Design, Fabrication, and Calibration of an IR-Based Ballistic Chronograph

A chronograph is a device that measures the time between two events. This article discusses the design, fabrication, and calibration of a ballistic chronograph designed to measure the time taken by a projectile to travel a fixed distance between two checkpoints, A and B, along a straight line. The i...

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Published in:IEEE transactions on instrumentation and measurement 2025, Vol.74, p.1-7
Main Authors: Mudgal, Dhruv Narayan, Bhatnagar, Naresh
Format: Article
Language:English
Subjects:
Calibration
chronograph
Fabrication
infrared screens
Light emitting diodes
microcontroller
Microcontrollers
photodiode
Photodiodes
Projectiles
Sensors
Time factors
Time measurement
Uncertainty
uncertainty analysis
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Bhatnagar, Naresh
description A chronograph is a device that measures the time between two events. This article discusses the design, fabrication, and calibration of a ballistic chronograph designed to measure the time taken by a projectile to travel a fixed distance between two checkpoints, A and B, along a straight line. The infrared transmitter-receiver pairs at A and B and an Arduino microcontroller circuit confirm that the projectile has crossed these checkpoints. The duration of this event is precisely recorded in the microcontroller's memory. The system was designed to measure speeds up to 3500 m/s for a projectile 50 mm in length. The time uncertainty of the chronograph was found to be 0.71~\mu s. Distance between the checkpoints was measured with a CNC-mounted probe with an uncertainty of 0.10 mm. The overall cost of this local chronograph is 4-33 times lower than the commercially available chronographs. The novelty of the device lies in its calibration, which was performed using another Arduino circuit programmed to control the blinking of the IR LEDs. Two IR pulses of specified widths separated by a specified time interval were sent by electronically controlling the IR sources and detected and measured by the IR sensors. This optoelectronic method of calibration eliminated the need for field calibration, simplifying the process.
doi_str_mv 10.1109/TIM.2024.3493894
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This article discusses the design, fabrication, and calibration of a ballistic chronograph designed to measure the time taken by a projectile to travel a fixed distance between two checkpoints, A and B, along a straight line. The infrared transmitter-receiver pairs at A and B and an Arduino microcontroller circuit confirm that the projectile has crossed these checkpoints. The duration of this event is precisely recorded in the microcontroller's memory. The system was designed to measure speeds up to 3500 m/s for a projectile 50 mm in length. The time uncertainty of the chronograph was found to be &lt;inline-formula&gt; &lt;tex-math notation="LaTeX"&gt;0.71~\mu &lt;/tex-math&gt;&lt;/inline-formula&gt;s. Distance between the checkpoints was measured with a CNC-mounted probe with an uncertainty of 0.10 mm. The overall cost of this local chronograph is 4-33 times lower than the commercially available chronographs. 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The novelty of the device lies in its calibration, which was performed using another Arduino circuit programmed to control the blinking of the IR LEDs. Two IR pulses of specified widths separated by a specified time interval were sent by electronically controlling the IR sources and detected and measured by the IR sensors. 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subjects Calibration
chronograph
Fabrication
infrared screens
Light emitting diodes
microcontroller
Microcontrollers
photodiode
Photodiodes
Projectiles
Sensors
Time factors
Time measurement
Uncertainty
uncertainty analysis
title Design, Fabrication, and Calibration of an IR-Based Ballistic Chronograph
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