Spectrum Brands MC.31XX Dynamic Parameters, Order information, IntroductionHardware information

Page 13

IntroductionHardware information

Dynamic Parameters

 

MC.3110

MC.3112

MC.3120

MC.3122

MC.3130

MC.3132

 

MC.3111

 

 

MC.3121

 

 

MC.3131

 

 

Test - Samplerate

1

MS/s

1

MS/s

10 MS/s

10 MS/s

25 MS/s

25 MS/s

Testsignal frequency

90 kHz

90 kHz

1

MHz

1

MHz

1

MHz

1

MHz

SNR (typ)

> 67.5 dB

> 66.9 dB

> 64.9 dB

> 64.9 dB

> 63.1 dB

> 62.4 dB

THD (typ)

< -62.8 dB

< -62.8 dB

< -62.5 dB

< -62.5 dB

< -62.5 dB

< -62.5 dB

SFDR (typ), excl harm.

> 80.8 dB

> 80.5 dB

> 80.5 dB

> 78.5 dB

> 79.5 dB

> 79.3 dB

SINAD (typ)

> 61.5 dB

> 61.4 dB

> 60.5 dB

> 60.5 dB

> 59.8 dB

> 59.4 dB

ENOB (based on SINAD)

> 9.9 LSB

> 9.9 LSB

> 9.8 LSB

> 9.8 LSB

> 9.6 LSB

> 9.6 LSB

Dynamic parameters are measured at ± 1 V input range (if no other range is stated) and 50 Ohm termination with the samplerate specified in the table. Measured parameters are aver- aged 20 times to get typical values. Test signal is a pure sine wave of the specified frequency with > 99% amplitude. SNR and RMS noise parameters may differ depending on the quality of the used PC. SNR = Signal to Noise Ratio, THD = Total Harmonic Distortion, SFDR = Spurious Free Dynamic Range, SINAD = Signal Noise and Distortion, ENOB = Effective Number of Bits. For a detailed description please see application note 002.

Order information

Order No

Description

 

Order No

Description

MC3110

MC.3110 with 8 MSample memory and drivers/SBench 5.x

 

MC3xxx-16M

Option: 16 MSample memory instead of 8 MSample standard mem

MC3111

MC.3111 with 8 MSample memory and drivers/SBench 5.x

 

MC3xxx-32M

Option: 32 MSample memory instead of 8 MSample standard mem

MC3112

MC.3112 with 8 MSample memory and drivers/SBench 5.x

 

MC3xxx-64M

Option: 64 MSample memory instead of 8 MSample standard mem

MC3120

MC.3120 with 8 MSample memory and drivers/SBench 5.x

 

MC3xxx-128M

Option: 128 MSample memory instead of 8 MSample standard mem

MC3121

MC.3121 with 8 MSample memory and drivers/SBench 5.x

 

MC3xxx-256M

Option: 256 MSample memory instead of 8 MSample standard mem

MC3122

MC.3122 with 8 MSample memory and drivers/SBench 5.x

 

MC3xxx-up

Additional handling costs for later memory upgrade

MC3130

MC.3130 with 8 MSample memory and drivers/SBench 5.x

 

 

 

MC3131

MC.3131 with 8 MSample memory and drivers/SBench 5.x

 

MC3xxx-mr

Option Multiple Recording: Memory segmentation

MC3132

MC.3132 with 8 MSample memory and drivers/SBench 5.x

 

MC3xxx-gs

Option Gated Sampling: Gate signal controls acquisition

 

 

 

MC3xxx-dig

Additional 4 synchronous digital inputs per channel, incl. cable

MC3xxx-smod

Star Hub: Synchronisation of 2 - 16 boards, one option per system

 

 

 

MC3xxx-time

Timestamp option: Extra memory for trigger time

 

MC31xx-dl

DASYLab driver for MC.31xx series

MCxxxx-xmf

Extra I/O, external connector: 24 DI/O, 4 Analog out, incl. cable

 

MC31xx-hp

VEE driver for MC.31xx series

 

 

 

MC31xx-lv

LabVIEW driver for MC.31xx series

MC3xxx-cs

Synchronisation of 2 - 4 boards, one option per system

 

MATLAB

MATLAB driver for all MI.xxxx, MC.xxxx and MX.xxxx series.

