Journal of the Korean Society for Precision Engineering

Numerical Analysis and Experimental Verification to Enhance the Assemble Process of an Array-type Permanent Magnet Sensor Using Steel Balls: Ho Cheol Lee; J. Korean Soc. Precis. Eng. 2025;42(11):965-970.
Published online November 1, 2025; DOI: https://doi.org/10.7736/JKSPE.025.110

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Identifying the impeller type is essential for enabling torque sensing in conventional agitators. Previous studies have demonstrated that using arrays of permanent magnets with like poles facing each other allows for cost-effective, non-contact sensors. However, these configurations create strong repulsive forces, complicating assembly during sensor fabrication. This study addresses the issue of poor assemblability by introducing a high-permeability ferromagnetic ball between the magnets. This ball not only reduces repulsive forces but can also induce attractive forces, making assembly easier. We analyzed the effects of ball diameter, magnet thickness, and the number of magnets on the inter-magnetic force using ANSYS Maxwell. To validate the finite element method (FEM) results, we conducted experiments, which showed that the measured values closely matched the simulation results. This confirmed that the ferromagnetic ball significantly mitigates the repulsion between magnets, and in some cases, reverses the force to attraction. These findings are important for enhancing assemblability in automated mass production. Additionally, the study identified an optimal steel ball size that minimizes repulsion while facilitating sensor miniaturization, providing a practical solution for compact sensor design.

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Position Control of a Linear Motor Motion Stage Using Augmented Kalman Filter: Keun-Ho Kim, Hyeong-Joon Ahn; J. Korean Soc. Precis. Eng. 2025;42(11):887-892.
Published online November 1, 2025; DOI: https://doi.org/10.7736/JKSPE.025.011

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The rapid growth of semiconductor and display manufacturing highlights the demand for fast, precise motion stages. Advanced systems such as lithography and bio-stages require accuracy at the μm and nm levels, but linear motor stages face challenges from disturbances, model uncertainties, and measurement noise. Disturbances and uncertainties cause deviations from models, while noise limits control gains and performance. Disturbance Observers (DOBs) enhance performance by compensating for these effects using input–output data and a nominal inverse model. However, widening the disturbance estimation bandwidth increases noise sensitivity. Conversely, the Kalman Filter (KF) estimates system states from noisy measurements, reducing noise in position feedback, but it does not treat disturbances as states, limiting compensation. To address this, we propose an Augmented Kalman Filter (AKF)–based position control for linear motor stages. The system was modeled and identified through frequency response analysis, and DOB and AKF were implemented with a PIV servo filter. Experimental validation showed reduced following error, jitter, and control effort, demonstrating the improved control performance of the AKF approach over conventional methods.

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A Study on Polymer-based Cylindrical Flow Sensor for 2-dimensional Detection: Wonjun Lee, Sang Hoon Lee; J. Korean Soc. Precis. Eng. 2025;42(6):447-454.
Published online June 1, 2025; DOI: https://doi.org/10.7736/JKSPE.025.030

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In this study, we fabricated and investigated the polymer-based cylindrical flow sensor for two-dimensional (2D) detection. The flow sensor was the drag force type flowmeter which was fabricated with ecoflex. It had CNT/PDMS as the piezoresistive material and a cylindrical shape to measure the 2D flow. It also had impact resistance and ease of fabrication due to its polymer-based sensor. At first, two piezoresistive parts were applied to evaluate detection properties. Forces from various direction were applied. Results showed its potential as a sensing device. Following this, the final flow sensor was fabricated with four piezoresistive parts and its sensitivity was measured in the air flow from 0 to 30 m/s. Resistance changes were measured while rotating the sensor. Outputs showed a form of sine waves. Data were repeatedly collected under various conditions. The direction and air flow rate were then determined. To check physical impact resistance, a sudden high air flow rate with 100m/s was applied to the sensor and a stable output was obtained. These results suggest that such ecoflex-based cylindrical flow sensor can be used as a 2D flow rate sensor.

