THIS PRODUCT IS END-OF-LIFE. Show more about end-life-products policy.
Recommended product:
Product:
16 bit transient recorder
Description:
The MX.46xx for the first time offers 16 bit resolution synchronously on four channels at very high sampling rates. Every channel has its own amplifier and A/D converter. This eliminates the problems known from multiplexed systems like phase error between the channels or high crosstalk. Every input channel can be offset and gain calibrated by software using a highprecision onboard calibration source. The user will easily find a matching solution from the eight offered models. These versions are working with sampling rates of 200 kS/s, 500 kS/s, 1 MS/s or 3 MS/s. The boards can also be updated to a multichannel system using PXI backplane signals.
Facts & Features:
- Up to 200 kS/s on 4 channels
- Simultaneously sampling on all channels
- Separate ADC and amplifier per channel
- 8 input ranges: +/-50 mV up to +/-10 V
- Programmable input offset of +/-5 V
- complete on-board calibration
- True differential / single-ended selectable
- Up to 64 MSample on-board memory
- 32 MSample standard memory installed
- Window/pulsewidth/re-arm trigger
- Synchronization possible
- CompactPCI/PXI 3U compatible
- Supporting PXI star trigger
- Supporting PXI trigger bus
- Supporting PXI reference clock
Application examples:
- High precision audio measurements
- Vibration analysis
- Life cycle tests of plastic components
FIFO mode
The FIFO mode is designed for continuous data transfer between measurement board and PC memory (with up to 100 MByte/s) or hard disk. The control of the data stream is done automatically by the driver on interrupt request. The complete installed on-board memory is used for buffer data, making the continuous streaming extremely reliable.PXI Star Trigger Card (Optional)
The MX.9010 is a special PXI star trigger card designed for the Spectrum PXI products. It allows to route clock and trigger synchronously to all PXI slots that are connected to the star trigger slot. The PXI reference clock is overwritten and external trigger events are synchronized to the sampling clock.Channel Trigger
The data acquisition boards offer a wide variety of trigger modes. Besides the standard signal checking for level and edge as known from oscilloscopes it's also possible to define a window trigger. Trigger conditions can be combined with logical conjunctions like OR to adopt to different application scenarios.
External Trigger
All boards can be triggered using an external TTL signal. It's possible to use positive or negative edge also in combination with a programmable pulse width. An internally recognized trigger event can - when activated by software - be routed to the trigger connector to start external instruments.
PXI Trigger
The Spectrum cards support star trigger as well as the PXI trigger bus. using a simple software commend one or more trigger lines can be used as trigger source. This feature allows the easy setup of OR connected triggers from different cards.Timestamp
The timestamp option writes the time positions of the trigger events in an extra memory. The timestamps are relative to the start of recording, a defined zero time, externally synchronized to a radio clock, or a GPS receiver. With this option acquisitions of systems on different locations can be set in a precise time relation.External Clock
Using a dedicated connector a sampling clock can be fed in from an external system. It's also possible to output the internally used sampling clock to synchronize external equipment to this clock.
PXI Reference Clock
The card is able to use the 10 MHz reference clock that is supplied by the PXI system. Enabled by software the PXI reference clock is feeded in the on-board PLL. This feature allows the cards to run with a fixed phase relation.Reference Clock
The option to use a precise external reference clock (normally 10 MHz) is necessary to synchronize the board for high-quality measurements with external equipment (like a signal source). It's also possible to enhance the quality of the sampling clock in this way. The driver automatically generates the requested sampling clock from the fed in reference clock.On-board Calibration
The on-board calibration can be run on user request and calibrates the amplifier against a dedicated internal high precision calibration source. After this calibration data is stored permanently in an on-board EEPROM and is automatically used for further acquisitions.
Differential Inputs
With a simple software command the inputs can individually be switched from single-ended (in relation to ground) to differential, without loosing any inputs. When the inputs are used in differential mode the A/D converter measures the difference between two lines with relation to system ground.
Programmable Input Amplifiers
The analog inputs can be adapted to real world signals using individual settings for each channel. A large number of different input ranges and a programmable input offset allow to adopt perfectly to the real world signals.Programmable Input Offset
Most of the Spectrum A/D cards offer a user programmable signal offset opening the Spectrum boards to a wide variety of setups. The signal offset at least covers a range of +/-100 % of the currently selected input range making unipolar measurements with the card possible. Besides this the input range offset can be programmed individually allowing a perfect match of the A/D card section to the real world signal.This standard driver is included in the card delivery and it is possible to get the newest driver version free of charge from our homepage at any time. There are no additional SDK fees for the classical text-based programming. All boards are delivered with drivers for Windows 7, Windows 8, Windows 10 and Windows 11, all 32 bit and 64 bit.
