DLM6000 MSO & DSO Series (DISCONTINUED)

Notice: This product was discontinued on Sep 2, 2012. See this replacement product:

DLM5000 Mixed Signal Oscilloscope

Yokogawa's new DLM6000 series digital and mixed signal oscilloscopes boast fresh physical and on-screen interfaces, based on extensive market research and user feedback. It incorporates dedicated, backlit buttons for the most commonly accessed settings, and unique Yokogawa controls, like the 5-way selector button and spring loaded ‘jog shuttle' control.

The DLM6000 series oscilloscopes offer an extensive range of capabilities for waveform characterization, powerful tools for detecting glitches and anomalies, advanced signal enhancement and noise reduction technologies, and a range of options for serial bus analysis and power measurement. Select from models with four channels plus 16 or 32 bit logic inputs, and 500MHz, 1.0GHz, or 1.5GHz bandwidths.

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Features
Functions
Options
Connectivity
Accessories

Features
Functions
Options
Connectivity
Accessories

High-Speed Acquisition and History Memory

High Acquisition Rate Unchanged Even When Displaying Logic Signals

During continuous measurement : Up to 25,000 times per second per channel
In N Single mode : Up to 2.5 million times per second per channel

Waveform update rate determines your probability of catching an intermittent glitch. On other mixed signal oscilloscopes, enabling the logic inputs severly impacts waveform update rate. The DLM6000 maintains waveform update rates so you can detect abnormalities and transients in your analog or logic channels.

History Memory Function and
High Speed Acquisition

Preserve up to 2000 captures of actual waveform data (not screen images)
After measurement has stopped, you can review past waveforms individually for detailed analysis.
Search and Zoom
Automated measurement of waveform parameters
Variety of computations

High-speed acquisition means you can even capture instantly

On most oscilloscopes, to observe and analyze abnormalities such as unpredictable noise in detail, you have to devise clever trigger settings and re-measure the event.
But with the DL6000/DLM6000 there is no need to re-measure the phenomena because once the event occurs, you can use the History Memory function to recall past waveforms that were originally displayed on screen.

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Example of the usefulness of observing intermittent signals: Observation of SD bus commands

SD card bus commands are sent intermittently, and the non-signal portions of these waveforms do not need to be analyzed.

To be able to capture the commands that you want to observe from such signals, you can set a serial bus trigger and use the History memory to acquire up to 2000 of the waveforms that match the trigger conditions into History memory while ignoring the non-signal waveforms.

Rather than acquiring a single waveform to the entire acquisition memory, you can acquire multiple waveforms of only the needed command, and analyze them.

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Search & Zoom

Quickly extract locations and abnormalities you wish to analyze from the acquired waveform data, and zoom in anywhere on waveform details.
The DL6000/DLM6000 series has enhanced Search and Zoom functions for searching for desired portions of waveform data and observing those waveforms in detail.

Search function for extracting abnormal phenomena
The search function can search both analog and logic signals in History Memory (History Search).

Main Search Functions:

State search (Hi/Lo setting of each channel)
Serial pattern (I2C, SPI, CAN, general-use pattern) search
Polygon zone search
Waveform zone search
Parameter search (Measured parameters, FFT, etc.)

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Display two zoom areas simultaneously

Because the DL6000/DLM6000 series lets you set zoom factors independently, you can display two zoomed
waveform areas with different time axis scales at the same time.

Zoom and scroll with the zoom knob and jog shuttle
Intuitively adjust the zoom factor with the zoom knob, and the scroll with the jog shuttle. You can also scroll the zoom window automatically with the Auto Scroll function.

Automated measurement of waveform parameters

Automated measurement of waveform parameters - Automatically display waveform values

Vertical waveform parameters such as amplitude, RMS
Time axis waveform parameters such as frequency, startup time
Delay time between specified signal edges
Automatic measurement of time axis waveform parameters is even possible on logic signals
Measurement Location Indicator indicates the measured location of a specified item

Display the statistics on the automated measurement values of waveform parameters.

