How Maxima Automation is Transforming Industrial Efficiency Through Customized Automation Solutions

Introduction

In today’s competitive industrial landscape, efficiency, safety, and data accuracy are non-negotiable. Since 2009, Maxima Automation has been helping industries across India and beyond achieve these goals with advanced, custom-built automation solutions.

Why Industrial Automation Matters

With rising production demands and stricter safety regulations, industries require more than off-the-shelf tools. Industrial automation not only reduces human error but also ensures real-time monitoring, faster throughput, and better compliance. At Maxima Automation, we engineer solutions that integrate seamlessly with your existing infrastructure.

Our Core Solutions

1. Data Acquisition Systems (DAQ)

We design scalable, real-time data acquisition systems tailored for test stands, environmental monitoring, and manufacturing analytics. Our DAQ systems are known for:

High-speed data logging

Modular architecture

Cloud-ready integration

Secure storage and retrieval

2. Gas Detection Systems

Safety is our priority. Our gas detection systems include portable and fixed detectors for hazardous gases, featuring:

ATEX-certified components

Phosgene badge integration

Custom calibration for site-specific requirements

3. Automated Test Equipment (ATE)

For industries such as aerospace, electronics, and automotive, our automated test benches deliver repeatable, high-precision results. Features include:

Multi-sensor integration

LabVIEW-based interfaces

Data visualization dashboards

4. Modular Skid Systems

These plug-and-play units support chemical injection, calibration, and sampling, built to exact industry standards.

Who We Serve

Maxima Automation supports clients in:

Oil & Gas

Aerospace & Defense

Pharmaceuticals

Energy & Utilities

Research Labs

Our team works closely with OEMs, EPC contractors, and industrial consultants to deliver tailored results.

Why Choose Maxima Automation?

Over 15 years of proven expertise

In-house design, development, and support

Focus on compliance, scalability, and sustainability

Global reach with local engineering expertise

Final Thoughts

Whether you're looking to enhance safety with reliable gas detection, optimize operations with DAQ systems, or streamline testing with automated solutions, Maxima Automation is your trusted partner.

Virtual Instrumentation: Revolutionizing Measurement and Automation

In today’s digital era, traditional measurement and control systems are being replaced by Virtual Instrumentation (VI), offering greater flexibility, accuracy, and efficiency in data acquisition, analysis, and automation. Virtual Instrumentation integrates hardware and software to create powerful, customizable measurement and testing solutions, making it a game-changer in engineering, research, healthcare, and industrial automation.

What is Virtual Instrumentation?

Virtual Instrumentation is a software-based approach to measurement and automation that replaces physical instruments with PC-based software and modular hardware components. Instead of using fixed-function devices, VI allows users to build customized measurement systems that meet their specific needs.

How Does Virtual Instrumentation Work?

A Virtual Instrumentation system consists of three main components:

Data Acquisition (DAQ) Hardware – Collects real-world signals from sensors and converts them into digital data.

Software (Graphical or Programming-Based Interface) – Processes and analyzes data using platforms like LabVIEW, MatDeck, or Python.

PC or Embedded System – Runs the software and provides visualization through dashboards and graphs.

Key Features of Virtual Instrumentation

✔ Customizable & Scalable – Users can design specific measurement and automation systems tailored to their needs. ✔ Multi-Sensor Integration – Connects multiple devices such as sensors, transducers, and controllers. ✔ Real-Time Data Processing – Provides instant signal analysis and control feedback. ✔ Graphical User Interface (GUI) – Interactive visual elements for monitoring and control. ✔ Cost-Effective – Eliminates the need for multiple physical instruments, reducing expenses.

Applications of Virtual Instrumentation

Virtual Instrumentation is widely used across multiple industries, including:

1. Engineering & Industrial Automation

Real-time monitoring of temperature, pressure, and vibration in manufacturing plants.

Automation of quality control and testing procedures in production lines.

Control of robotic and embedded systems in smart factories.