Cab-3f-9m-80

Adapter cable: SMB female to BNC male 80 cm

 

Cab-3f-9f-80

Adapter cable: SMB female to BNC female 80 cm

Cab-3f-9m-200

Adapter cable: SMB female to BNC male 200 cm

 

Cab-3f-9f-200

Adapter cable: SMB female to BNC female 200 cm

 

 

 

 

 

(c) Spectrum GmbH

13

Page 12 Page 14
Image 13
Page 12 Page 14
Contents English version April 27 MC.31xxPage Software Driver Installation Hardware InstallationIntroduction SoftwareProgramming the Board Fifo ModeAnalog Inputs Standard acquisition modesOption Gated Sampling Option Multiple RecordingOption Timestamp Option Extra I/OPreface IntroductionGeneral Information PrefaceMC.3110 MC.3120 MC.3130 MC.3111 MC.3121 MC.3131 Different models of the MC.31xx seriesIntroduction MC.3112 MC.3122 MC.3132 Digital inputs Additional optionsExtra I/O Option -XMF Introduction Additional optionsTimestamp StarhubSpectrum type plate Hardware information Block diagram Technical DataOrder information Dynamic ParametersIntroductionHardware information Order No DescriptionInstalling the board in the system Hardware InstallationSystem Requirements Installing a board with extra I/O Option -XMF Installing a board with digital inputs/outputsHardware Installation Mounting the wired boards Installing multiple boards synchronized by starhubHooking up the boards Only use the included flat ribbon cablesInstalling multiple synchronized boards Interrupt Sharing Software Driver InstallationInterrupt Sharing Software Driver Installation Windows InstallationWindows Version controlDriver Update Windows Driver Update Windows XP Software Driver InstallationWindows XP Windows NT Software Driver Installation Windows NTAdding boards to the Windows NT driver Overview LinuxNow it is possible to access the board using this device Installing the deviceDriver info Automatic load of the driverSoftware Overview SoftwareFirst Test with SBench Software OverviewHeader files ++ Driver InterfaceMicrosoft Visual C++ Borland C++ BuilderNational Instruments LabWindows/CVI Other Windows C/C++ compilersDriver functions Include DriversFunction SpcSetParam Software ++ Driver Interface Using the Driver under LinuxFunction SpcSetParam Function SpcSetData WindowsType definition Delphi Pascal Programming InterfaceInclude Driver ExamplesSoftware Visual Basic Examples Visual Basic Programming InterfaceVBA for Excel Examples Visual Basic Programming Interface Programming the Board Error handlingOverview Register tablesInitialization Example for error checkingStarting the automatic initialization routine PCI RegisterInstalled features and options Installed memoryHardware version Date of productionUsed type of driver Used interrupt lineProgramming the Board Initialization Driver versionExample program for the board initialization Powerdown and resetSpcpcimemsize SpcpciserialnoChannel Selection Analog InputsImportant note on channels selection Analog InputsRerouting information for module Channel reroutingSPCCHROUTE0 SPCCHROUTE1Input ranges Setting up the inputsRegister Value Direction Description Offset range Input offsetOverrange bit Automatical adjustment of the offset settingsInput termination Spcadjsave ADJUSER0 Spcadjautoadj AdjallProgramming Standard acquisition modesMemory, Pre- and Posttrigger Pretrigger = memsize posttriggerCommand register Starting without interrupt classic modeMaximum posttrigger in MSamples Minimum memsize and posttrigger in samplesStandard acquisition modes Programming Starting with interrupt driven modeStatus register Fast 8 bit mode Normal mode201100 Enables the fast 8 bit mode Data organizationReading out the data with SpcGetData Standard modeValue ’start’ as a 32 bit integer value Value ’len’ as a 32 bit integer valueProgramming General Information Fifo ModeBackground Fifo Read Speed LimitationsSoftware Buffers Programming Fifo ModeTheoretical maximum sample rate PCI Bus Throughput 60040 Read out the number of available Fifo buffersBuffer processing Fifo Mode ProgrammingAnalog acquisition or generation boards Digital I/O 701x or 702x or pattern generator boardsFifo acquisition example Example Fifo acquisition modeSpcfifostart SpcfifowaitSample format Internally generated sample rate Clock generationStandard internal sample rate Maximum internal sample rate in MS/s normal mode Using plain quartz without PLLExternal reference clock Clock generationDirect