Yokogawa understands the unique demands of automotive and transportation. As vehicle technology continues to advance in the areas of safety, environmental friendliness, and comfort, Yokogawa test & measurement instruments continue to evolve and advance to support the increasingly complex electronic vehicle components, systems, and innovations. Yokogawa diligently provides up-to-the-minute technologies in Body Control, Safety Systems (ABS, Airbags, Rollover Prevention), Drivetrain performance, development, ECU (Electronic Control Unit), In-Vehicle Entertainment and various others. With foresight, Yokogawa also offers measuring instruments that will lead you into the future in five key areas: Hybrid Electric Vehicle (HEV), Fuel Cells, In-vehicle LAN, Vehicle components and Intelligent Transport System (ITS) equipment. Yokogawa also offers compliance test solutions such as CAN, the de-facto standard, and Advanced Power Analyzers, such as the SB5000 Serial Bus Analyzer with advanced functions for Flex-Ray technology, the protocol for incoming standards. These are just a few of the ways Yokogawa diligently strives to meet your evolving needs.
The DL850 can take engineers to a new level of efficiency in the development of everything from green devices to complex advanced systems.
The request for lower uncertainties in power measurements are increasing,especially in the transformer industries. Their role is to ensure that the electricity is distributed in an efficient and reliable way.
In recent years, energy-saving instruments including inverters have been actively developed. Researchers in R&D sections want to evaluate their prototypes in real time to enhance the development efficiency. Therefore, measuring instruments are required to have functions for not only simply recording data but also immediately calculating power values and efficiency based on the data. To meet this demand, Yokogawa has developed a unique real-time math function for the DL850 ScopeCorder, our multi-channel waveform recording instrument. This paper gives an overview of the function and its application examples.
This white paper describes the WT1800, a precision power analyzer that has been replaced by the WT1800E, a unit with numerous improvements including better accuracy. Please visit the WT1800E product page to learn more about the WT1800E.
To keep pace with the increasing speed of switching devices in inverters, Yokogawa has developed the WT1800 precision power analyzer with 10 times faster sampling speed and 5 times wider frequency bandwidth compared with previous models. Its basic accuracy is 0.15% and the frequency bandwidth of voltage and current is 0.1 Hz to 5 MHz (-3 dB, Typical) including the DC component. With up to six inputs, a single WT1800 unit can measure the efficiency of three-phase inverters. In addition, the high-speed data capturing mode allows the WT1800 to measure transient power. This paper describes the high-speed, real-time power measurement technologies underlying these functions.
This white paper describes the WT1600 precision power analyzer, a model that has been discontinued and replaced with the WT1800E. Please visit the WT1800E product page for more information regarding the WT1800E.
We have developed the WT1600, a high-precision, wide-bandwidth power meter. The WT1600 can measure DC and AC signals from 0.5 Hz to 1 MHz with a basic power accuracy of 0.1%. With the maximum of six input elements installed, a single WT1600 can measure the efficiency of a three-phase inverter. In addition to the functions of conventional power meters, it has wider ranges and various functions including waveform display. This paper gives an outline of the WT1600.
Battery Voltage Fluctuation During ABS Action
Measuring efficiency with high precision: simultaneous measurement of input and output
Observation of Inverter Switching Waveforms
Surge Waveform Recording & Power Monitoring
Knock Sensor Development
Voltage Probing Considerations for Electro-Mechanical Measurements
Measurement of Injection Timing
Evaluating Electrical Vehicles Non-Contract Charging Systems
Evaluating DC Power Supply for Office Automation Equipment
Construction and verification of SENT communication system
Evaluating Inverter Output Filters
Evaluating Starting Characteristics for Flurescent Lamps
Evaluating Inverter-Driven Microwaves
Transient Power Measurement of a Facsimile Machine
Power Distribution System Tests for Shorts and Switching
Evaluating Inverters and Motors
Large Capacity/Motor Characterization for Hybrid Car Development
Evaluating Electrical Vehicle Non-Contract Charging Systems
Testing Solenoids Used in Automatic Transmissions
Simple Creation of Indicator Diagrams (P-V Diagram)
Analysis of Engine Combustion Pressure
Misfire Analysis with Time Interval Analyzer
Evaluating Starting Characteristics for Flurescent Lamps
Timing Test of Side-Impact Air Bag
Testing Engine Valve Spring Strength
Measuring Conversion Efficiency of Power Conditioner
Evaluating Magnetic Components
Reference equipment for power calibration
Characteristics of Transient Response from Industrial Robots
Evaluating and designing the Electric Power Steering (EPS)
In this application note you will learn when and how to use different methods to connect a current transformer to a power analyzer.
If a product uses power, then power consumption and power quality measurements must be made as part of product design and test. These measurements are essential to optimize product design, comply with standards and provide nameplate information to customers.
This article will discuss best practices for making these measurements, starting with power measurement basics and proceeding to the types of instruments and associated components typically used to make measurements. The article will conclude with real-world examples, which apply the information imparted earlier in the article to solve practical measurement problems. Although most of us have been exposed to basic power measurement equations, a primer is helpful to summarize this information and to show how it applies to product design and test.
There are several factors for a user to consider when using an IEPE accelerometer, particularly when used with newly available integrated signal conditioner/data acquisition systems. Correctly managing these factors will help the user avoid erroneous data from their IEPE accelerometer and ensure the quality of the measurement data is at the level they expect and require.
One of the main responsibilities of engineers and technicians is data analysis, and this article will show how multi-touch technologies can be used to improve the performance of this and other related tasks.
How can I capture data from motion sensors synchronized with other analog data? The Yokogawa ScopeCorder series of instruments feature input modules and functions to make this possible.
Watch a step-by-step walkthrough of recording GPS position and motion data on the DL350.
In this video we review the major features of the DL350 showcasing its portability, functionality, and operability. This device features battery power, 18 signal conditioning input modules, and touchscreen access to enhanced triggers, math, and analysis.
In this video, Dami Ashebu, an Application Engineer with Yokogawa Test and Measurement discusses how a DL850EV data acquisition system can be used to gather various analog and serial bus data for systems validation and reverse engineering in the automotive industry.
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