2. Scientific Research & Laboratories

Physics and chemistry experiments requiring precise measurements.

Environmental monitoring for air and water quality analysis.

Biomedical research involving signal processing for healthcare innovations.

3. Automotive & Aerospace Testing

Performance testing of engines, braking systems, and fuel efficiency.

Aircraft sensor calibration and diagnostics for safety compliance.

Simulation of space missions and satellite telemetry systems.

4. Healthcare & Medical Devices

Patient monitoring systems for tracking heart rate, blood pressure, and ECG.

Medical imaging and diagnostics using signal processing algorithms.

Automated lab equipment for drug testing and bioinformatics research.

Virtual Instrumentation with MatDeck

MatDeck provides an advanced virtual instrumentation environment, offering tools for:

✔ Data Acquisition & Signal Processing – Supports multiple DAQ hardware like Advantech, ICP DAS, and LabJack. ✔ SCADA & Remote Monitoring – Control industrial processes through real-time dashboards. ✔ No-Code Drag & Drop GUI Development – Create custom instrumentation panels with minimal programming. ✔ AI & Machine Learning Integration – Automate data analysis using artificial intelligence models.

Advantages of Virtual Instrumentation Over Traditional Instruments

FeatureVirtual InstrumentationTraditional InstrumentsCustomization✅ Highly flexible❌ Fixed functionalityScalability✅ Expandable & modular❌ Limited to specific tasksReal-Time Analysis✅ Instant data processing❌ Requires external analysisCost-Effectiveness✅ Lower cost, fewer physical devices❌ Expensive standalone instrumentsRemote Access✅ Accessible from any location❌ On-site only

Conclusion

Virtual Instrumentation is transforming the way we measure, analyze, and automate processes across industries. By integrating hardware, software, and real-time data processing, it enhances accuracy, efficiency, and cost-effectiveness in research, engineering, and automation.

With platforms like MatDeck, LabVIEW, and Python, businesses and researchers can develop customized, scalable, and intelligent instrumentation solutions, paving the way for a smarter and more connected world.

WHAT IS DATA ACQUISITION (DAQ)?

Data Acquisition Systems have its contribution in a wide range of activities of day-to-day life. Most commonly, it is used to measure the electrical signals from some sensor.it is often referred, is the process of digitizing data from the world around us so it can be displayed, analyzed, and stored in a computer.

DAQ system applications are usually controlled by software programs developed using various using general purpose programming language such as Assembly, BASIC, C, C++, C#, Fortran, Java, LabVIEW. TMCS is NI Silver Alliance Partner we also provide LabVIEW Software offshore consultation.

for responsive DATA ACQUISITION (DAQ) services you can visit to TMCS

LabVIEW Data Acquisition System 

Data acquisition is a critical aspect of various industries, from scientific research to industrial automation. LabVIEW, developed by National Instruments, offers a powerful platform for designing and implementing data acquisition systems efficiently. In this article, we'll delve into the intricacies of LabVIEW data acquisition systems, exploring their components, setup, programming, benefits, applications, case studies, challenges, and future trends. 

Introduction to LabVIEW Data Acquisition System 

Understanding Data Acquisition Systems 

Data acquisition systems are instrumental in collecting and processing data from physical phenomena or systems. These systems typically consist of sensors, signal conditioning hardware, and software for data processing and analysis. 

Importance of LabVIEW in Data Acquisition 

LabVIEW stands out as a premier software tool for data acquisition due to its user-friendly graphical programming interface and extensive library of functions for signal processing, analysis, and visualization. 

Components of a LabVIEW Data Acquisition System 

Hardware Components 

A LabVIEW data acquisition system comprises various hardware components, including sensors, signal conditioning modules, data acquisition devices (DAQ), and interfaces for connecting with external devices. 

Software Components 

LabVIEW software provides the programming environment for configuring, controlling, and monitoring data acquisition processes. It offers a wide range of built-in functions and libraries for seamless integration with hardware components. 