external clock External clockingMinimum external sample rate Maximum external samplerate in MS/sCHANNEL0 CHANNEL1 CHANNEL2 CHANNEL3 External clock with dividerFifo General Description Trigger modes and appendant registersSoftware trigger External TTL triggerEdge triggers Example on how to set up the board for positive TTL triggerTrigger modes and appendant registers Positive TTL triggerPositive and negative TTL trigger Pulsewidth triggersTTL pulsewidth trigger for long High pulses TTL pulsewidth trigger for short High pulsesTTL pulsewidth trigger for short LOW pulses TTL pulsewidth trigger for long LOW pulsesSpctriggermode Tmttlhighlp SpcpulsewidthOverview of the channel trigger registers Channel TriggerSpctriggermode Tmchannel TmchxoffSpctriggermode Tmchor TriggerlevelSPCTRIGGERMODE0 Tmchxoff SPCTRIGGERMODE2 TmchxoffSPCTRIGGERMODE0 Tmchxpos Reading out the number of possible trigger levelsSPCHIGHLEVEL0 Input ranges Triggerlevel ±50 mV ±100 mV ±200 mV ±500 mVChannel trigger on positive edge Detailed description of the channel trigger modesChannel trigger on negative edge Channel trigger on positive and negative edgeChannel pulsewidth trigger for long negative pulses Channel pulsewidth trigger for long positive pulsesChannel pulsewidth trigger for short negative pulses Channel pulsewidth trigger for short positive pulsesTmchxposgsp Channel steepness trigger for flat negative pulses Channel steepness trigger for flat positive pulsesChannel steepness trigger for steep negative pulses Channel steepness trigger for steep positive pulsesChannel window trigger for leaving signals Channel window trigger for entering signalsChannel window trigger for long outer signals Channel window trigger for long inner signalsChannel window trigger for short outer signals Channel window trigger for short inner signalsWhen using Multiple Recording pretrigger is not available Standard ModeOption Multiple Recording Recording modesTrigger modesOption Multiple Recording Resulting start delaysSpcmemsize SpctriggermodeOption Gated Sampling General information and trigger delayOption Gated Sampling SpcgateAlignement samples per channel End of gate alignementAllowed trigger modes Number of samples on gate signalOption Gated SamplingTrigger modes External TTL edge triggerExample program Option Gated Sampling Example programChannel trigger Spctriggermode TmttlposOption Timestamp StartReset modeTimestamp modes LimitsFunctions for accessing the data RefClock mode optionalTimestamp Status Reading out timestamp dataSpcGetData nr, ch, start, len, data Data formatSpctimestampcount Example programs Standard acquisition modeAcquisition with Multiple Recording Digital I/Os Option Extra I/OAnalog Outputs Channel directionProgramming example Option Extra I/O Programming exampleOption Digital inputs Bit Standard Mode Digital Inputs enabledSample format SpcreaddigitalDifferent synchronization options Synchronization OptionSynchronization with option cascading Synchronization with option starhubSet up the board parameters Setup order for the different synchronization optionsLet the master calculate it’s clocking Write Data to on-board memory output boards onlyDefine the boards for trigger master Example for data writingExample of board #2 set as trigger master 4a Define synchronization or triggerExample board number 0 is clock master Define the board for clock masterDefine the remaining boards as clock slaves Arm the boards for synchronizationWait for the end of the measurement Start all of the trigger master boardsRead data from the on-board memory acquisition boards only Restarting the board for another synchronized run2a Write first data for output boards Example of Fifo buffer allocationSpcsyncmasterfifo SpcsyncslavefifoGeneral information Additions for synchronizing different boards20xx 30xx 31xx 40xx 45xx 60xx 61xx 70xx 72xx Calculating the clock dividersBoard type 3122 3120 Setting up the clock divider40 MS/s Board type 3025 3131Delay in standard non Fifo modes Resulting delays using different boards or speedsDelay in Fifo mode Additions for equal boards with different sample ratesError Codes Error CodesError name Value hex Value dec Error description AppendixExtra I/O with external connectorOption -XMF Pin assignment of the multipin connectorOption Digital inputs Pin assignment of the multipin cable
Top Page Image Contents