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M2p 汎用デジタイザ

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M2p.59xx 16ビット、20MS/s, 40MS/s, 80MS/s, 125MS/s、1~8チャネル

1/2/4/8チャネル
入力抵抗  1MΩ/50Ω
チャネル毎に独立した16ビットADおよびアンプ
全チャネル同時サンプリング
6入力レンジ:±200mV~±10 V
トリガ:Window、パルス幅、スパイク、OR/AND
測定モード:Streaming、ABA、マルチレコード、ゲートレコード、Time stamp他
PCとの接続:PcIe gen1 x4

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ドキュメント名 M2p 汎用デジタイザ
ドキュメント種別 製品カタログ
ファイルサイズ 1Mb
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取り扱い企業 株式会社エレクトロニカ IMT事業部 (この企業の取り扱いカタログ一覧)

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SPECTRUM INSTRUMENTATION
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株式会社エレクトロニカ IMT事業部

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M2p 汎用デジタイザ M2p.59xx 16ビット、20MS/s, 40MS/s, 80MS/s, 125MS/s、1~8チャネル 1/2/4/8チャネル 入力抵抗 1MΩ/50Ω チャネル毎に独立した16ビットADおよびアンプ 全チャネル同時サンプリング 6入力レンジ:±200mV~±10 V トリガ:Window、パルス幅、スパイク、OR/AND 測定モード:Streaming、ABA、マルチレコード、ゲートレコード、Time stamp他 PCとの接続:PcIe gen1 x4 製品名 分解能 入力チャネル サンプリングレート 帯域 M2p.5920-x4 16 1 20MS/s 10MHz M2p.5921-x4 16 2 20MS/s 10MHz M2p.5922-x4 16 4 20MS/s 10MHz M2p.5926-x4 16 4 20MS/s 10MHz M2p.5923-x4 16 8 20MS/s 10MHz M2p.5930-x4 16 1 40MS/s 20MHz M2p.5931-x4 16 2 40MS/s 20MHz M2p.5932-x4 16 4 40MS/s 20MHz M2p.5936-x4 16 4 40MS/s 20MHz M2p.5934-x4 16 8 40MS/s 20MHz
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製品名 分解能 入力チャネル サンプリングレート 帯域 M2p.5940-x4 16 1 80MS/s 40MHz M2p.5941-x4 16 2 80MS/s 40MHz M2p.5942-x4 16 4 80MS/s 40MHz M2p.5946-x4 16 4 80MS/s 40MHz M2p.5943-x4 16 8 80MS/s 40MHz M2p.5960-x4 16 1 125MS/s 60MHz M2p.5961-x4 16 2 125MS/s 60MHz M2p.5962-x4 16 4 125MS/s 60MHz M2p.5966-x4 16 4 125MS/s 60MHz M2p.5968-x4 16 4 125MS/s(4チャネル) 60MHz 8 80MS/s(8チャネル)
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M2p.59xx-x4 - 16 bit general purpose Digitizer • Up to 125 MS/s on four or 80 MS/s on eight channels • Ultra Fast PCI Express x4 interface Speed SNR ENOB20 MS/s up to 81.0 dB up to 13.2 LSB • Simultaneously sampling on all channels 40 MS/s up to 75.3 dB up to 12.2 LSB • Separate dedicated 16 bit ADC and amplifier per channel 80 MS/s up to 74.2 dB up to 12.0 LSB • 6 input ranges: ±200 mV up to ±10 V 125 MS/s up to 73.3 dB up to 11.8 LSB • 512 MSamples (1 GByte) on-board memory • Window, re-arm, OR/AND trigger • Synchronization of up to 16 cards per system • Features: Single-Shot, Streaming, Multiple Recording, Gated Sampling, ABA, Timestamps • Direct data transfer to CUDA GPU using SCAPP option • PCIe x4 Gen 1 Interface • Works with x4/x8/x16 PCIe slots • Sustained streaming mode up to 700 MB/s • Half-length PCIe Form Factor Operating Systems Recommended Software Drivers • Windows 7, 8, 10 • Visual C++, Delphi, C++ Builder, • MATLAB • Linux Kernel 2.6, 3.x, 4.x GNU C++, VB.NET, C#, J#, Java, • LabVIEW • Windows/Linux 32 and 64 bit Python • LabWindows/CVI • SBench 6 • IVI single-ended channels true differential channels General Information (non-isolated) Model 1 ch 2 ch 4 ch 8 ch 1 ch 2 ch 4 ch The M2p.59xx series allows recording of up to M2p.5920-x4 20 MS/s (OEM version) 20 MS/s (OEM version) eight Single-Ended channels or up to four differen- M2p.5921-x4 20 MS/s 20 MS/s 20 MS/s 20 MS/s tial channels both with sampling rates of up to M2p.5922-x4 20 MS/s 20 MS/s 20 MS/s 20 MS/s 20 MS/s 125 MS/s. These PCI Express cards offer outstand- M2p.5926-x4 20 MS/s 20 MS/s 20 MS/s 20 MS/s 20 MS/s 20 MS/s M2p.5923-x4 20 MS/s 20 MS/s 20 MS/s 20 MS/s 20 MS/s 20 MS/s 20 MS/s ing A/D features both in resolution and speed. M2p.5930-x4 40 MS/s (OEM version) 40 MS/s (OEM version) The cards can be switched between Single-Ended M2p.5931-x4 40 MS/s 40 MS/s 40 MS/s 40 MS/s inputs with a programmable offset and true differen- M2p.5932-x4 40 MS/s 40 MS/s 40 MS/s 40 MS/s 40 MS/s tial inputs. If used in differential mode each two M2p.5936-x4 40 MS/s 40 MS/s 40 MS/s 40 MS/s 40 MS/s 40 MS/s inputs are connected together reducing the number M2p.5933-x4 40 MS/s 40 MS/s 40 MS/s 40 MS/s 40 MS/s 40 MS/s 40 MS/s of available channels by half. M2p.5940-x4 80 MS/s 80 MS/s Importantly, the high-resolution 16-bit ADCs deliver M2p.5941-x4 80 MS/s 80 MS/s 80 MS/s 80 MS/s sixteen times more resolution than digitizers using M2p.5942-x4 80 MS/s 80 MS/s 80 MS/s 80 MS/s 80 MS/s older 12-bit technology and 256 times more resolu- M2p.5946-x4 80 MS/s 80 MS/s 80 MS/s 80 MS/s 80 MS/s 80 MS/s M2p.5943-x4 80 MS/s 80 MS/s 80 MS/s 80 MS/s 80 MS/s 80 MS/s 80 MS/s tion than what is available from digital scopes that M2p.5960-x4 125 MS/s 125 MS/s commonly use 8-bit ADCs. M2p.5961-x4 125 MS/s 125 MS/s 125 MS/s 125 MS/s All boards of the M2p.59xx series may use the M2p.5962-x4 125 MS/s 125 MS/s 125 MS/s 125 MS/s 125 MS/s whole installed on-board memory of up to M2p.5966-x4 125 MS/s 125 MS/s 125 MS/s 125 MS/s 125 MS/s 125 MS/s 512 MSamples, completely for the currently activat- M2p.5968-x4 125 MS/s 125 MS/s 125 MS/s 80 MS/s 125 MS/s 125 MS/s 125 MS/s ed number of channels.SPECTRUM INSTRUMENTATION GMBH · AHRENSFELDER WEG 13-17 · 22927 GROSSHANSDORF · GERMANY 26.2.2019 PHONE: +49 (0)4102-6956-0 · FAX: +49 (0)4102-6956-66 · E-MAIL: info@spec.de · INTERNET: www.spectrum-instrumentation.com