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Development of Gas Sensors based on Volumetric and Manometric Analysis for Measuring Gas Emission and Diffusion Coefficient in Low-density Polyethylene Polymer: Ji Hun Lee, Sang Koo Jeon; J. Korean Soc. Precis. Eng. 2025;42(4):333-345.
Published online April 1, 2025; DOI: https://doi.org/10.7736/JKSPE.025.015

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Gas sensors are crucial devices in various fields such as industrial safety, environmental monitoring, and gas infrastructure. Designed to have high-sensitivity, stability, and reliability, gas sensors are often required to be cost-effective with quick response and compactness. To meet diverse needs, we developed two types of gas sensors based on volumetric and manometric analyses. These sensors could operate by measuring gas volume and pressure changes, respectively, based on emitted gas. These sensors are capable of determining gas transport parameters such as gas uptake, solubility, and diffusivity for gas-charged polymers in a high-pressure environment. These sensors can provide rapid responses within one-second. They can measure gas concentration ranging from 0.01 wt·ppm to 1,500 wt·ppm with adjustable sensitivity and measurement ranges. As a result, such sensor system can be used to facilitate real time detection and analysis of gas transport properties in pure gases including H₂, He, N₂, O₂, and Ar.

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Design of a 3-Axis Compliant Robotic Deburring Tool with Force Sensing and Variable Stiffness Capabilities: Gi-Seong Kim, Jeong-Hyeon Jun, Han Sung Kim; J. Korean Soc. Precis. Eng. 2025;42(3):215-221.
Published online March 1, 2025; DOI: https://doi.org/10.7736/JKSPE.024.107

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In this paper, a deburring tool with 3-axis compliance is presented for deburring using a robot manipulator. Compliance is provided with beam structures instead of pneumatic pressure, which enables integrated 3-axis force sensing and variable stiffness. Two radial compliances were achieved using 4-PSS (Prismatic-Spherical-Spherical) legs, with P joints composed of cantilever beams. The one axial compliance was configured with two ball bushings and a linear spring. Strain gauges were attached to cantilever beams and a load cell was mounted between the linear spring and the universal joint to perform force sensing. The stability of vibrations and force sensing were verified through deburring experiments using the proposed deburring tool. Additionally, experiments on automatic offset for applying a constant force during deburring were conducted and results were validated by comparing the workpiece before and after the deburring process.

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Stress Analysis of a Robot End-Effector Knife for the Deburring Process
Jeong-Jin Park, Jeong-Hyun Sohn, Kyung-Chang Lee
Journal of the Korean Society of Manufacturing Process Engineers.2025; 24(6): 42. CrossRef
Stress Analysis of a Robot End-Effector Knife for the Deburring Process
Jeong-Jin Park, Jeong-Hyun Sohn, Kyung-Chang Lee
Journal of the Korean Society of Manufacturing Process Engineers.2025; 24(6): 42. CrossRef

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Introduction and Trends of Time-synchronized Measurement Devices to Advance Data-driven Smart Grid Monitoring: Gyul Lee; J. Korean Soc. Precis. Eng. 2024;41(10):735-740.
Published online October 1, 2024; DOI: https://doi.org/10.7736/JKSPE.024.082

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The smart grid was initially developed to facilitate communication between operators of the electric power system (such as power generation companies and transmission system operators) and consumers within the distribution network. To implement the smart grid paradigm, time-synchronized measurement devices were developed and introduced into the electric power system. Phasor measurement units (PMUs) and waveform measurement units (WMUs) were created for wide-area transmission networks (at the high-voltage layer), while micro-PMUs were introduced for real-time state estimation in distribution networks (at the low-voltage layer). These time-synchronized measurement devices allow power system operators to monitor the operational status of power generation, transmission, and distribution infrastructure in real time. In particular, data-driven applications utilizing the measurement data can intelligentize and advance the monitoring, operation, and control of the smart grid. The capabilities of digitized high-resolution measurement and time-synchronization are the key factors that enable these contributions to the smart grid. This paper provides an introduction to time-synchronized measurement devices, outlines their specific capabilities, and explores the data-driven applications that can be implemented for advanced smart grid monitoring systems.