Normal statistical processing (Continuous)
Statistical processing for each period (Cycle)

Statistical processing of history waveforms (History)

Measure a variety of parameters automatically
Simply select the check boxes of parameters you wish to measure automatically in the setting screen's parameter list.

Simultaneously measure up to 16 parameters during acquisition. Additional measured values can be obtained in the analysis screen, or via PC communication. DLM6000 Web 17

You can measure waveform parameters of every cycle of a periodic waveform, and display results in lists and trend graphs. This is useful when evaluating period-by-period waveform fluctuations or loss in switching circuits.

Real Time Filter and High Resolution Mode

Input Filters

The DLM6000/DL6000 can restrict filter out unwanted high frequency noise and expose only the frequency bandwidth of the signals you are working with. Every analog channel offers independent, real-time bandwidth filters.

Analog Filters: 200MHz / 20MHz
Real-time Digital Filters: 8MHz / 4MHz / 2MHz / 1MHz 500kHz / 250kHz / 125kHz / 62.5kHz / 32kHz/ 16kHz / 8kHz

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High Resolution Mode

Digital oscilloscopes have offer excellent time resolution. However, nearly all digital oscilloscopes provide only 8-bits of vertical (voltage) resolution. With Yokogawa's High Resolution mode (real-time FIR filter), the oscilloscope will oversample and reconstruct a higher resolution signal with resolutions of up to 12 bits. Unlike averaging, High Resolution mode does not require a repetitive signal and works on single shot acquisitions.

Switching Waveform Measurement
When measuring SMPS waveforms, highly precise evaluation is impossible due to the insufficient dynamic range offered by 8-bit oscilloscopes. In such cases, you can use High Resolution mode to raise the precision of the waveform as well as of any computed results.

Intuitive Operation and High Performance Waveform Analysis Tool

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Abundant Trigger Functions

	To easily isolate specific waveforms, the DL6000/DLM6000 offers a variety of application-oriented triggers, from simple edge triggers to pulse width, multi-criteria combination and time difference triggers.

Action On Trigger Function

When your test involves waiting for intermittent phenomena, you can use the Action On trigger function to automatically save waveform data to file when trigger conditions are met. You can also send e-mail notifications on every trigger. Even for phenomena that occur only once per day or less, you can be sure that a record of the data, including the date and time, will be kept.

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Logic signal measurement and analysis

Observing up to 32-bit logic signals together with analog signals

Observing many signals simultaneously and checking their correlations and timing is an effective means of verifying increasingly complex embedded systems.

With the DLM6000 series, you can measure up to 32-bit logic signals and 4 channels of analog waveforms simultaneously, and investigate hidden data in waveforms using bus analysis and computation functions.

Grouping logic signals to make them easy to read and understand

As many as 5 groups of logic signals can be defined. You can enter display settings for each group, and specify which bit in each group is the LSB or MSB
regardless of the bit arrangement of the logic probe.
This means that even if pin assignments or signal arrangements change, you only need to change settings rather than to repeat the probing of the circuit.

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Bus and State displays make logic signals easy to read and analyze

The DL6000/DLM6000 is not limited to displaying logic signals as waveforms. It can also show logic signals assigned to groups in a Bus display, or specified
clock signals in a State display.
Therefore, parallel output values of an address bus or A/D converter can be read directly. Functions like these make analysis of logic signals easy, so that operating checks of the device under test can be performed more quickly and accurately.

Virtual D/A Computation function displays to 32-bit logic signals as analog waveforms

The DL6000/DLM6000 includes a Virtual D/A Computation function, in which address bus signals or logic signals from data converter I/O can be converted to analog waveforms and displayed. You can display logic signals output from an A/D converter, and by comparing them with the original analog waveforms prior to conversion, you can investigate the general dynamic characteristics of the A/D conversion. Displaying the address bus signal as a waveform is also useful for identifying instances of abnormal memory access. D/A converted waveforms can undergo FFT analysis or have additional digital filtering computations applied to them.