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Software Support data de-multiplexing, data conversion or FFT. All the software is based on C/C++ and can easily be implemented, expanded and Windows drivers modified with normal programming skills. The cards are delivered with drivers for Windows 7, Windows 8 and Windows 10 (each 32 bit and 64 bit). Programming exam- Hardware features and options ples for Visual C++, C++ Builder, LabWindows/CVI, Delphi, Visu- al Basic, VB.NET, C#, J#, Python, Java and IVI are included. PCI Express x4 The M2p series cards use a PCI Express Linux Drivers x4 Gen 1 connection. They can be used All cards are delivered with full Linux support. Pre com- in PCI Express x4, x8 and x16 slots with piled kernel modules are included for the most common hosts supporting Gen 1, Gen 2 or Gen 3. distributions like Fedora, Suse, Ubuntu LTS or Debian. The The maximum sustained data transfer rate Linux support includes SMP systems, 32 bit and 64 bit is more than 700 MByte/s (read direction) or TBD MByte/s (write systems, versatile programming examples for GNU C++, direction) per slot. Physically supported slots that are electrically Python as well as the possibility to get the driver sources for your connected with only x1 or x2 can also be used with the M2p series own compilation. cards, but with reduced data transfer rates. Connections SBench 6 The cards are equipped with SMB connectors for the an- A base license of SBench 6, the alog signals as well as for the external trigger and clock easy-to-use graphical operating input. In addition, there are four MMCX connectors: one software for Spectrum cards, is in- multi-function output (X0) and three multi-function I/O cluded in the delivery. The base li- connectors (X1, X2, X3). These multi-function connectors cense makes it is possible to test can be individually programmed to perform different the card, display acquired data functions: and make some basic measure- ments. It's a valuable tool for • Clock output (X0 only) checking the card’s performance • Trigger output and assisting with the unit’s initial • Status output (armed, triggered, ready, ...) setup. The cards also come with a demo license for the SBench 6 • Synchronous digital inputs, being stored inside the analog data professional version. This license gives the user the opportunity to samples test the additional features of the professional version with their • Asynchronous I/O lines hardware. The professional version contains several advanced • Logic trigger inputs measurement functions, such as FFTs and X/Y display, import and export utilities as well as support for all acquisition modes including data streaming. Data streaming allows the cards to continuously ac- Input Amplifier quire data and transfer it directly to the PC RAM or hard disk. The analog inputs can be adapt- SBench 6 has been optimized to handle data files of several ed to real world signals using a GBytes. SBench 6 runs under Windows as well as Linux (KDE, wide variety of settings that are GNOME and Unity) operating systems. A test version of SBench 6 individual for each channel. By can be downloaded directly over the internet and can run the pro- using software commands the in- fessional version in a simulation mode without any hardware in- put termination can be changed stalled. Existing customers can also request a demo license for the between 50 Ohm and 1 MOhm, one can select a matching input professional version from Spectrum. More details on SBench 6 can range and the signal offset can be compensated for. be found in the SBench 6 data sheet. Differential inputs Third-party products With a simple software command the inputs can individually be Spectrum supports the most popular third-party software products switched from single-ended (in relation to ground) to differential by such as LabVIEW, MATLAB or