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Obtaining Forming Limit Diagram Using OpenCV: Min Seok Kim, Jeong Kim; J. Korean Soc. Precis. Eng. 2024;41(9):719-723.
Published online September 1, 2024; DOI: https://doi.org/10.7736/JKSPE.024.052

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The Forming Limit Diagram (FLD) is a criterion used to assess the formability of sheet metal during a manufacturing process. Traditionally, FLDs are obtained through manual measurements using Mylar tape or through the use of automatic deformation measurement systems such as ARMIS and ARGUS. However, the use of Mylar tape is not user-friendly and can result in errors. Additionally, the cost of using automatic measuring equipment is high. To address these challenges, we propose a method that utilizes a low-cost USB digital microscope and the Python-based open-source library, OpenCV, to obtain forming limit diagrams. This approach allows for the measurement of deformation on specimens by analyzing circles printed on them. To evaluate the performance of this method, a circular grid was printed on a sus430 0.3 t specimen and a nakajima test was conducted. The strain data obtained using this system was then compared to the FLD obtained with the ARGUS system. The results confirmed that the formability of sheet metal can be assessed at a lower cost using our proposed method.

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Comparative Analysis between IMU Signal-based Neural Network Models for Energy Expenditure Estimation: Chang June Lee, Jung Keun Lee; J. Korean Soc. Precis. Eng. 2024;41(3):191-198.
Published online March 1, 2024; DOI: https://doi.org/10.7736/JKSPE.023.126

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Estimating energy expenditure is essential in monitoring the intensity of physical activity and health status. Energy expenditure can be estimated based on wearable sensors such as inertial measurement unit (IMU). While a variety of methods have been developed to estimate energy expenditure during day-to-day activities, their performances have not been thoroughly evaluated under walking conditions according to various speeds and inclines. This study investigated IMU-based neural network models for energy expenditure estimation under various walking conditions and comparatively analyzed their performances in terms of sensor attachment locations and training/testing datasets. In this study, two neural network models were selected based on a previous study (Slade et al., 2019): (M1) a multilayer perceptron using sensor signals during each gait cycle, and (M2) a recurrent neural network using sensor signal sequences of a fixed window size. The results revealed the following: (i) the performance of the foot attachment model was the best among the five sensor attachment locations (0.89 W/kg for M1 and 1.14 W/kg for M2); and (ii) although the performance of M1 was superior to that of M2, M1 requires accurate gait detection for data segmentation by each stride, which hinders the usefulness of M2.

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Development of a Novel Ventilation Estimation Model Based on Convolutional Neural Network (CNN)
Jeongyeon Chu, Jaehyon Baik, Kangsu Jeong, Seungwon Jung, Youngjin Park, Hosu Lee
Journal of Korea Robotics Society.2025; 20(1): 138. CrossRef

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Characterization of a Copper Thin Film Using the Surface Acoustic Wave Measurement Technique: Taehyung Kim, Yun Young Kim; J. Korean Soc. Precis. Eng. 2024;41(3):183-189.
Published online March 1, 2024; DOI: https://doi.org/10.7736/JKSPE.023.125

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The elastic property of a copper (Cu) thin film was investigated using the surface acoustic wave (SAW) measurement technique. The Cu film was deposited on a quartz substrate using a direct current magnetron sputter and its surface morphology was inspected using atomic force microscopy. Time-domain waveforms of the SAW on the film were acquired at different propagation distances to estimate the Young’s modulus of Cu such that the experimentally-obtained dispersion curve can be compared to the analytical result calculated using the Transfer Matrix method for curve-fitting. Results showed that the film’s elastic property value decreased by 18.5% compared to that of the bulk state, and the scale effect was not significant in the thickness range of 150-300 nm, showing good agreement with those by the nanoindentation technique. The property, however, increased by 15.5% with the grain coarsening.

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Work Coordinate Setup in Ultra-precision Machine Tool Using Tunneling Effect: Handeul You, Sangjin Maeng; J. Korean Soc. Precis. Eng. 2024;41(2):89-94.
Published online February 1, 2024; DOI: https://doi.org/10.7736/JKSPE.023.134

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Work coordinate setup is a time-consuming and difficult task in ultraprecision machining. The setup process determines the precision and tolerance of the machined parts. In ultraprecision machining, the table can be moved in the nanometer range, but the accuracy of the measuring device has not reached the nanometer accuracy range. Although several measurement methods have been proposed, the attained precision is still insufficient. Some methods also lose the precision when the sensor is changed with the tool after the work coordinate setup is completed. A work coordinate setup method proposed in this study could improve the precision and the measurement process using electron tunneling. Since the method can use the tool as a sensor probe, the changing process does not degrade the measurement precision. In addition, the proposed method can theoretically detect the distance between the tool and the workpiece in sub-nanometers like a scanning tunneling microscope. The simple system requires a precision current amplifier capable of measuring electron tunneling current in the picoampere to nanoampere range and a power supply. The method, installed on an ultra-precision machine tool, was tested on WC and aluminum material. The accuracy of the method was evaluated for applied voltage.