Setting Up a LabVIEW Data Acquisition System 

Installation Process 

Setting up LabVIEW involves installing the software on a compatible computer system and configuring it to communicate with the hardware components of the data acquisition system. 

Configuring Hardware 

Once the software is installed, users need to configure the hardware components by selecting appropriate drivers and setting up communication protocols within the LabVIEW environment. 

Programming in LabVIEW for Data Acquisition 

Basics of LabVIEW Programming 

LabVIEW programming involves creating virtual instruments (VIs) using a graphical programming language known as G, which utilizes a block diagram approach for visual representation of code. 

Data Acquisition Techniques 

LabVIEW offers various data acquisition techniques, including analog and digital input/output, voltage measurements, frequency measurements, and waveform generation, all of which can be implemented through intuitive programming constructs. 

Benefits of Using LabVIEW for Data Acquisition 

Versatility and Flexibility 

LabVIEW provides a versatile and flexible platform for designing custom data acquisition systems tailored to specific application requirements. 

Integration with Other Systems 

LabVIEW seamlessly integrates with other systems and software tools, allowing for interoperability and compatibility with existing infrastructure. 

Scalability and Customization 

LabVIEW offers scalability, enabling users to expand their data acquisition systems as per evolving needs, along with extensive customization options for optimizing performance. 

Applications of LabVIEW Data Acquisition System 

Industrial Automation 

LabVIEW data acquisition systems find extensive applications in industrial automation for monitoring and controlling processes in manufacturing, quality assurance, and product testing. 

Scientific Research 

In scientific research, LabVIEW facilitates data collection and analysis in diverse fields such as physics, chemistry, biology, and environmental science, enabling researchers to conduct experiments and gather insights efficiently. 

Medical Monitoring 

LabVIEW-based data acquisition systems play a crucial role in medical monitoring applications, including patient monitoring, diagnostic equipment, and biomedical research, aiding in the advancement of healthcare technologies. 

Environmental Monitoring 

LabVIEW is utilized for environmental monitoring tasks such as weather forecasting, pollution detection, and ecological research, contributing to the preservation and sustainability of natural resources. 

Case Studies: Real-World Implementations 

Case Study 1: Automotive Testing 

LabVIEW data acquisition systems are employed in automotive testing facilities for evaluating vehicle performance, conducting crash tests, and analyzing vehicle dynamics under various conditions. 

Case Study 2: Weather Monitoring 

Meteorological agencies utilize LabVIEW-based data acquisition systems for collecting and analyzing weather data, including temperature, humidity, wind speed, and precipitation, to forecast weather patterns accurately. 

Case Study 3: Biomedical Research 

In biomedical research laboratories, LabVIEW facilitates the acquisition and analysis of physiological data, imaging data, and genetic data, supporting advancements in disease diagnosis, treatment, and drug development. 

Challenges and Solutions in LabVIEW Data Acquisition 

Compatibility Issues 

One challenge in LabVIEW data acquisition is compatibility issues between hardware components and software versions, which can be mitigated through careful selection and configuration of compatible components. 

Data Processing Challenges 

Processing large volumes of data in real-time poses another challenge, requiring efficient algorithms and hardware optimization techniques to ensure timely and accurate data acquisition and analysis. 

Calibration and Maintenance 

Regular calibration and maintenance of hardware components are essential to maintain the accuracy and reliability of LabVIEW data acquisition systems, requiring adherence to best practices and standards. 

Future Trends in LabVIEW Data Acquisition 

Advancements in Hardware Technology 

Future advancements in hardware technology, such as faster processors, higher-resolution sensors, and wireless connectivity, will enhance the performance and capabilities of LabVIEW data acquisition systems. 

AI Integration 

Integration of artificial intelligence (AI) algorithms into LabVIEW data acquisition systems will enable predictive analytics, anomaly detection, and autonomous decision-making, revolutionizing data acquisition processes. 