LabWindows/CVI. All drivers come combining each two single-ended inputs to one differential input. with detailed documentation and working examples are included in When the inputs are used in differential mode the A/D converter the delivery. Support for other software packages, like VEE or Da- measures the difference between two lines with relation to system syLab, can also be provided on request. ground. SCAPP – CUDA GPU based data processing Automatic on-board calibration For applications requiring All of the channels are calibrated in factory before the board is high powered signal and shipped. To compensate for different variations like PC power sup- data processing Spectrum ply, temperature and aging, the software driver provides routines offers SCAPP (Spectrum’s for an automatic onboard offset and gain calibration of all input CUDA Access for Parallel ranges. All the cards contain a high precision on-board calibration Processing). The SCAPP reference. SDK allows a direct link between Spectrum digitiz- Digital inputs ers and CUDA based This option acquires additional syn- GPU cards. Once in the chronous digital channels phase- GPU users can harness the processing power of the GPU’s multiple stable with the analog data. As de- (up to 5000) processing cores and large (up to 24 GB) memories. fault a maximum of 3 additional SCAPP uses an RDMA (Linux only) process to send data at the dig- digital inputs are available on the front plate of the card using the itizers full PCIe transfer speed to the GPU card. The SDK includes a multi-purpose I/O lines. set of examples for interaction between the digitizer and the GPU card and another set of CUDA parallel processing examples with easy building blocks for basic functions like filtering, averaging,
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Ring buffer mode fast digitizer. The exact position of the trigger events is stored as The ring buffer mode is the timestamps in an extra memory. standard mode of all oscillo- scope instruments. Digitized Timestamp data is continuously written The timestamp function into a ring memory until a writes the time positions of trigger event is detected. After the trigger, post-trigger samples are the trigger events in an extra recorded and pre-trigger samples can also be stored. The number memory. The timestamps are of pre-trigger samples available simply equals the total ring mem- relative to the start of record- ory size minus the number of post trigger samples. ing, a defined zero time, ex- ternally synchronized to a radio clock, an IRIG-B a GPS receiver. FIFO mode Using the external synchronization gives a precise time relation for The FIFO or streaming mode is designed for continuous data trans- acquisitions of systems on different locations. fer between the digitizer card and the PC memory. When mounted in a PCI Express x4 Gen 1 interface read streaming speeds of up External clock input and output to 700 MByte/s are possible. The control of the data stream is done Using a dedicated connector a sampling clock can be fed in from automatically by the driver on interrupt request basis. The complete an external system. Additionally it’s also possible to output the in- installed onboard memory is used to buffer the data, making the ternally used sampling clock on a separate connector to synchro- continuous streaming process extremely reliable. nize external equipment to this clock. Channel trigger Reference clock The digitizers offer a wide variety of trigger modes. These include The option to use a precise a standard triggering mode based on a signals level and slope, like external reference clock that found in most oscilloscopes. It is also possible to define a win- (typically 10 MHz) is nec- dow mode, with two trigger levels, that enables triggering when essary to synchronize the signals enter or exit the window. Each input has its own trigger cir- instrument for high-quality cuit which can be used to setup conditional triggers based on logi- measurements with external equipment (like a signal source). It’s cal AND/OR patterns. All trigger modes can be combined with a also possible to enhance the stability of the sampling clock in this re-arming mode for accurate trigger recognition even on noisy sig- way. The driver automatically generates the requested sampling nals. clock from the fed in reference clock. External trigger input Star-Hub All boards can be triggered using an external analog or digital sig- The Star-Hub is an additional mod- nal. The external trigger