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A Recurrent Neural Network for 3D Joint Angle Estimation based on Six-axis IMUs but without a Magnetometer: Chang June Lee, Woo Jae Kim, Jung Keun Lee; J. Korean Soc. Precis. Eng. 2023;40(4):301-308.
Published online April 1, 2023; DOI: https://doi.org/10.7736/JKSPE.022.112

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Inertial measurement unit (IMU)-based 3D joint angle estimation have a wide range of important applications, among them, in gait analysis and exoskeleton robot control. Conventionally, the joint angle was determined via the estimation of 3D orientation of each body segment using 9-axis IMUs including 3-axis magnetometers. However, a magnetometer is limited by magnetic disturbance in the vicinity of the sensor, which highly affects the accuracy of the joint angle. Accordingly, this study aims to estimate the joint angle using the 6-axis IMU signals composed of a 3-axis accelerometer and a 3-axis gyroscope without a magnetometer. This paper proposes a recurrent neural network (RNN) model, which indirectly utilizes the joint kinematic constraint and thus estimates joint angles based on 6-axis IMUs without using a magnetometer signal. The performance of the proposed model was validated for a mechanical joint and human elbow joint, under magnetically disturbed environments. Experimental results showed that the proposed RNN approach outperformed the conventional approach based on a Kalman filter (KF), i.e., RNN 3.48° vs. KF 10.01° for the mechanical joint and RNN 7.39° vs. KF 21.27° for the elbow joint.

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Register Marks Position Measurement System to Numerically Evaluate the Fidelity of Engraved Pattern Position in a Printing Roll: Sung Min Lee, Jong Su Lee, Hyung Sun Kim, Jong Guen Choi; J. Korean Soc. Precis. Eng. 2022;39(9):701-709.
Published online September 1, 2022; DOI: https://doi.org/10.7736/JKSPE.022.022

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Printed electronics is a manufacturing technology that fabricates electronic devices using printing techniques. Due to its characteristics of low cost and simple process, a roll-to-roll printing technique has been used to achieve the large area and mass production of flexible electronic devices such as a thin film transistor. In the roll-to-roll printing process, a fidelity of the engraved pattern position is one of the most important techniques to fabricate high resolution multi-layer electronic devices. In this study, an engraved register mark position measurement system was developed to numerically evaluate the position accuracy of engraved mark in printing roll. The proposed system is based on a high-precision encoder based position control system and a high-resolution machine vision system. The measurement error of the developed system is within the camera resolution ±2.1 μm, verifying the superiority of the system. Using the developed system, we measured the position errors of the engraved register marks for six industrial scale printing rolls. This study suggests that the position error of the engraved mark should be considered to achieve a high precision register control below ±10 μm and necessity of the developed system.

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Tailoring threshold voltage of R2R printed SWCNT thin film transistors for realizing 4 bit ALU
Sajjan Parajuli, Younsu Jung, Sagar Shrestha, Jinhwa Park, Chanyeop Ahn, Kiran Shrestha, Bijendra Bishow Maskey, Tae-Yeon Cho, Ji-Ho Eom, Changwoo Lee, Jeong-Taek Kong, Byung-Sung Kim, Taik-Min Lee, SoYoung Kim, Gyoujin Cho
npj Flexible Electronics.2024;[Epub] CrossRef
Industrial Roll-to-Roll Printing Register Control Using a Pulse-Width Subdivision Detection Algorithm
Bangchao Liu, Youping Chen, Jingming Xie, Bing Chen
Applied Sciences.2023; 13(9): 5307. CrossRef