IoT Integration 

LabVIEW data acquisition systems will increasingly integrate with the Internet of Things (IoT) ecosystem, leveraging cloud computing, edge computing, and wireless sensor networks for enhanced connectivity, scalability, and interoperability. 

Conclusion 

LabVIEW data acquisition systems offer a comprehensive solution for collecting, processing, and analyzing data across various industries and applications. With its user-friendly interface, robust functionality, and versatility, LabVIEW continues to empower engineers, researchers, and scientists in their quest for innovation and discovery. If you want to read more blogs/articles so visit on PujaControls

A Guide To Data Acquistion System - TMCS India

A data acquisition system is a system that consists of a computer, measurement devices, and sensors. Processing acquired data requires a data acquisition system, which gathers the information needed to comprehend electrical and physical processes. 

For the purposes of engineering or scientific research, data acquisition systems can collect information about a real-world system and store it in an understandable, retrievable manner.

Essential components of Data Acquisition System:  

Sensors:

Interacting with the entity being measured is the primary function of sensors and transducers. They convert physical phenomena like light, temperature, pressure, position, sound, etc. into a measurable signals like Voltage & Current. 

Signal Conditioners:

The electrical signals collected by the sensors may be distorted by noise or interference and require processing before they can be used. Sometimes the signals are too weak for the data acquisition system to pick up. As a result, supplementary circuitry is employed for signal optimization. A signal conditioner is a technical term for this additional hardware. Therefore, signal conditioning is the act of making the signals as error-free as possible.

Analog-to-Digital Converters:

This DAQ module is responsible for digitizing analog inputs. It is the function of this chip to take information from its surrounding environment and translate it into discrete levels that a computer can understand.

Software Application (NI LabVIEW):

NI LabVIEW is well equipped for creating DAQ applications and it also supports many hardware devices. Within a manufacturing environment, LabVIEW is widely used for automated product testing, becoming the standard for the industry. Possible Integration with multiple hardware platforms makes LabVIEW  the a Preferred Software development platform  for engineers, designers and research scientists.

Parameters Measured on DAQ:

Many different parameters can be measured using a data acquisition system, including the following:

* Current

* Voltage

* Strain

* Frequency or time interval

* Pressure

* Temperature

* Distance

* Vibration

* Angles

* Digital signals

* Weight

Benefits of DAQ System:

* Accurate 

* Flexible 

* Scalable 

* Programmable 

DAQ Applications:

Automotive:

In order to ensure that the manufactured automobile parts are of the highest quality, data acquisition software & equipments are used.

NI Instruments: 

The data acquisition (DAQ) devices offered by National Instruments are organized into distinct groups to facilitate the quick and simple selection. Types of these systems, such as temperature and strain, or common form factors, are used to quantify them.

Aerospace Defense: 

Data acquisition products are used by virtually every aerospace industry and flight testing facility. These systems can function in a wide variety of contexts and conditions. Every DAQ system is put through its paces in the lab, in the telemetry control room, on the engine test stand, and on the flight line to make sure it performs as well as it needs to. 

There are a wide variety of uses for these systems, including monitoring direct analog inputs or digitized parameters being tele-metered from an aircraft to a ground monitoring station, flight testing, range safety, missile testing, maintenance, and troubleshooting on (or next to) an aircraft, electromechanical testing in an aircraft hangar, component testing & validation, structural testing on military vehicles, and more.

Electronics:

The electronics sector makes use of data acquisition systems. They are used to measure heat output, resistance, conductivity, magnetics, etc., all of which play a role in electrical design.

What is Data Acquisition System?

