on.bit5:RSLTEMPT (Result Empty)When the host reads the Result register, and the Result register becomes empty, RSLTEMPTstatus turns on.bit6:DECTOUT (Decoder Timeout)After setting the Decoder to either, monitor only, write only or real time correction modes, if, evenafter the time of three sectors (normal speed PB 40.6 ms) passes, sync is not detected, thenDECTOUT status is turned on.2.1.6Clear Interrupt Status (INTCLR) registerWhen any of the respective bits of this register is set to “H”, the corresponding interrupt status is cleared. After the interrupt status clearance, the bit automatically turns to “L”. Accordingly there is no need for the CPU to set to “L” again.bit0:DECINT (Decoder Interrupt)bit1:HDMACMP (Host DMA Complete)bit2:DRVOVRN (Drive Over Run)bit3:HSTCMND (Host Command)bit4:HCRISD (Host Chip Reset Issued)bit5:RSLTEMPT (Result Empty)bit6:DECTOUT (Decoder Timeout)2.1.7Drive • Last • Address • Low (DLADR-L) register—20—2.1.8Drive • Last • Address • High (DLADR-H) registerWhen the Decoder is executing either of write only, real time correction mode or CD-DA mode, CPU sets the last address that writes into the buffer, data from the drive. When ENDLADR bit of DECCTL register is set to “H” and the Decoder is executing the above modes, if data from the drive is written into the buffer at the address specified from DLADR, all writing into the buffer is prohibited after that.2.1.9Drive • Address • Low (DADRC-L) counter2.1.10Drive • Address • Counter High (DADRC-H)This counter keeps the address that writes data from the drive into the buffer. When drive data is written into the buffer, DADRC contents are output form BA0 to 15. For every byte written in the buffer, DADRC is incremented. Before the Decoder executes either write only, real time correction mode or CD-DA mode, CPU sets the buffer write head address to DADRC.This counter can also be used as the DMA address of the CPU port. During DMA execution of the CPU port, DADRC contents are output from BA0 to 15, DADRC is incremented at every byte of DMA execution.CPU can read or set DADRC contents at any time. Do not alter DADRC contents during either write only, real time correction or CD-DA mode and the DMA execution of CPU port.2.1.11Host • Address • Low (HADRC-L) counter2.1.12Host • Address • High (HADRC-H) counterThis counter keeps the address that writes data from the host into the buffer or reads from the buffer. During execution of the host port DMA, HADRC contents are output from BA0 to 15. The counter is incremented at every DMA of the host port.Before execution of the host port DMA, CPU sets the DMA head address to HADRC.CPU can read or set HADRC contents at any time, Do no alter HADRC contents during host port DMA execution.2.1.13Host • Transfer • Low (HXFRC-1) counter2.1.14Host • Transfer • High (HXFRC-H) counterThis counter indicates the number of host port DMA transfers. It is decremented at every host port DMA. When ENHXFRC bit (bit3) of DMACTL register is set to “H” and HXFRC value turns to 0, the host port DMA is disabled. At that time it is possible to send an interrupt request from this IC to the CPU.CPU can read and set HXFRC contents at any time. Do not alter HXFRC contents during Host port DMA execution.2.1.15Chip Control (CHPCTL) registerbit0:CPUBWPO (CPU Buffer Write Pointer)Sets the pointer value for CPU port DMA (buffer write).bit1:CHPRST (Chip Reset)Setting this bit to “H” initializes the interior of this IC. After the initialization of the interior of this IC iscompleted, this bit automatically turns to “L”. Accordingly it is not necessary to set the CPU to “L”. bit2:SWOPN (Sync Window Open)“H”;Setting this bit to “H” opens the window to allow for SYNC Mark detection. Sync protection circuit inside this IC is disabled.“L”;Setting this bit to “L” controls the window through the sync protection circuit inside the IC.bit3:RPSTART (Repeat Correction Start)Setting the Decoder to repeat correction mode and this bit to “H” starts the sector errorcorrection. As correction starts, this bit automatically turns to “L”. Accordingly it is not necessaryto set the CPU to “L”.bits4 to 7:Do not fail to set to “L”. If set to “H” IC operation is not guaranteed.—21—。