Product | Channels | Max. Samplerate | Max. Bandwidth |
---|---|---|---|
MX.4620 | 2 | 200 KS/s | 100 KHz |
MX.4630 | 2 | 500 KS/s | 250 KHz |
MX.4631 | 4 | 500 KS/s | 250 KHz |
MX.4640 | 2 | 1 MS/s | 500 KHz |
MX.4641 | 4 | 1 MS/s | 500 KHz |
MX.4650 | 2 | 3 MS/s | 1.50 MHz |
MX.4651 | 4 | 3 MS/s | 1.50 MHz |
On different platforms | Bus | Max. Bus Transfer speed |
---|---|---|
DN2.462-04 | Ethernet | 70 MByte/s |
M2i.4621 | PCI-X | 245 MByte/s |
M2i.4621-Exp | PCI Express x1 | 160 MByte/s |
MC.4621 | CompactPCI | 100 MByte/s |
Documents
MX.46xx Datasheet | Data sheet of the MX.46xx family |
21.02.2022 | 315 K | |
MX.46xx Manual | Manual of MX.46xx family |
21.02.2022 | 3 M | |
SBench 6 data sheet | Data sheet of SBench 6 |
15.01.2024 | 999 K | |
MATLAB Manual | Manual for MATLAB drivers for MI/MC/MX |
21.02.2022 | 70 K | |
LabVIEW Manual | LabVIEW Manual for MC/MX.46xx |
21.02.2022 | 723 K | |
SBench 6 Manual | Manual for SBench 6 |
21.02.2022 | 7 M |
WINDOWS DRIVER + SOFTWARE
MICX_NT32 | MI/MC/MX/PCI.xxx Windows 98/NT 32 Bit Drivers |
21.02.2022 | 353 K | |
MICX_XP (32-bit) | MI/MC/MX/PCI.xxx Windows XP/Vista 32 Bit Drivers |
21.02.2022 | 381 K | |
MICX_XP (64-bit) | MI/MC/MX/PCI.xxx Windows XP/Vista 64 Bit Drivers |
21.02.2022 | 579 K | |
MICX_WIN7_8 (32-bit) | MI/MC/MX/PCI.xxx Windows 7/8 32 Bit Drivers |
1.1.22681 | 11.11.2024 | 32 M |
MICX_WIN7_8 (64-bit) | MI/MC/MX/PCI.xxx Windows 7/8 64 Bit Drivers |
1.0.22610 | 25.10.2024 | 6 M |
MICX_WIN10 (32-bit) | MI/MC/MX/PCI.xxx Windows 10 32 Bit Drivers |
4 | 21.02.2022 | 415 K |
MICX_WIN10 (64-bit) | MI/MC/MX/PCI.xxx Windows 10/11 64 Bit Drivers |
4 | 21.02.2022 | 627 K |
c_header | C/C++ driver header and library files |
7.04 | 25.10.2024 | 44 K |
SBench5 | SBench 5 Installer |
5.3.0 | 21.02.2022 | 5 M |
SBench6 (32-bit) | SBench 6 (32-bit) Installer / Windows 7, 8, 10 |
6.5.09 | 25.10.2024 | 36 M |
SBench6 (64-bit) | SBench 6 (64-bit) Installer / Windows 7, 8, 10, 11 |
6.5.09 | 25.10.2024 | 49 M |
MATLAB Driver | MI / MC / MX MATLAB driver + examples |
21.02.2022 | 714 K | |
LabVIEW Driver | MI / MC / MX LabVIEW Driver |
21.02.2022 | 8 M | |
Examples | MI / MC / MX Examples for C/C++, Delphi, VB, LabWindows/CVI, ... |
21.02.2022 | 700 K |
LINUX DRIVER + SOFTWARE
Linux Driver Complete | MI / MC / MX Linux 32 bit and 64 bit Drivers |
1.0.22610 | 25.10.2024 | 6 M |
SBench6 | SBench 6 Linux 32 (.rpm) |
6.5.08 | 22.04.2024 | 26 M |
SBench6 | SBench 6 Linux 64 (.rpm) |
6.5.09 | 17.09.2024 | 23 M |
SBench6 | SBench 6 Linux 32 (.deb) |
6.5.08 | 22.04.2024 | 23 M |
SBench6 | SBench 6 Linux 64 (.deb) |
6.5.09 | 25.10.2024 | 22 M |
SBench6 | SBench6 Jetson (.deb) |
6.5.09 | 19.04.2024 | 11 M |
MICX Examples for Linux | MI / MC / MX Linux Examples (C/C++) |
21.02.2022 | 53 K |
Firmware
Product Notes
General Digitizer Introduction | General Introduction to Waveform Digitizers |
21.02.2022 | 587 K | |
High-Res High BW Digitizers | Advantages of High Resolution in High Bandwidth Digitizers |
21.02.2022 | 2 M | |
Digitizer Acquisition Modes | Using modular Digitizer Acquisition Modes |
21.02.2022 | 3 M | |
Digitizer Front-End | Proper Use of Digitizer Front-End Signal Conditioning |
21.02.2022 | 3 M | |
Trigger and Sync | Trigger, Clock and Synchronization Details at high-speed Digitizers |
21.02.2022 | 1 M | |
SBench 6 Introduction | SBench 6 - Data Acquisition and Analysis of Digitizer Data |
21.02.2022 | 1 M |
Application Notes
Ultrasonic Applications | Using Digitizers in Ultrasonic Applications |
21.02.2022 | 617 K | |
Signal Processing Tools | Using Signal Processing Tools to enhance Digitizer Data |
21.02.2022 | 1 M | |
Mechanical Measurements | Mechanical Measurements Using Digitizers |
21.02.2022 | 1 M | |
Power Measurements | Power Measurements Using Modular Digitizers |
21.02.2022 | 1 M | |
Using Probes & Sensors | Using Probes and Sensors with Modular Digitizers |
21.02.2022 | 858 K | |
Teaming AWG with Digitizer | Teaming an Arbitrary Waveform Generator with a Modular Digitizer |
21.02.2022 | 919 K | |
Common Digitizer Setup Problems | Application Note: Common Digitizer Setup Problems to avoid |
21.02.2022 | 1 M | |
AN Amplitude Resolution | Application Note: The Amplitude Resolution of Digitizers and how it affects Measurements |
21.02.2022 | 555 K |