Data Acquisition (DAQ) is the method of measuring electrical as well as physical factors such as voltage, current, pressure, temperature, fluid flow, etc. sampling signals that

measure real world physical conditions and converting the resulting samples into digital numeric values that can be manipulated by a computer. DAQ system applications are

usually controlled by software programs developed using various general purpose programming languages (LabVIEW)

Labview for mac 10.68

#Labview for mac 10.68 for mac os x#

#Labview for mac 10.68 mac os x#

#Labview for mac 10.68 serial#

#Labview for mac 10.68 drivers#

#Labview for mac 10.68 update#

This solution is appropriate for smaller, lessĬomplex, systems that don't require the features and abstraction provided Standard phone and email support is not available for the Only through online newsgroups, downloads, and register-level programming The Measurement Hardware DDK is designedįor advanced customers developing OEM type systems. Programming tools for NI PCI Data Acquisition devices. The Measurement HW DDK provides a set of multi-platform, register-level Measurement Hardware Driver Development Kit (freeload). Reliable/robust platform and that you do need to maintain another machine.įor native support NI has made available the The drawbacks are that a plain beige box PeeCee is not the most However the Pharlap OS has a reputation of being fairly cleanĪnd robust to avoid the normal problems associated with more common desktop Supporting the hardware of a cheap wintel box and the time labor associated With compatibility to all of NIs hardware. This will allow development in a clean, reliable and efficient environment Network problems isolated from data transfer and control. Probably throw a second cheap ethernet interface in the host to keep Mac OS X and LV 7.1 now support cross compiling for the RT/OS. Recommended it seems that the RT/OS will boot and run on most hardware. Realtime target can be any cheap PC, though NI lists some systems as With LabVIEW 7.1 the "host PC" can be an Apple MacIntosh running OS X! The The link gives a list of supported boards and hardware. This gets around the extreme cost of a PXI crate andĮmbedded hardware. Use a cheap PC as the host for all the hardware running the PharLap RT/OS as There is another little known solution that lets one use the bestĭevelopment environment with NI hardware. Theĭrawbacks of this approach is that the PXI crate is expensive and very Systems that need the features and abstraction provided by NI-DAQ. This solution is appropriate for larger, more complex,

#Labview for mac 10.68 mac os x#

Development is done a Mac OS X system using LabVIEW and deployed NI-DAQ, the driver for NI data acquisition devices, runs on the PXIĬontroller. The first, involves a PXI chassis containing NI PXIĭata acquisition devices and an NI RT-series PXI controller running LabVIEW NI PCI Data Acquisition devices are supported in So again this is a cross platform solution!ĭAQ is a bit trickier. Units running under OS X This uses the new release of NI-VISA which There was also a public demo of the new USB-DAQ Pretty cool that they use LabVIEW to create a C driver. Interface, the C interface will be a subset of the NI-DAQmx C API. Writing the driver in LabVIEW and then using the Application Builder toĬreate a shared library for the C interface. There is be a C interface for NI-DAQmx Base. It is based on Tim Ousley's DDHKĪnd is mostly written in LV! DMA is supported. Support for M series cards will be coming soon (Q1 2005?). The LabVIEW VIs work with LabVIEW 7.0 and higher. NI-DAQmx Base 1.4 supports NI 6508/DIO-96, PCI/PXI E Series, PCI/PXI B Series, PCI/PXI 671x/673x, S Series (AI only), USB-92xx, USB-6008, USB-6009 and USB-6501 devices on Mac OS X.

#Labview for mac 10.68 for mac os x#

Their DDK is not all that completeĪnd is why the driver does not integrate seamlessly into the current VISAĭriver for Mac OS X 10.3 and 10.2 that should work with more cardsīase has been released. The driver is based on NI's DDK and theirĬode has to be purchased, however I am willing to make my patches andĬhanges to this code freely available.

#Labview for mac 10.68 update#

I recommend trying the second file that has much improvedĪ Mac OS X 10.3.X (Panther version) is done as well as a significant update This file has only been tested under OS Xġ0.2.X (Jaguar). Currently you need to do the installation by hand, but the Used successfully for work with both LabVIEW and Igor to access GPIBĭevices. This driver seems to work well and has been The bulk of the work and the inital port was done by Bela Farago However a few of us have created a native OS X driver for the GPIB card,

#Labview for mac 10.68 drivers#

Than a PCI card, it also requires that the drivers be purchased in addition There is a private beta of the National Instruments PCI-GPIB driver! Join the beta program.įor GPIB access, NI recommends use of their ENET-GPIB device thatĬommunicates thru TCP/IP to a GPIB interface. If you use it under classicĮmulation use the drivers installed under classic.