Making logic signal measurement probing easier and minimizing effects on the target

There are two different types of logic probe that can be used with the DLM6000, depending on the application.

250 MHz logic probe (model 701989, Input Impedance: 100 kΩ)
The model 701989 is a 250 MHz logic probe with a tip shape designed for probing circuit boards. In addition to probing with the pincher tip, the tips can be stacked in the included holder, making it easy to connect to and disconnect from a 2.54 mm pitch box connector.

High impedance logic probe (model 701988, Input Impedance: 1MΩ, Max. toggle speed 100MHz)
The model 701988 is a 100 MHz general-purpose logic probe with an impedance of 1 MΩ. Its high impedance gives it characteristics that make it difficult to influence the behavior of the target. Aside from pincher tip probing, the head with the tip removed can also be connected to a 2.54 mm pitch diameter connector.

Serial bus analysis function (option)

You can add on I2C, SPI, CAN, LIN, and other serial bus-specific trigger and analysis functions to your DL6000/DLM6000 series instrument. With these functions, you can trigger on specific serial bus parameters, and display the waveforms along with protocol analysis indicating the decoded serial bus information.

Moreover, the DL6000/DLM6000 series also comes with a "Serial Bus Auto-Setup" function to eliminate the tedious task of entering settings when starting the analysis.

Auto Setup Function for Serial Bus Analysis

Display signal waveforms, protocol information, and decode information in real time The DL6000/DLM6000's serial bus analysis function simultaneously displays these three pieces of information on screen in real time. You can link the protocol information with the waveform information, select data in the protocol list, and automatically display the corresponding part of the analog waveform. Check the protocol list to see whether transferred information is correct. If not, you can determine whether there were any electrical problems at the waveform level. In operational analysis of systems that include serial busses, this can be very useful for sorting out hardware from software problems.
Analyzing two busses at once Both analog and logic inputs can be used for serial bus analysis. Also, two different serial busses can be analyzed at the same time. For example, you can analyze a CAN and LIN bus simultaneously, or use an MSO to analyze two SPI busses at once.
Example: Behavioral analysis of an I²C control motor You can trigger on specific data sent to a motor controller on an I2C bus and capture the waveform. Then, you can observe and analyze the content and timing of the data, plus the behavior of the activated motor. Together with that, you can use an MSO to observe control circuit logic signals, enabling you to evaluate the overall system.

Computation Functions

Digital filters, integrals, edge, rotary count, logic signal DA conversion computation, and FFT computation functions come standard. As these computations are hardware-based, results appear on screen quickly. Even computations that traditionally needed to be sent to a separate PC for processing can now be executed at high speed on the oscilloscope, thus greatly reducing the time and effort involved in computing and analyzing waveform data.

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Digital Filter Computations
Digital filters, integrals, edge, rotary count, logic signal DA conversion computation, and FFT computation functions come standard.

As these computations are hardware-based, results appear on screen quickly. Even computations that traditionally needed to be sent to a separate PC for processing can now be executed at high speed on the oscilloscope, thus greatly reducing the time and effort involved in computing and analyzing waveform data.

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FFT Computation

You can perform FFT computation for analog signal waveforms or DA computation waveforms. This includes not only signal spectra, but also coherent and transfer functions.

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User defined MATH (option)

By combining basic math, trigonometric functions, differentials, digital filters,waveform parameters, and other values, you can define and execute equations and display the results along with the observed waveform

Power Supply Analysis Function (optional)

By using combinations of differential and current probes, you can evaluate switching loss or analyze safe operating area (SOA) in power supply waveforms. Through statistical computation you can also measure multiple switching waveforms and display loss on a per-week basis in lists and trends, or display statistics on aggregate loss of up to 2000 switching waveforms stored in History Memory. If precise calculations are required, a correction function and High Resolution mode are available.

Cycle-by-cycle switching loss statistics and trend display
It can be extremely useful to check for fluctuations in switching frequency or voltage modulated by the commercial power input voltage on screen, at the same time as the waveform of that input voltage. Fluctuations in cycle-by-cycle loss, peak current, and other phenomena can be checked in lists and trend graphs thereby allowing you to identify excessive changes from power-ON to stable operation.

