Hioki Usb Cdc Driver

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Aug 3, 2024, 2:22:35 PM8/3/24

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The copyright to the executable program file and associated documents is owned by HIOKI E.E. CORPORATION. This utility may not be bundled with software or other publications which are sold for profit without the express written permission of the copyright owner.
Further, this product may not be modified without the express written permission of the copyright owner.

Hioki welcomes opinions, suggestions, operation reports, and bug reports. Please send such communications to the following address.
Hioki reserves the right to incorporate any suggestions and opinions received in its products without notice.
E-mail: os-...@hioki.co.jp (International Sales and Marketing Section)

*HIOKI welcomes opinions, suggestions, operation reports, and bug reports. Please send such communications to the following address.
*HIOKI reserves the right to incorporate any suggestions and opinions received in its products without notice.
*E-mail: os-...@hioki.co.jp (HIOKI E. E. CORPORATION, International Sales and Marketing Section)

1. These are LabVIEW drivers for Model PW8001 Power Analyzer.
2. This LabVIEW driver can control and collect data from PW8001. However, it is not capable of controlling all functions. For details, refer to the Function Manual.
3. Please refer to "Sample Program Instruction.pdf" about the DEMO function.
4. The drivers are written and have been verified to work with LabVIEW2021.
If a driver is overwritten with a later version of LabVIEW, it will be unreadable with earlier versions of it.
5. This LabVIEW driver was created for firmware version "1.50" of the PW8001. There may be parts that behave differently from previous or later versions.

Version upgrade should be conducted by a qualified technician familiar with the functions and operations.
If you are uncertain as to how to proceed, please contact your local HIOKI distributor for assistance.

Install the USB driver before connecting the instrument to a computer with a USB cable. If they already connected, unplug the USB cable.
1 Log into the computer with administrative privileges such as "administrator."
2 Exit all applications that are running on the computer.
3 Unzip the downloaded file and run[HiokiUsbCdcDriver.msi] (driver installer).
It may take some time for the dialog box is displayed, depending on the system environment. Wait for the dialog box to be displayed.
4 After the installation is completed, connect the instrument and the computer with a USB cable.
The instrument is now recognized.
When the Hardware Wizard screen for new hardware is displayed, select [No, not this time] when "Windows Update" prompts to connect, and then select [Install the software automatically].
If an instrument with a different serial no. is connected, you may be notified that a new device has been detected. When this happens, install the USB driver by following the instructions on the screen.

If the driver listed is not the right version or operating system, search our driver archive for the correct version. Enter Hioki E.E. Hioki 3197 into the search box above and then submit. In the results, choose the best match for your PC and operating system.

After downloading your new driver, installation is the next step. On Windows, utilize the built-in Device Manager utility to manage this process. This tool provides a comprehensive view of all system-recognized devices and their associated drivers. To complete the installation, a system restart is typically required for the driver update to take effect.

This is the LabVIEW driver for LCR Meter IM3536.
This LabVIEW driver can control and collect data. However, it is not capable of controlling all functions. For details, refer to the Function Manual.

I was soaking in the scenery of Hioki as the taxi cruised up the mountainous roads, reflecting on the events that transpired to this moment. After about a month of planning, deciding on an itinerary in Kyushu days before my departure, and traveling almost the entire length of Kyushu itself the past few days, Kanosuke Distillery was going to be my first ever whisky distillery visit. My taxi driver engaged with some small talk with me, perhaps because he could sense the jitters from my seat, equal parts excitement and nervousness.

For starters, we went into the history of Komasa Jyozo. Komasa Jyozo produced sake at first, making premium rice sake (known as omiki お神酒) as offering to the gods at the local shrine. Over the years, Komasa changed to offering shochu instead, and this century-long tradition is still in practice today.

After seeing the stills, I was guided to the warehouse for the casks. There are a few warehouses at Kanosuke Distillery like the ones mentioned earlier, with this one being the closest to the stills. We have the Cask No. 1, No. 2, No. 3, and an ex- Mellowed Kozuru cask.

Nose: A mix between milk chocolate, dark chocolate and malt drinks. The peat smells a lot muddier and less oceanic or phenolic, when mixed with the chocolatey smells. This really reminds me of a chocolate fondue.

The WT500 Power Analyzer excels at single- and three-phase power measurements. Standard features include a color TFT display and USB interface for communications and memory. The instrument has a basic power accuracy of 0.1%, maximum inputs of 1000 V, 40 A and a measurement bandwidth of DC to 100 kHz.

Two USB ports for peripherals are installed for direct data saving (up to 1 G byte) in USB memory at shortest intervals.
The saved data can be opened in applications such as Excel.

* Excel is a registered trademark of Microsoft Corporation in the U.S.A.

In addition to numerical data, the WT500 can display input signal waveforms and trends (time variation of numerical data).
Bar graph display and vector display are also available with the harmonic measurement (/G5) option.

*1 Waveforms of up to approximately 5 kHz can be displayed.
*2 Excludes single-phase models.
Split screen display for numerical values and waveforms is not available.

Only necessary items within the measured data like voltage, current, and power can be saved in USB memory in binary or CSV format (up to 1 GB).

Files saved in CSV format can be opened in general-purpose applications such as Excel to allow displaying of data in graphs.

In addition to integration functions of active power (WP), current (q), reactive power (WQ), and apparent power (WS), a new feature provides measurement of bought and sold watt hours. Also, average active power can be calculated over an integration interval.
This feature is useful for evaluating the power consumed by intermittent-control instruments in which the power value fluctuates. Average active power is calculated by using user-defined settings.

Current can be measured by using current clamps without disconnecting power supply wiring (voltage output type). By setting an external current sensor conversion ratio, it can support various types of current clamp-on probes.

By connecting to a monitor, you can create large displays of numerical values and waveforms. This function is convenient for simultaneously confirming data on multiple monitors, or to check data remotely.

This function enables simultaneous measurement of normal and harmonic data. Harmonic components of up to the 50th order can be measured. With the WT500 you can simultaneously confirm voltage, current, and the distortion factor (THD) as well as measure the distortion factor without switching modes.

This function allows you to calculate individual phase voltages and phase currents from the line voltages and phase currents measured in a three-phase, three-wire (3P3W) system. The phase voltage can be calculated from the line voltage measured with the three-phase, three-wire (3V3A) method. This is useful when you want to determine the phase voltage in a DUT with no neutral line by using the three-phase, three-wire (3V3A) method.

In addition to the standard two channels of frequency measurement, an option is available for frequency measurement on all channels. This option provides frequency measurement of voltage and current on all channels with input elements 1 through 3 installed.This is necessary when you want to measure voltage and current frequency from the instrument's I/O as well as voltage and current frequencies of multiple items under test at the same time.

With increased focus on reducing energy consumption and compliance with efficiency standards, this app note provides an overview on the types of measurements needed for efficiency and power quality, and the instruments that take them.

Energy consumption in low-power and standby modes is an important issue due to increased awareness that energy resources are becoming limited and demand for energy-saving household electrical appliances continues to grow. IEC62301 Ed2.0 (2011) and EN 50564:2011 define standby mode as the lowest energy consumption of an appliance not performing its main function, when connected to the mains. IEC62301 Ed2.0 (2011) defines test methods and requirements for both the mains supply and the test equipment. It is crucial that design and test engineers choose highly accurate power measurement tools to confirm that their devices meet these requirements.