#Labview for mac 10.68 serial#

The Keyspan Twin Serial adaptor seems to work. However all previous versions do run under classic emulationĪccess to instruments can be made thru ethernet (tcp/ip) and serial ports. As of LabVIEW version 7.X, Mac OS 9 will not be It is fully functional and is compatible with LabVIEW on all LabVIEW was released for OS X starting in June of 2003 when version 7.0 was LabVIEW from National Instruments under Mac OSX. I am trying to put together as much as I know about the options for running

low-cost portable data acquisition device

low-cost portable data acquisition device

USER GUIDE AND SPECIFICATIONS NI myDAQ Figure 1. NI myDAQ NI myDAQ is a low-cost portable data acquisition (DAQ) device that uses NI LabVIEW-based software instruments, allowing students to measure and analyze real-world signals. NI myDAQ is ideal for exploring electronics and taking sensor measurements. Combined with NI LabVIEW on the PC, students can analyze and process acquired signals and…

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low-cost portable data acquisition device

low-cost portable data acquisition device

USER GUIDE AND SPECIFICATIONS NI myDAQ Figure 1. NI myDAQ NI myDAQ is a low-cost portable data acquisition (DAQ) device that uses NI LabVIEW-based software instruments, allowing students to measure and analyze real-world signals. NI myDAQ is ideal for exploring electronics and taking sensor measurements. Combined with NI LabVIEW on the PC, students can analyze and process acquired signals and…

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low-cost portable data acquisition device

low-cost portable data acquisition device

USER GUIDE AND SPECIFICATIONS NI myDAQ Figure 1. NI myDAQ NI myDAQ is a low-cost portable data acquisition (DAQ) device that uses NI LabVIEW-based software instruments, allowing students to measure and analyze real-world signals. NI myDAQ is ideal for exploring electronics and taking sensor measurements. Combined with NI LabVIEW on the PC, students can analyze and process acquired signals and…

View On WordPress

low-cost portable data acquisition device

low-cost portable data acquisition device

USER GUIDE AND SPECIFICATIONS NI myDAQ Figure 1. NI myDAQ NI myDAQ is a low-cost portable data acquisition (DAQ) device that uses NI LabVIEW-based software instruments, allowing students to measure and analyze real-world signals. NI myDAQ is ideal for exploring electronics and taking sensor measurements. Combined with NI LabVIEW on the PC, students can analyze and process acquired signals and…

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Data acquisition software

Information Acquisition (DAQ) Software

Dewesoft has been creating driving information obtaining (DAQ) programming for over 20 years. Dewesoft X is the world's best information procurement (DAQ), information recording, and information examination programming.

 The product got numerous global honors, is inventive, extremely simple to utilize, and requires no programming to get, store and examine information synchronized from a few information sources - simple, computerized, CAN, CAN FD, CXP, GPS, video, sequential and numerous different information interfaces.

There are as a wide range of programming programs as there are utilizes for the data gotten. Most all product frameworks perform two significant stages, information assortment and information mining, in information obtaining frameworks. Information assortment is the most common way of gathering and sorting out measurements and data, while information mining includes tracking down designs in huge arrangements of information. Information procurement programming gives the important point of interaction among sensors and human administrators.

 These projects transform enormous informational collections into reasonable and significant data which can be utilized to control or test hardware. Information can likewise be introduced in different structures to find designs and significant elements. This sort of programming is every now and again established utilizing programming conditions like LabVIEW, MATLAB and Visual C++, contingent upon the planned utilizations of the product.