Waveform parameter measurement function for power supply analysis

Harmonic Analysis of Power Supply Current Based on EN61000-3-2 (IEC61000-3-2)
Bar graphs and lists of harmonics can be displayed together with the appropriate limits for the device under test as defined by the IEC standard (supports device classes A-D). Any measured value which exceeds the limit is highlighted.

Diverse Connectivity - Remote Control, Data Transfer, and Data Saving

700924 Differential Probe 1400V / 100 MHz

Differential oscilloscope probe
100 MHz
±1400 V (DC + ACpeak) at 1000:1
Internal battery or probe power supply
Oscilloscopes, ScopeCorders

700925 Differential Probe 500V / 15 MHz

Works with Oscilloscopes, ScopeCorders. 15 MHz, 100:1/10:1, Max. Differential Voltage: ±500 V (DC + ACpeak) or 350 Vrms at 100:1 attenuation, Probe Power: Internal battery or probe power supply.

700939 Active FET Probe 10V / 900 MHz

700939 Active FET Probe
900 MHz Active FET Probe Circuit
10:1, ±10 V (DC + ACpeak) FET Input Active Probe
1.5 m

701917 Current Probe 50 MHz / 5 ARMS

701917 oscilloscope current probe
Frequency bandwidth: DC to 50 MHz
Maximum continuous input range: 5 Arms
Functions with Digital Oscilloscopes, ScopeCorders, other waveform measuring instruments

701918 Current Probe 120 MHz / 5 ARMS

Yokogawa 701918 Current Probe
Frequency bandwidth: DC to 120 MHz
Maximum continuous input range: 5 Arms
Functions with Digital Oscilloscopes, ScopeCorders, other waveform measuring instruments

701920 Differential Probe 12V / 500 MHz

701920 Oscilloscope Differential Probe
DC to 500 MHz
10:1
Max. Input Voltage:(to ground) ±40 V (DC + AC peak)
Max. Differential Voltage ±12 V (DC + ACpeak)
Probe power supply
50 Ω input system oscilloscope

701921 Differential Probe 700V / 100 MHz

100 MHz, 100:1/10:1, Max. Differential Voltage: ±700 V (DC + ACpeak) at 100:1 attenuation, Probe Power: Internal battery or probe power supply

701922 Differential Probe 20V / 200 MHz

200 MHz, 10:1, Max. Differential Voltage: ±20 V (DC + ACpeak), Probe Power: probe power supply. Works with 50 Ω input system oscilloscope.

701924 Differential Probe 25V / 1 GHz

701924 Differential Probe
1 GHz, 50:1, Max. Differential Voltage: ±25 V (DC + ACpeak), Probe Power: dedicated probe interface

701926 Differential Probe 7000V / 50 MHz

50 MHz, 1000:1/100:1, Max. Differential Voltage: 5000 Vrms/7000 Vpeak (1000:1), Probe Power: Internal battery or probe power supply B9852MJ power cable is bundled Work with Oscilloscopes, ScopeCorders

701928 Current Probe 100 MHz / 30 ARMS

701928 current probe

Front-end powered

Recognized automatically

Adjust zero position from operation of DLM2000, DLM3000, DLM4000, DL6000/DLM6000, DL9000/DLM9000, SB5000