input has one comparator that can be used ule allowing the phase stable syn- for standard edge and level triggers. chronization of up to 16 boards in one system. Two versions are avail- Multiple Recording able: one with up to 6 cards and The Multiple Recording the large version supports up to 16 mode allows the recording of cards in one system. Both versions several trigger events with an can be mounted in two different extremely short re-arming ways, to either extend the cards time. The hardware doesn’t length to ¾ PCIe length occupying one slot, or extend its width to need to be restarted in be- two slots whilst keeping the ½ PCIe length. tween. The on-board memory is divided in several segments of the same size. Each of them is filled with data if a trigger event occurs. Independent of the number of boards Pre- and posttrigger of the segments can be programmed. The num- there is no phase delay between all ber of acquired segments is only limited by the used memory and channels. The Star-Hub distributes trigger is unlimited when using FIFO mode. and clock information between all boards. As a result all connected boards Gated Sampling are running with the same clock and the same trigger. All trigger sources can be The Gated Sampling mode combined with OR/AND allowing all allows data recording con- channels of all cards to be trigger source trolled by an external gate at the same time. signal. Data is only record- ed if the gate signal has a programmed level. In addi- External Amplifiers tion a pre-area before start For the acquisition of extreme- of the gate signal as well as a post area after end of the gate signal ly small voltage levels with a can be acquired. The number of gate segments is only limited by high bandwidth a series of ex- the used memory and is unlimited when using FIFO mode. ternal amplifiers is available. Each of the one channel am- ABA mode plifiers is working with a fixed input impedance and allows - The ABA mode com- depending on the bandwidth bines slow continuous - to select different amplifica- data recording with fast tion levels between x10 (20 acquisition on trigger dB) up to x1000 (60 dB). Us- events. The ABA mode ing the external amplifiers of the SPA series voltage levels in the uV works like a slow data and mV area can be acquired. logger combined with a
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Technical Data Analog Inputs Resolution 16 bit (can be reduced to acquire simultaneous digital inputs) Input Range software programmable ±200 mV, ±500 mV, ±1 V, ±2 V, ±5 V, ±10 V Input Type software programmable Single-ended or True Differential Input Offset (single-ended) software programmable programmable to ±100% of input range in steps of 1% ADC Differential non linearity (DNL) ADC only 592x: ±0.2/±0.8 LSB (typ./max.) 593x: ±0.5/±0.9 LSB (typ./max.) 594x: ±0.5/±0.9 LSB (typ./max.) 596x: ±0.5/±0.9 LSB (typ./max.) ADC Integral non linearity (INL) ADC only 592x: ±1.0/±2.3 LSB (typ./max.) 593x: ±2.0/±7.5 LSB (typ./max.) 594x: ±2.0/±7.5 LSB (typ./max.) 596x: ±2.0/±7.5 LSB (typ./max.) Offset error (full speed), DC signal after warm-up and calibration ≤ 0.1% of range Gain error (full speed), DC signal after warm-up and calibration ≤ 0.1% of reading AC accuracy 1 kHz signal ≤ 0.3% of reading AC accuracy 50 kHz signal ≤ 0.5% of reading Crosstalk: Signal 1 MHz, 50 Ω range ≤ ±1V ≤ 95 dB on adjacent channels range ≥ ±2V ≤ 90 dB on adjacent channels Crosstalk: Signal 10 MHz, 50 Ω range ≤ ±1V ≤ 87 dB on adjacent channels range ≥ ±2V ≤ 85 dB on adjacent channels Analog Input impedance software programmable 50 Ω /1 MΩ || 30 pF Analog input coupling fixed DC Over voltage protection range ≤ ±1V ±5 V (1 MΩ), 3.5 Vrms (50 Ω) Over voltage protection range ≥ ±2V ±50 V (1 MΩ), 5 Vrms (50 Ω) CMRR (Common Mode Rejection Ratio) range ≤ ±1V 100 kHz: 75 dB, 1 MHz: 60 dB, 10 MHz: 40 dB CMRR (Common Mode Rejection Ratio) range ≥ ±2V 100 kHz: 55 dB, 1 MHz: 52 dB, 10 MHz: 50 dB Channel selection (single-ended inputs) software programmable 1, 2, 4 or 8 channels (maximum is model dependent) Channel selection (true differential inputs) software programmable 1, 2 or 4 channels (maximum is model dependent) Trigger Available trigger modes software programmable Channel Trigger, External, Software, Window, Pulse, Re-Arm, Spike, Or/And, Delay Channel trigger level resolution software programmable 16 bit Trigger edge software programmable Rising edge, falling edge or both edges Trigger pulse width software programmable 0 to [4G - 1] samples in steps