 Information procurement programming is utilized to screen conditions in various sorts of conditions. Historical centers and food storerooms depend on information securing programming to keep a consistent temperature level. Producers use information securing frameworks to screen their hardware and to make any important changes.

Information securing programming is utilized to control test conditions, enact wellbeing alerts, and manage temperature in delicate conditions. The product can likewise be utilized to perform programmatic experiences to test hardware and parts.

https://www.cloudquant.com/

About I²C

  I²C is a multi-master protocol that uses two signal lines. The two I²C signals are named ‘serial data’ (SDA) and ‘serial clock’ (SCL). There is no need of chip select (servant select) or compromise logic. Basically, any number of servants and any number of masters can be united onto these two signal lines and correspond to each other using a protocol that specifies:

• 7-bits servant addresses: every device united to the bus has got such a unique address;

• certain control bits for governing the communication commence, end, and direct for any acknowledgement mechanism.

• data are divided into 8-bit bytes

The data standard must be chosen betwixt 100 kbps, 400 kbps and 3.4 Mbps, accordingly called standard mode, a fast mode and high-speed mode. Some I²C variations contain 10 kbps and 1 Mbps as genuine speeds. Physically, the I²C bus comprises the two active wires SDA and SCL and a ground connection. The effective wires are both bi-directional. The I2C protocol necessity states that the IC that begins a data transfer on the bus is treated the Bus Master. Therefore, at the time, all the other ICs were considered to be Bus Servants.

At electrical rank, there is literally no conflict at all if multiple instruments try to put any logic rank on the I²C bus lines together. If one of the drivers attempts to write a logical zero and the other a logical one, then the open-drain and pull-up arrangement ensure that there will be no shortcut and the bus will indeed see a logical zero transiting on the bus. In other words, in any conflict, a logic zero always ‘scores’.

Furthermore, the I²C protocol likewise helps at dealing with communication problems. Any apparatus present on the I²C listens to it permanently. Promising masters on the I²C encountering a START condition will wait until a STOP is encountered to attempt a new bus admission. Servants on the I²C bus will decode the device address that follows the START condition and checks if it doubles theirs. All the servants that are not addressed will wait until a STOP status is issued before listening repeatedly to the bus. Likewise, since the I²C protocol foresees active-low acknowledge bit after each byte, the master/servant couple can identify their counterpart presence. Ultimately, if anything else goes bad, this would signify that the apparatus ‘talking on the bus’ would know it by simply comparing what it sends with what is seen on the bus. If a difference is detected, a STOP case must be issued, which discharges the bus.

CONSULTATION SERVICES – TMCS

National Instruments software has been a technical pioneer and leader in virtual instrumentation for than four decades, a groundbreaking notion that has altered the way engineers and scientists in business, government, and academia approach measurement and automation. Everything from prototyping and probability analysis to project management and the integration of third-party software and hardware may be done quickly.

TMCS is a National Instruments, USA Silver Alliance Partner (system integrator/applications expert) capable of handling system design, system integration, and applications engineering utilizing any combination of National Instruments' high-performance software and hardware solutions.

OUR CAPABILITIES INCLUDE

Turn-key Systems Engineering

Software Development for Measurement, Data Acquisition, and Control Applications

System Engineering, Hardware and Software for Sophisticated Networks for Distributed Data Acquisition and Control Systems

Design and Assembly of Complete Control Panels and their Integration

Data Acquisition Systems

Data Acquisition Systems often referred, as the process of digitizing data from the world around us so it can be displayed, analyzed and stored in a computer. DAQ system applications are usually controlled by software programs developed using various programming language such as C, C++, Python, NI LabVIEW.

Data acquisition is a critical component of contemporary test and measurement systems, and National Instruments LabVIEW (short for Laboratory Virtual Instrument Engineering Workbench) is a prominent software tool for this purpose. LabVIEW is a graphical programming language that enables engineers and scientists to rapidly and simply construct unique test and measurement applications.

