Subhra Majhi scite author profile

Subhra Majhi

5Publications

88Citation Statements Received

65Citation Statements Given

How they've been cited

202

How they cite others

178

Affiliations

Curtin University, ChemCentre

Publications

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Characterisation of road bumps using smartphones

Mukherjee

Majhi

2016

Eur. Transp. Res. Rev.

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Introduction Speed bumps are used as the main means of controlling vehicle speeds all over the world. It is not too infrequent, especially in the emerging economies, to have unmarked bumps that can be perilous for the passengers. Fortuitously, the roadways and mobile phone networks have grown simultaneously in emerging economies. This paper demonstrates the capability of smartphones placed inside the vehicles in characterisation of road bumps. The smart mobile phones have accelerometers and position sensors that can be useful for autonomous monitoring roads. This can empower the user community in monitoring of roads. However, the capability of the smartphone in discerning different types of speed bumps while travelling in heterogeneous vehicle types needs to be examined. Methods A range of road vehicles is mathematically modelled as mass, spring, and damper systems. The mathematical model of the vehicle is excited with parameters analogous to some common speed bumps and its acceleration response is calculated. The accelerometer of a smartphone is validated by comparing it with high precision accelerometers. The acceleration response of the phone while passing over the corresponding road bumps, which was used in the model earlier, is recorded using an Android based application. The experiment is repeated for different classes of vehicles. Filters have been used to reduce noise in the signals. A time averaging technique has been employed to compress the collected data. Results and conclusionsThe acceleration signals have been digitally processed to capture road bumps. The importance of using a mathematical model to understand the acceleration response of a vehicle has been established. Also, the use of pass filters to extract the signal of concern from the noisy data has been exhibited. The ability of the technique to discern different types of speed bumps while travelling in a variety of vehicle types has been demonstrated. This investigation demonstrates the potential to automatically monitor the condition of roadways obviating costly manual inspections. As smartphones are ubiquitous, the methodology has the potential to empower the user community in the maintenance of infrastructure.

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Effect of elevated temperatures on concrete incorporating ferronickel slag as fine aggregate

2018

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Summary This study evaluates the effect of elevated temperature exposure on concrete incorporating ferronickel slag (FNS) as a replacement of natural sand. Concrete cylinders were exposed up to 800°C, and the changes in compressive strength, mass, ultrasonic pulse velocity (UPV), and microstructure were investigated. The concretes containing up to 100% FNS aggregate showed no spalling and similar cracking to that of the concrete using 100% natural sand. For exposures up to 600°C, the residual strengths of concretes containing 50% FNS were 7% to 10% smaller than the concrete with 100% sand. Use of 30% fly ash as cement replacement improved residual strength by pozzolanic reaction for exposures up to 600°C. An equation has been found from the correlation between residual strength and UPV. Therefore, UPV can be used as a nondestructive test to estimate the extent of postfire damage and residual strength of concrete incorporating FNS aggregate and fly ash.

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Corrosion detection in steel bar: A time-frequency approach

Majhi

Mukherjee

George

et al. 2019

NDT & E International

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Corrosion monitoring in steel bars using Laser ultrasonic guided waves and advanced signal processing

Majhi

Mukherjee

George

et al. 2021

Mechanical Systems and Signal Processing

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Healing fine cracks in concrete with bacterial cement for an advanced non-destructive monitoring

Kaur

Majhi

Dhami

2020

Construction and Building Materials

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Subhra Majhi

Characterisation of road bumps using smartphones

Effect of elevated temperatures on concrete incorporating ferronickel slag as fine aggregate

Corrosion detection in steel bar: A time-frequency approach

Corrosion monitoring in steel bars using Laser ultrasonic guided waves and advanced signal processing

Healing fine cracks in concrete with bacterial cement for an advanced non-destructive monitoring

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