**8. Conclusion**

*LabVIEW - A Flexible Environment for Modeling and Daily Laboratory Use*

**5. Medical applications**

these devices.

**6. Education**

NI-IMAQ software and CompactRIO DAQ.

**7. Miscellaneous applications**

LabVIEW is applicable for standalone as well as moving system design. Wherever the application of a mixed system comes then the design complexity will increase and monitoring will be more complicated. Here the graphical user interface [11] will be more useful to control the action of the system and its programming.

Jung et al. [12], integrated the flexible multimodal sensor based E-Skin which will mimic the skin in human beings. The sensors like temperature, pressure, flow and humidity everything has been included to create the characteristics of human skin. To measure the varying resistance in the hair sensor they customized the PC-Controlled Servomotor LabVIEW Tower Pro SG 90 and PC-recordable acquisition board NI USB-6218. The E-Skin plays vital role in soft electronics to enhance the Human-Machine Interface (HMI) for analyzing the ECG, EMG and other parameters. The wearable and flexible electronics [13] paves the way for comfort in using

Many real time remote –based laboratory models have been constructed to help the students in schools and higher education institutions to perform the research and gain the knowledge from their own location itself. Several laboratories including the light sensing experiment designed by Singh et al. [14] using LabVIEW, LDR and LM35 sensor, the phasor estimation algorithm using NI ELVIS kit designed by Mondal et al. [15], operational process monitoring application using SHRIMP VL application, analog electronics experiment using "RedPitaya" [16] etc. The LabVIEW has been effectively and efficiently included in many studies in literature to enhance and boost the research community. Polat et al. [17], designed the Distance Vocation Education and Traning D-VET to monitor the lighting levels of LED lamps in remote laboratory with the help of PID controller, Sensor, Actuator,

Azenova et al. [18] designed an e-learning course for second year industrial students under the category of laboratory experiments in electronics. The LabVIEW is incorporated in the Goodyear e-learning model they have adopted for implementing to their students. The basic laboratory experiments like clipper, clamper, inverting and non-inverting amplifier, summing and differential amplifier were

The fault detection in analog circuit can be easily analyzed with the help of LabVIEW interfaces using deep forest learning method. Zhen et al. [19] have designed the fault diagnosis scheme with the Waveform generator Agilent 33250, Data acquisition module NI 1042q, LabVIEW, Digital oscilloscope Agilent 54853 along with power supply and testing circuit. The outputs of testing circuit are collected by data acquisition module and stored in the LabVIEW and used for further

For assessing the quality of water to ensure the living of aquatic species like fishes in a healthy environment. Othman et al. [20], proposed a system using the sensors to measure the pH level and temperature of the water in the tank. The data

simulated with the help of virtual instruments front panel in LabVIEW.

**122**

diagnosis.

The applications of LabVIEW in electronics and communication field has been presented in this chapter. The role of LabVIEW in Speech signal processing, Photovoltaic cell emulator, Fault diagnosis scheme, Cognitive radio signal analysis, FESTO workstation control, Water tank surveillance, Embedded system like the Crude Oil Separator, smart turf harvesting machine and robotics applications were discussed briefly. The demonstration and exploration of laboratory courses for school and college students are in reach of hand because of the interface provided by the LabVIEW and source of the Internet.