One typical use for NI LabVIEW is the creation of test benches, which are systems meant to automate the testing of electrical or mechanical components. These test bench may be used to do functional testing, stress testing, and other sorts of testing, and they can considerably increase the efficiency and accuracy of testing operations.

NI 6001 Multifunction I/O- Based System

USB Multifunction I/O Device – 8 AI (14-Bit, 20 KS/s), 2 AO (5 KS/s/Ch), 13 DIO  

Description:

Multifunction I/O device

32-bit Counter

Data Logging

Portable Measurements

Data Acquisition system for Verification Validation

NI CDAQ 9185 for Data Acquisition

CompactDAQ Chassis – 4-Slot, TSN-Enabled Ethernet CompactDAQ Chassis

Description:

Controls Timing Synchronization between NI modules and host

Connectivity Options – USB, Ethernet, Wi-Fi

Multiple Hardware timed operations

For limited channel count data acquisitions which needs measurement from multiple networks, signals and sensors, the Compact DAQ is the ideal choice.

NI CDAQ 9181 for Data Acquisition

CompactDAQ Chassis 1 Slot, Ethernet CompactDAQ Chassis

Description:

Created for compact, decentralized sensor measurement systems.

Manages the timing synchronization of NI modules with the host

May be used to produce a mix of analogue, digital, and counter/timer measurements by combining C Series I/O modules.

NI 9234 for Vibration Monitoring system

C Series Sound and Vibration Input Module, 2-Channel, 102.4 KS/s/Ch Simultaneous, ±5 V

Description:

Vibration and Sound Input Module

software-selectable coupling for AC/DC

IEPE short/open detection,

Signal conditioning for IEPE

Signal conditioning for IEPE

Comes with the NI DAQmx driver setup tool.

Supports Python, C++, and NI programming environments.

The system calculates displacement, velocity, and acceleration.

This is the CLAD Preparation Video series on LabVIEW Advantage. Resources to pass CLAD Exam: NI Training: LabVIEW Core 1, Core 2, and DAQ: https://goo.gl/Pb793D CLAD Preparation Sample Exam: https://goo.gl/hqL3FF Daily CLAD NI Forum Blog: https://goo.gl/Kr2D35 Facebook: https://goo.gl/RPFRWc Youtube: https://goo.gl/ygVMJ8 Twitter: https://goo.gl/VXj10d Tumblr: https://goo.gl/dyFckX Blog: https://goo.gl/DtG8sa Wordpress: https://goo.gl/Cf7xoN Pinterest: https://goo.gl/X0lFev Ram Gurung is a CLA and LabVIEW Training and Certification Expert. He has been training scientists, engineers, and students to develop robust and relatively future proof applications using LabVIEW and NI tools. He has trained and produced 70+ CLDs so far and more in the making. Gain the advantage on accelerating your LabVIEW Programming by subscribing and learning from his channel. Take advantage of Free LabVIEW Training Videos LabVIEW Training Videos Category: CLAD Disclaimer: NI and LabVIEW are the product and trademarks of National Instruments. This channel is independent of National Instruments. No copyright infringement is intended. The videos are made solely for informational and educational purposes. The ideas, concepts, and videos are of only of this channel. In some cases, materials from other sources has been used to analyze the problem to help the viewers. For e.g. Daily CLAD forum questions. All the materials that are third party depicted in this channel are properties of their respective owners. If you believe the copyright infringement has occurred. Please contact at [email protected] and we will remove from the video. Getting Started with NI LabVIEW Basic LabVIEW - Tutorials An Introduction to LabVIEW Searches related to labview tutorial labview 2010 tutorial labview tutorial pdf labview download labview tutorial video labview 2009 tutorial labview 8.5 tutorial labview training labview 2012 tutorial

ノックマンとチリリンでタイプライター。 LabVIEW 2020とUSB-6008マルチファンクションDAQを使用。 #明和電機 #LabVIEW https://t.co/D3nZwnlUll http://twitter.com/umelog/status/1300782558557302789