Authors :
Aviral Tiwari ; Kavita Prajapati ; Pramod Singh
Volume/Issue :
Volume 9 - 2024, Issue 5 - May
Google Scholar :
https://tinyurl.com/3bn8d4a2
Scribd :
https://tinyurl.com/23j5mncf
DOI :
https://doi.org/10.38124/ijisrt/IJISRT24MAY2067
Note : A published paper may take 4-5 working days from the publication date to appear in PlumX Metrics, Semantic Scholar, and ResearchGate.
Abstract :
system is constructed using ultrasonic sensor
HC-SR04, ARDUINO UNO module, and LED display.
The ultrasonic sensor transmits ultrasonic pulses in the
form of waves and receives back the pulses after the
waves are reflected by an object. The time duration of
ultrasonic between transmission and reception is
calculated as the distance between the sensor and sample.
The method of thickness measurement adheres the
sample to the holder in front of an ultrasonic sensor. The
Thickness measurement of the sample is calculated based
on the distance between the sensor to the holder (fixed
barrier) and the sample to the sensor. The zero position
of the measurement is the distance of the sensor to the
holder.
The objective of THICKNESS CIPHER is to
minimize the use of Manual Gauges by decreasing the
time and manpower. The output of the Thickness gauge is
usually time-consuming and can be inappropriate due to
human error, which tends to the data loss. A thickness
meter is defined as an instrument that is used to quickly
and easily measure the thickness of a material. They
provide valuable insights into the integrity and measure
the thickness of the sheets. This is done on a manual
basis. In industries, it is very difficult to measure the
thickness of any sheet or any object in a digital form.
Keywords :
Thickness Cipher, Ultrasonic Sensor, Foam.
References :
- Luciano, Nava-Balanzar, et al. "Development of an ultrasonic thickness measurement equipment prototype." 2010 20th International Conference on Electronics Communications and Computers (CONIELECOMP). IEEE, 2010..
- K. W. Suh and C. P. Park, in Polymeric Foams, D. Klempner and K. Frisch, eds., Hanser Publishers (1991).
- Williams, M. K.; Weiser, E. S.; Fesmire, J. E.; Grimsley, B. W.; Smith, T. M.; Brenner, J. R.; Nelson, G. L. Polym. Adv. Technol. 2005, 16, 167.
- "Internet of Things: Opportunities and challenges for semiconductor companies". McKinsey & Company. Retrieved 2016-11-22.
- "IOT Brings Fragmentation in Platform" (PDF). Retrieved 2018-03-19.
- Steve Kovach (July 30, 2013). "Android Fragmentation Report". Business Insider. Retrieved October 19, 2013.
- "Who Needs the Internet of Things?". Linux.com | The source for Linux information. Retrieved 2016-11-22.
system is constructed using ultrasonic sensor
HC-SR04, ARDUINO UNO module, and LED display.
The ultrasonic sensor transmits ultrasonic pulses in the
form of waves and receives back the pulses after the
waves are reflected by an object. The time duration of
ultrasonic between transmission and reception is
calculated as the distance between the sensor and sample.
The method of thickness measurement adheres the
sample to the holder in front of an ultrasonic sensor. The
Thickness measurement of the sample is calculated based
on the distance between the sensor to the holder (fixed
barrier) and the sample to the sensor. The zero position
of the measurement is the distance of the sensor to the
holder.
The objective of THICKNESS CIPHER is to
minimize the use of Manual Gauges by decreasing the
time and manpower. The output of the Thickness gauge is
usually time-consuming and can be inappropriate due to
human error, which tends to the data loss. A thickness
meter is defined as an instrument that is used to quickly
and easily measure the thickness of a material. They
provide valuable insights into the integrity and measure
the thickness of the sheets. This is done on a manual
basis. In industries, it is very difficult to measure the
thickness of any sheet or any object in a digital form.
Keywords :
Thickness Cipher, Ultrasonic Sensor, Foam.