701929 Current Probe 50 MHz / 30 ARMS

701929 Current Probe 50 MHz / 30 ARMS
Front-end powered
Auto-recognized
DLM2000-4000, DL/DLM6000, DL/DLM9000, SB5000

701930 Current Probe 10 MHz / 150 ARMS

701930 Current Probe 10 MHz / 150 ARMS
Powered by Yokogawa Digital Oscilloscopes, Scopecorders or external power supply

701931 Current Probe 2 MHz / 500 ARMS

701931 Current Probe 2 MHz / 500 ARMS
Powered by Yokogawa Digital Oscilloscopes, Scopecorders or external power supply

701944 High Voltage Passive Probe 1000Vrms / 400 MHz

701944 High Voltage Passive Probe 1000Vrms / 400 MHz
For DL1700, DLM2000-6000, DL6000, DL9000, SB5000 series

701945 High Voltage Passive Probe 1000Vrms / 250 MHz

3m High Voltage Probe (oscilloscope)
DC to 250 MHz bandwidth
100:1 attenuation
Max Input 1000 Vrms CAT II 4000 V transient over-voltage CAT I

701971 DC Power Cable, Alligator Clip Type for DL850EV

701971 Alligator clip type for DL850EV ScopeCorder
For the DC power supply model (/DC).

701988 Logic Probe 100 MHz / 8-bit thumbnail

701919 oscilloscope probe stand
Flexible arm, heavy base to hold and stabilize 8-13mm probes
Can simplify circuit board testing

Application Notes
FAQs

Application Notes
FAQs

Application Note

Making Real-Time Corrected Parametric Measurements Using a Digital Oscilloscope

FAQ

Frequency to Voltage Conversion

FAQ

Is There a Method to Programatically Determine the Number of Valid Waveforms on DL Series Oscilloscopes?

FAQ

What is the Service Procedure for Verifying Time Axis Accuracy?

FAQ

Why is the Displayed Record Length Shorter than the Specified Record Length?

FAQ

What is the Measured Propagation Delay for the PB500 500 MHz Passive Probe (701943)?

FAQ

What are the Differences Between Unbalanced, Balanced, Isolated and Differential Input?

FAQ

What is Hi-Resolution Mode?

FAQ

What is Decimation and How do I use Decimation in Xviewer?

FAQ

DL Series Oscilloscope Won't Measure Rise or Fall Time

FAQ

How Can I Programatically Verify if the Calculations for Waveform Parameters are Completed?

FAQ

How do I use the DLM2000 Mixed Signal Oscilloscopes Enhanced Parameter Measurement and Calculation Feature?

FAQ

How do I Measure Delay on the DL850?

FAQ

How Can I Effectively Achieve a Sample Rate Less Than 5 Sa/sec on the Yokogawa DL850 ScopeCorder?

FAQ

Why do I Need to use a Hub When Communicating With the Instrument via Ethernet?

FAQ

Why Can't I Connect to My DLM Oscilloscope Using DL-GATE?

FAQ

What is the Sanitation Procedure for Yokogawa Oscilloscopes?

FAQ

What is the Meaning of "Header Size" for an ASCII Format Data File?

FAQ

Why Does the DLM6000 Mixed Signal Oscilloscope Show the Network Icon After it has Been Initialized Back to Factory Default Settings?

FAQ

What is the Difference Between Offset and Position on the DL Series Oscilloscopes?

FAQ

How can I Express an Arbitrary Exponentiation Other Than the Square and Cube Computation Function in XViewer?

FAQ

What is the DC Accuracy When the Waveform Position has Been Changed?

FAQ

Can Xviewer Combine the Binary Format Data Files Saved by Different Products?

FAQ

How Much Residual Noise Should There be on a Yokogawa Oscilloscope?

FAQ

What is the Recommended Sampling Rate for CAN Bus or I2C Analysis on the DL Series Instruments?

FAQ

What is the Difference Between the DL/DLM Series IEC Harmonic Measurement and the WT3000 Precision Power Analyzer IEC Harmonic Measurement via the Harmonic Analysis Software?

FAQ

Is VXI-11 Required for a DLM2000 Mixed Signal Oscilloscope to Xviewer Connection Over Ethernet?

FAQ

How Many Math Channels are Available on the DL/DLM6000 Digital Oscilloscope?

FAQ

Why is the Sample Rate and HResolution Not Equivalent in an ASCII File Saved by a DL Series Oscilloscope?

FAQ

Can the /F3 and /F4 Trigger and Analysis Options be Installed on the Same DLM6000 unit?