of 1 sample Trigger delay software programmable 0 to [4G - 1] samples in steps of 1 samples Trigger holdoff (for Multi, ABA, Gate) software programmable 0 to [4G - 1] samples in steps of 1 samples Multi, ABA, Gate: re-arming time < 24 samples (+ programmed pretrigger + programmed holdoff ) Pretrigger at Multi, ABA, Gate, FIFO software programmable 8 up to [32 kSamples / number of active channels] in steps of 8 Posttrigger software programmable 8 up to [8G - 4] samples in steps of 8 (defining pretrigger in standard scope mode) Memory depth software programmable 8 up to [installed memory / number of active channels] samples in steps of 8 Multiple Recording/ABA segment size software programmable 8 up to [installed memory / number of active channels] samples in steps of 8 Internal/External trigger accuracy 1 sample Timestamp modes software programmable Standard, Startreset, external reference clock on X1 (e.g. PPS from GPS, IRIG-B) Data format Std., Startreset: 64 bit counter, increments with sample clock (reset manually or on start) RefClock: 24 bit upper counter (increment with RefClock) 40 bit lower counter (increments with sample clock, reset with RefClock) Extra data software programmable none, acquisition of X1/X2/X3 inputs at trigger time, trigger source (for OR trigger) Size per stamp 128 bit = 16 bytes External trigger Ext X1, X2, X3 External trigger type Single level comparator 3.3V LVTTL logic inputs External trigger impedance software programmable 50 Ω / 5 kΩ For electrical specifications refer to External trigger input level ±5 V (5 kΩ), ±2.5 V (50 Ω), „Multi Purpose I/O lines“ section. External trigger over voltage protection ±20 V (5 kΩ), 5 Vrms (50 Ω) External trigger sensitivity 200 mVpp (minimum required signal swing) External trigger level software programmable ±5 V in steps of 1 mV External trigger bandwidth 50 Ω DC to 400 MHz n.a. 5 kΩ DC to 300 MHz DC to 125 MHz Minimum external trigger pulse width ≥ 2 samples ≥ 2 samples
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Multi Purpose I/O lines (front-plate) Number of multi purpose output lines one, named X0 Number of multi purpose input/output lines three, named X1, X2, X3 Multi Purpose line X0 X1, X2, X3 Input: available signal types software programmable n.a. Asynchronous Digital-In, Synchronous Digital-In, Timestamp Reference Clock, Logic trigger Input: signal levels n.a. 3.3 V LVTTL Input: impedance n.a. 10 kΩ to 3.3 V Input: maximum voltage level n.a. -0.5 V to +4.0 V Input: maximum bandwidth n.a. 125 MHz Output: available signal types software programmable Run-, Arm-, Trigger-Output, Run-, Arm-, Trigger-Output, Asynchronous Digital-Out, Asynchronous Digital-Out ADC Clock Output, Output: impedance 50 Ω Output: drive strength Capable of driving 50 Ω loads, maximum drive strength ±48 mA Output: type / signal levels 3.3V LVTTL, TTL compatible for high impedance loads Output: update rate (synchronous modes) sampling clock Clock Clock Modes software programmable internal PLL, external clock, external reference clock, sync Internal clock range (PLL mode) software programmable see „Clock Limitations and Bandwidth“ table below Internal clock accuracy ≤ ±1.0 ppm (at time of calibration in production) Internal clock aging ≤ ±0.5 ppm / year PLL clock setup granularity (int. or ext. reference) 1 Hz External reference clock range software programmable 128 kHz up to 125 MHz Direct external clock to internal clock delay 4.3 ns Direct external clock range see „Clock Limitations and Bandwidth“ table below External clock type Single level comparator External clock input level ±5 V (5 kΩ), ±2.5 V (50 Ω), External clock input impedance software programmable 50 Ω / 5 kΩ External clock over voltage protection ±20 V (5 kΩ), 5 Vrms (50 Ω) External clock sensitivity 200 mVpp (minimum required signal swing) External clock level software programmable ±5 V in steps of 1mV External clock edge rising edge used External reference clock input duty cycle 45% - 55% Clock output electrical specification Available via Multi Purpose output X0. Refer to „Multi Purpose I/O lines“ section. Synchronization clock multiplier „N“ for software programmable N being a multiplier (1, 2, 3, 4, 5, ... Max) of the card with the currently slowest sampling clock. different clocks on synchronized cards The card maximum (see „Clock Limitations and Bandwidth“ table below) must not be exceeded. ABA mode clock divider for slow clock software programmable 8 up to (64k - 8) in steps of 8 Channel to channel skew on one card < 200 ps (typical) Skew between star-hub synchronized cards TBD Connectors Analog Inputs SMB male (one for each single-ended input) Cable-Type: Cab-3f-xx-xx Trigger Input SMB male Cable-Type: Cab-3f-xx-xx Clock Input SMB male Cable-Type: Cab-3f-xx-xx Multi Purpose I/O MMCX female (4 lines) Cable-Type: Cab-1m-xx-xx Environmental and Physical Details Dimension (Single Card) 168 mm (½ PCIe length) x 107 mm x 20 mm (single slot width) Dimension 168 mm (½ PCIe length) x 107 mm x 40 mm (double slot width) (Card with option -SH6tm or -SH16tm installed) Dimension 245 mm (¾ PCIe length) x 107 mm x 20 mm (single slot width) (Card with option -SH6ex or -SH16ex installed) Weight (M2p.59xx series) maximum 215 g Weight (Star-Hub Option -SH6ex, -SH6tm) including 6 sync cables 65 g Weight (Star-Hub Option -SH16ex, -SH16tm) including 16 sync cables 90 g Warm up time 10 minutes Operating temperature 0 °C to 40 °C Storage temperature -10 °C to 70 °C Humidity 10% to 90% PCI Express specific details PCIe slot type x4, Generation 1 PCIe slot compatibility (physical) x4, x8, x16 PCIe slot compatibility (electrical) x1, x4, x8, x16, Generation 1, Generation 2, Generation 3 Sustained streaming mode > 700 MB/s (measured with a chipset supporting a TLP size of 256 bytes, using PCIe x4 Gen1) (Card-to-System: M2p.59xx)
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Certification, Compliance, Warranty EMC Immunity Compliant with CE Mark EMC Emission Compliant with CE Mark Product warranty 5 years starting with the day of delivery Software and firmware updates Life-time, free of charge Power Consumption 3.3V 12V Total M2p.59x0, 59x1, 59x2 0.1 A 1.1 A 13.6 W M2p.59x3, 59x6, 59x8 0.1 A 1.5 A 18.4 W MTBF MTBF TBD hours
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Clock Limitations and Bandwidth M2p.592x, M2p.593x M2p.594x M2p.596x DN2.592-xx DN2.593-xx DN2.596-xx DN6.592-xx DN6.593-xx DN6.596-xx max internal clock (non-synchronized cards) 20 MS/s 40 MS/s 80 MS/s 125 MS/s min internal clock (non-synchronized cards) 1 kS/s 1 kS/s 1 kS/s 1 kS/s max internal clock (cards synchronized via star-hub) 20 MS/s 40 MS/s 80 MS/s 125 MS/s min internal clock (cards synchronized via star-hub) 128 kS/s 128 kS/s 128 kS/s 128 kS/s max direct external clock 20 MS/s 40 MS/s 80 MS/s 125 MS/s min direct external clock 1 MS/s 1 MS/s 1 MS/s 1 MS/s -3 dB analog input bandwidth > 10 MHz > 20 MHz > 40 MHz > 60 MHz RMS Noise Level (Zero Noise), typical figures M2p.592x, DN2.592-xx, DN6.592-xx Input Range ±200 mV ±500 mV ±1 ±2 V ±5 V ±10 V Voltage resolution 6.1 µV 15.3 µV 30.5 µV 61.0 µV 152.6 µV 305.2 µV 50 Ω <4.0 LSB <25 µV <2.6 LSB <40 µV <2.1 LSB <65 µV <4.3 LSB <263 µV <2.6 LSB <397 µV <2.1 LSB <641 µV 1 MΩ <4.5 LSB <28 µV <3.0 LSB <46 µV <2.5 LSB <107 µV <4.5 LSB <275 µV <3.0 LSB <458 µV <2.5 LSB <763 µV M2p.593x, DN2.593-xx, DN6.593-xx Input Range ±200 mV ±500 mV ±1 ±2 V ±5 V ±10 V Voltage resolution 6.1 µV 15.3 µV 30.5 µV 61.0 µV 152.6 µV 305.2 µV 50 Ω <6.0 LSB <37 µV <5.0 LSB <77 µV <4.5 LSB <138 µV <6.5 LSB <397 µV <5.0 LSB <763 µV <4.5 LSB <1.4 mV 1 MΩ <6.5 LSB <40 µV <5.0 LSB <77 µV <4.5 LSB <138 µV <6.5 LSB <397 µV <5.0 LSB <763 µV <4.5 LSB <1.4 mV M2p.594x Input Range ±200 mV ±500 mV ±1 ±2 V ±5 V ±10 V Voltage resolution 6.1 µV 15.3 µV 30.5 µV 61.0 µV 152.6 µV 305.2 µV 50 Ω <7.0 LSB <43 µV <5.5 LSB <85 µV <4.5 LSB <138 µV <7.5 LSB <458 µV <5.5 LSB <840 µV <4.5 LSB <1.4 mV 1 MΩ <7.5 LSB <46 µV <5.8 LSB <89 µV <4.5 LSB <138 µV <7.7 LSB <470 µV <5.8 LSB <886 µV <4.5 LSB <1.4 mV M2p.596x, DN2.596-xx, DN6.596-xx Input Range ±200 mV ±500 mV ±1 ±2 V ±5 V ±10 V Voltage resolution 6.1 µV 15.3 µV 30.5 µV 61.0 µV 152.6 µV 305.2 µV 50 Ω <9.0 LSB <55µV <6.8 LSB <104 µV <5.5 LSB <168 µV <9.0 LSB <550 µV <6.8 LSB <1.1 mV <5.5 LSB <1.7 mV 1 MΩ <9.5 LSB <58µV <7.1 LSB <109 µV <5.5 LSB <168 µV <9.5 LSB <580 µV <7.1 LSB <1.1 mV <5.5 LSB <1.7 mV D ynamic Parameters, typical figures M2p.592x, DN2.592-xx, DN6.592-xx Test - sampling rate 20 MS/s Input Range ±200 mV ±500 mV ±1 ±2 V Test Signal Frequency 1 MHz n.a. 1 MHz n.a. 1 MHz n.a. 1 MHz n.a. SNR (typ) ≥ 77.2 dB n.a. ≥ 79.8 dB n.a. ≥ 81.0 dB n.a. ≥ 75.0 dB n.a. THD (typ) ≤ 92.5 dB n.a. ≤ -92.8 dB n.a. ≤ -89.5 dB n.a. ≤ -76.5 dB n.a. SFDR (typ), excl. harm. ≥ 103.0 dB n.a. ≥ 103.0 dB n.a. ≥ 105.0 dB n.a. ≥ 93.0 dB n.a. ENOB (based on SNR) ≥ 12.5 LSB n.a. ≥ 13.0 LSB n.a. ≥ 13.2 LSB n.a. ≥ 12.2 LSB n.a. ENOB (based on SINAD) ≥ 12.5 LSB n.a. ≥ 13.0 LSB n.a. ≥ 13.1 LSB n.a. ≥ 11.8 LSB n.a. M2p.593x, DN2.593-xx, DN6.593-xx Test - sampling rate 40 MS/s Input Range ±200 mV ±500 mV ±1 ±2 V Test Signal Frequency 1 MHz 10 MHz 1 MHz 10 MHz 1 MHz 10 MHz 1 MHz 10 MHz SNR (typ) ≥ 73.0 dB ≥ 72.6 dB ≥ 74.6 dB ≥ 74.4 dB ≥ 75.3 dB ≥ 75.3 dB ≥ 71.9 dB ≥ 71.8 dB THD (typ) ≤ -87.8 dB ≤ -67.0 dB ≤ -89.0 dB ≤ -67.0 dB ≤ -86.1 dB ≤ -67.2 dB ≤ -79.0 dB ≤ -67.2 dB SFDR (typ), excl. harm. ≥ 98.3 dB ≥ 96.5 dB ≥ 98.8 dB ≥ 99.5 dB ≥ 101.0 dB ≥ 100.0 dB ≥ 81.7 dB ≥ 91.3 dB ENOB (based on SNR) ≥ 11.8 LSB ≥ 11.8 LSB ≥ 12.1 LSB ≥ 12.0 LSB ≥ 12.2 LSB ≥ 12.2 LSB ≥ 11.7 LSB ≥ 11.6 LSB ENOB (based on SINAD) ≥ 11.8 LSB ≥ 10.7 LSB ≥ 12.1 LSB ≥ 10.7 LSB ≥ 12.2 LSB ≥ 10.8 LSB ≥ 11.6 LSB ≥ 10.7 LSB M2p.594x Test - sampling rate 80 MS/s Input Range ±200 mV ±500 mV ±1 ±2 V Test Signal Frequency 1 MHz 10 MHz 1 MHz 10 MHz 1 MHz 10 MHz 1 MHz 10 MHz SNR (typ) ≥ 70.6 dB ≥ 70.5 dB ≥ 72.9 dB ≥ 72.8 dB ≥ 74.2 dB ≥ 74.2 dB ≥ 69.8 dB ≥ 69.8 dB THD (typ) ≤ -87.3 dB ≤ -76.9 dB ≤ -86.6 dB ≤ -76.3 dB ≤ -84.8 dB ≤ -70.1 dB ≤ -79.0 dB ≤ -77.9 dB SFDR (typ), excl. harm. ≥ 97.5 dB ≥ 105.0 dB ≥ 101.0 dB ≥ 104.0 dB ≥ 100.0 dB ≥ 100.0 dB ≥ 96.9 dB ≥ 96.6 dB ENOB (based on SNR) ≥ 11.4 LSB ≥ 11.4 LSB ≥ 11.8 LSB ≥ 11.8 LSB ≥ 12.0 LSB ≥ 12.0 LSB ≥ 11.2 LSB ≥ 11.2 LSB ENOB (based on SINAD) ≥ 11.4 LSB ≥ 11.3 LSB ≥ 11.8 LSB ≥ 11.5 LSB ≥ 12.0 LSB ≥ 11.1 LSB ≥ 11.2 LSB ≥ 11.2 LSB
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M2p.59xx-x4 - 16 bit general purpose DigitizerM2p.596x, DN2.596-xx, DN6.596-xx Test - sampling rate 125 MS/s Input Range ±200 mV ±500 mV ±1 V ±2 V Test Signal Frequency 1 MHz 10 MHz 40 MHz 1 MHz 10 MHz 40 MHz 1 MHz 10 MHz 40 MHz 1 MHz 10 MHz 40 MHz SNR (typ) ≥ 68.1 dB ≥ 66.2 dB ≥ 65.5 dB ≥ 70.5 dB ≥ 69.9 dB ≥ 68.7 dB ≥ 73.3 dB ≥ 72.7 dB ≥ 71.5 dB ≥ 67.8 dB ≥ 65.8 dB ≥ 65.1 dB THD (typ) ≤ -81.5 dB ≤ -74.5 dB ≤ -53.7 dB ≤ -82.5 dB ≤ -77.6 dB ≤ -55.3 dB ≤ -83.3 dB ≤ -68.9 dB ≤ -57.3 dB ≤ -78.0 dB ≤ -75.6 dB ≤ -53.7 dB SFDR (typ), excl. harm. ≥ 95.0 dB ≥ 93.4 dB ≥ 92.3 dB ≥ 97.5 dB ≥ 96.8 dB ≥ 94.0 dB ≥ 98.5 dB ≥ 98.1 dB ≥ 96.4 dB ≥ 91.5 dB ≥ 89.0 dB ≥ 89.0 dB ENOB (based on SNR) ≥ 11.0 LSB ≥ 10.7 LSB ≥ 10.6 LSB ≥ 11.4 LSB ≥ 11.3 LSB ≥ 11.1 LSB ≥ 11.8 LSB ≥ 11.8 LSB ≥ 11.6 LSB ≥ 11.0 LSB ≥ 10.6 LSB ≥ 10.5 LSB ENOB (based on SINAD) ≥ 11.0 LSB ≥ 10.6 LSB ≥ 8.6 LSB ≥ 11.4 LSB ≥ 11.1 LSB ≥ 8.9 LSB ≥ 11.7 LSB ≥ 11.0 LSB ≥ 9.2 LSB ≥ 10.9 LSB ≥ 10.6 LSB ≥ 8.6 LSB Dynamic parameters are measured at ±1 V input range (if no other range is stated) and 50Ω termination with the samplerate specified in the table. Measured parameters are averaged 20 times to get typical values. Test signal is a pure sine wave generated by a signal generator and a matching bandpass filter. Amplitude is >99% of FSR. 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 Dis- tortion, ENOB = Effective Number of Bits. Hardware block diagram8 Insert document name here
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M2p.59xx-x4 - 16 bit general purpose DigitizerOrder Information The card is delivered with 512 MSample on-board memory and supports standard acquisition (Scope), FIFO acquisition (streaming), Multiple Recording, Gated Sampling, ABA mode and Timestamps. Operating system drivers for Windows/Linux 32 bit and 64 bit, examples for C/C++, LabVIEW (Windows), MATLAB (Windows and Linux), LabWindows/CVI, IVI, .NET, Delphi, Java, Python and a Base license of the oscilloscope software SBench 6 are included. Adapter cables are not included. Please order separately! PCI Express x4 Order no. A/D Resolution Standard mem Single-Ended Inputs Differential Inputs M2p.5920-x4 16 Bit 512 MSample 1 channel 20 MS/s 1 channel 20 MS/s OEM only M2p.5921-x4 16 Bit 512 MSample 2 channels 20 MS/s 2 channels 20 MS/s M2p.5922-x4 16 Bit 512 MSample 4 channels 20 MS/s 2 channels 20 MS/s M2p.5926-x4 16 Bit 512 MSample 4 channels 20 MS/s 4 channels 20 MS/s M2p.5923-x4 16 Bit 512 MSample 8 channels 20 MS/s 4 channels 20 MS/s M2p.5930-x4 16 Bit 512 MSample 1 channel 40 MS/s 1 channel 40 MS/s OEM only M2p.5931-x4 16 Bit 512 MSample 2 channels 40 MS/s 2 channels 40 MS/s M2p.5932-x4 16 Bit 512 MSample 4 channels 40 MS/s 2 channels 40 MS/s M2p.5936-x4 16 Bit 512 MSample 4 channels 40 MS/s 4 channels 40 MS/s M2p.5933-x4 16 Bit 512 MSample 8 channels 40 MS/s 4 channels 40 MS/s M2p.5940-x4 16 Bit 512 MSample 1 channel 80 MS/s 1 channel 80 MS/s M2p.5941-x4 16 Bit 512 MSample 2 channels 80 MS/s 2 channels 80 MS/s M2p.5942-x4 16 Bit 512 MSample 4 channels 80 MS/s 2 channels 80 MS/s M2p.5946-x4 16 Bit 512 MSample 4 channels 80 MS/s 4 channels 80 MS/s M2p.5943-x4 16 Bit 512 MSample 8 channels 80 MS/s 4 channels 80 MS/s