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Lateral Shearing Interferometry based on a Polarization Grating for Wavefront Sensing: Hyo Bin Jeong, Hyo Mi Park, Ki-Nam Joo; J. Korean Soc. Precis. Eng. 2022;39(4):245-251.
Published online April 1, 2022; DOI: https://doi.org/10.7736/JKSPE.022.009

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In this investigation, we propose a simple and effective lateral shearing interferometer based on a polarization grating. In the lateral shearing device, an incident beam is split into two beams by a polarization grating, and the returning beams can be laterally shifted after reflecting off a flat mirror and passing through the polarization grating again. These two beams are not only laterally shifted, but also their polarization states are orthogonal to each other as circular polarizations. With a single image obtained by a pixelated polarization CMOS camera, the proposed LSI can obtain the phase map corresponding to the x-sheared interferogram, and the other phase map can be calculated from another single image obtained by 90° rotation of the shearing device. Then, the original wavefront corresponding to the surface figure of the specimen can be reconstructed by wavefront reconstruction algorithms. In the experiments, various wavefronts generated by concave mirrors and a deformable mirror were measured and compared with those of a commercial Shack-Hartmann sensor.

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Optical Performance Using the Surface Form Error Modeling based on A Monte-Carlos Simulation of An Optical Window
Kwang-Woo Park, Ji-Hun Bae, Chi-Yeon Kim
Journal of the Korean Society for Precision Engineering.2024; 41(9): 725. CrossRef

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Moving Object Position Estimation Algorithm Using Reflected Beam Intensity of Retro-Reflector and LiDAR: Jung-Seok Seo, Ju-Hyeon Park, Gye-Jo Jung; J. Korean Soc. Precis. Eng. 2022;39(2):143-149.
Published online February 1, 2022; DOI: https://doi.org/10.7736/JKSPE.021.102

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This paper relates to the implementation of moving object position estimation by Pulsed LiDAR that can detect objects with high precision, speed, and spatial resolution. LiDAR measures the distance by calculating a return travel time when target is reflected. The retro-reflector, regardless of incident angle, can be reflected horizontally in the incident direction. This algorithm proposes a new approach method using LiDAR and retro-reflectors. According to the above algorithm, position can be determined by automatically detecting 90% of the reflected return beam intensity from moving objects to which the retro-reflector is attached. When this algorithm was applied indoors, it was possible to locate the position of the scanner accurately within ±5 mm error in 2,500 × 2,500 (mm) space. Also, it can detect a space of up to 5,000 × 5,000 (mm), making this an effective method for determining the position of a moving object in indoors.

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A Kalman Filter for Inverse Dynamics of IMU-Based Real-Time Joint Torque Estimation: Ji Seok Choi, Chang June Lee, Jung Keun Lee; J. Korean Soc. Precis. Eng. 2022;39(1):69-77.
Published online January 1, 2022; DOI: https://doi.org/10.7736/JKSPE.021.085

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One of the problems in inverse dynamics calculation for the inertial measurement unit (IMU)-based joint force and torque estimation is the amplified signal noises of segment kinematic data mainly due to the differentiation procedure and segmental soft tissue artifacts. In order to deal with this problem, appropriate filtering methods are often recommended for signal enhancement. Conventionally, a low-pass filter (LPF) is widely used for the kinematic data. However, the zero-phase LPF requires post-processing, while the real-time LPF causes an unignorable time lag. For this reason, it is inappropriate to use the LPF for real-time joint torque estimation. This paper proposes a Kalman filter (KF) for inverse dynamics of IMUbased joint torque estimation in real time without any time lag, while utilizing the smoothing capability of the KF. Experimental results showed that the proposed KF outperformed a real-time LPF in the estimation accuracy of hip joint force and torque during jogging on the spot by 100 and 29%, respectively. Although the proposed KF requires the process of adjusting covariance according to the dynamic conditions, it can be expected to improve the estimation performance in the field where joint force and torque need to be estimated in real time.

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Wearable Inertial Sensors-based Joint Kinetics Estimation of Lower Extremity Using a Recurrent Neural Network
Ji Seok Choi, Chang June Lee, Jung Keun Lee
Journal of the Korean Society for Precision Engineering.2023; 40(8): 655. CrossRef