M2p.5960-x4 16 Bit 512 MSample 1 channel 125 MS/s 1 channel 125 MS/s M2p.5961-x4 16 Bit 512 MSample 2 channels 125 MS/s 2 channels 125 MS/s M2p.5962-x4 16 Bit 512 MSample 4 channels 125 MS/s 2 channels 125 MS/s M2p.5966-x4 16 Bit 512 MSample 4 channels 125 MS/s 4 channels 125 MS/s M2p.5968-x4 16 Bit 512 MSample 4 channels 125 MS/s 4 channels 125 MS/s 8 channels 80 MS/s Options Order no. Option M2p.xxxx-SH6ex (1) Synchronization Star-Hub for up to 6 cards incl. cables, only one slot width, card length 245 mm M2p.xxxx-SH6tm (1) Synchronization Star-Hub for up to 6 cards incl. cables, two slots width, standard card length M2p.xxxx-SH16ex (1) Synchronization Star-Hub for up to 16 cards incl. cables, only one slot width, card length 245 mm M2p.xxxx-SH16tm (1) Synchronization Star-Hub for up to 16 cards incl. cables, two slots width, standard card length M2p-upgrade Upgrade for M2p.xxxx: Later installation of option Star-Hub Services Order no. Recal Recalibration at Spectrum incl. calibration protocol Cables Order no. for Connections Length to BNC male to BNC female to SMA male to SMA female to SMB female Analog/Clock-In/Trig-In 80 cm Cab-3f-9m-80 Cab-3f-9f-80 Cab-3f-3mA-80 Cab-3f-3fA-80 Cab-3f-3f-80 Analog/Clock-In/Trig-In 200 cm Cab-3f-9m-200 Cab-3f-9f-200 Cab-3f-3mA-200 Cab-3f-3fA-200 Cab-3f-3f-200 Probes (short) 5 cm Cab-3f-9f-5 Clk-Out/Trig-Out/Extra 80 cm Cab-1m-9m-80 Cab-1m-9f-80 Cab-1m-3mA-80 Cab-1m-3fA-80 Cab-1m-3f-80 Clk-Out/Trig-Out/Extra 200 cm Cab-1m-9m-200 Cab-1m-9f200 Cab-1m-3mA-200 Cab-1m-3fA-200 Cab-1m-3f-200 Information The standard adapter cables are based on RG174 cables and have a nominal attenuation of 0.3 dB/m at 100 MHz. Amplifiers Order no. Bandwidth Connection Input Impedance Coupling Amplification SPA.1412 (2) 200 MHz BNC 1 MOhm AC/DC x10/x100 (20/40 dB) SPA.1411 (2) 200 MHz BNC 50 Ohm AC/DC x10/x100 (20/40 dB) SPA.1232 (2) 10 MHz BNC 1 MOhm AC/DC x100/x1000 (40/60 dB) SPA.1231 (2) 10 MHz BNC 50 Ohm AC/DC x100/x1000 (40/60 dB) Information External Amplifiers with one channel, BNC/SMA female connections on input and output, manually adjustable offset, man- ually switchable settings. An external power supply for 100 to 240 VAC is included. Please be sure to order an adapter cable matching the amplifier connector type and matching the connector type for your A/D card input. Software SBench6 Order no. SBench6 Base version included in delivery. Supports standard mode for one card. SBench6-Pro Professional version for one card: FIFO mode, export/import, calculation functions SBench6-Multi Option multiple cards: Needs SBench6-Pro. Handles multiple synchronized cards in one system. Volume Licenses Please ask Spectrum for details. Software Options Order no. SPc-RServer Remote Server Software Package - LAN remote access for M2i/M3i/M4i/M4x/M2p cards SPc-SCAPP Spectrum’s CUDA Access for Parallel Processing - SDK for direct data transfer between Spectrum card and CUDA GPU. Includes RDMA activation and examples. Signed NDA needed for access. (1) : Just one of the options can be installed on a card at a time. (2) : Third party product with warranty differing from our export conditions. No volume rebate possible. Technical changes and printing errors possible SBench, digitizerNETBOX and generatorNETBOX are registered trademarks of Spectrum Instrumentation GmbH. Microsoft, Visual C++, Windows, Windows 98, Windows NT, Window 2000, Windows XP, Windows Vista, Windows 7, Windows 8 and Windows 10 are trademarks/registered trademarks of Microsoft Corporation. LabVIEW, DASYLab, Diadem and LabWindows/CVI are trademarks/registered trademarks of National Instruments Corporation. MATLAB is a trademark/registered trademark of The Mathworks, Inc. Delphi and C++Builder are trademarks/registered trademarks of Embarcadero Technologies, Inc. Keysight VEE, VEE Pro and VEE OneLab are trademarks/registered trademarks of Keysight Technologies, Inc. FlexPro is a registered trademark of Weisang GmbH & Co. KG. PCIe, PCI Express and PCI-X and PCI-SIG are trademarks of PCI-SIG. LXI is a registered trademark of the LXI Consortium. PICMG and CompactPCI are trademarks of the PCI Industrial Computation Manufacturers Group. Oracle and Java are registered trademarks of Oracle and/or its affiliates. Intel and Intel Xeon are trademarks or registered trademarks of Intel Corporation. AMD and Opteron are trademarks or registered trademarks of Advanced Micro Devices. NVIDIA, CUDA, GeForce, Quadro and Tesla are trademarks/registered trademarks of NVIDIA Corporation. (c) Spectrum GmbH 9