Journal of Electronics, Electromedical Engineering, and Medical Informatics
The Journal of Electronics, Electromedical Engineering, and Medical Informatics (JEEEMI) is a peer-reviewed open-access journal. The journal invites scientists and engineers throughout the world to exchange and disseminate theoretical and practice-oriented topics which covers three (3) majors areas of research that includes 1) Electronics, 2) Biomedical Engineering, and 3)Medical Informatics (emphasize on hardware and software design). Submitted papers must be written in English for an initial review stage by editors and further review process by a minimum of two reviewers.
Articles
270 Documents
<![CDATA[Patient Monitor for SpO2 and Temperature Parameters ]]>
<![CDATA[Moch Sahrul Triandi Putra Sahrul]]>;
<![CDATA[Triwiyanto]]>;
<![CDATA[Torib Hamzah]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 1 No 2 (2019): October ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v1i2.2
<![CDATA[Patient monitor is an apparatus used to monitor the patient's condition in real-time, hence the patient's physiological conditions can be identified at that time. The purpose of this study is to design a patient monitor for SpO2 and temperature parameters based on computer with Delphi progaming. In this work, the author developed patient monitor with two parameters (SpO2 and Temperature). The workings of this tool are very simple by installing the finger sensor on the finger and the temperature sensor in the armpit area will then be detected by the two sensors that will be displayed on the PC and LCD Characters, analog data from the ADC Atmega is received by the personal computer (PC) via Bluetooth HC -05 and values per parameter are also displayed on the Character LCD. After measuring, get an error in the tool, the biggest SpO2 error of this tool is 1.02% and get the smallest error of 0.8%. And for the biggest error of Temperature of 1.02% and the smallest error of 0.8%.]]>
<![CDATA[Baby Incubator Based on PID Control With Kangaroo Mode (Kangaroo Mode and Humidity) ]]>
<![CDATA[Nur Fildzah Hidayati]]>;
<![CDATA[Endro Yulianto]]>;
<![CDATA[Abd Kholiq]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 1 No 2 (2019): October ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v1i2.3
<![CDATA[Baby Incubator is one of the electromedical equipment used to provide protection to premature babies or low birth weight. Baby care in the baby incubator causes separation of mother and baby. A new innovation in the care of premature babies who bring their babies and mothers closer is Kangaroo Method Management (PMK). Kangaroo method treatment aims to create emotional attachment to the baby, so that the mother will confidently take care. The research and manufacture of this module uses a method of treating baby incubator by adding a reading of the room temperature when the kangaroo mode runs at a setting of 34 ° C - 37 ° C with the effect of room temperature at 18 ° C, 24 ° C, and 30 ° C and setting the humidity control automatically by measuring at a temperature of 32 ° C, then measuring the results immediately. Sensors used to detect temperature are LM35 sensors and sensors used to detect humidity using DHT22. Based on the measurement results obtained uncertainty values on the measurement of humidity 2.1, the measurement of temperature stability can be seen from the results of the graph which shows that the room temperature is not too influential at the temperature of the baby incubator. This study has shown the development of baby incubators to help mothers who have babies born prematurely so that they can have a good bond with how to treat skin to skin. This study has proven that its accuracy is appropriate to be used to stabilize the condition of babies born prematurely and help to treat PMK in some hospitals. In the future, this research can be made and used in small clinics in villages at low costs.]]>
<![CDATA[Fetal Doppler Simulator Based on Arduino ]]>
<![CDATA[Alfina Nadhirotussolikah]]>;
<![CDATA[Andjar Pudji]]>;
<![CDATA[Muhammad Ridha Mak'ruf]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 2 No 1 (2020): January ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v2i1.6
<![CDATA[Heart rate of the fetal is the main indicator of the fetal life in the womb. Monitoring fetal heart rate can’t be done, so a tool is needed to monitoring fetal heart rate. Fetal heart rate can be monitored with fetal doppler. To test the accuracy of Fetal Doppler, a calibration is needed with the Fetal Doppler Simulator. This tool will simulate the fetal heart rate with a BPM value that can be adjusted according to the settings on the device. This module using Arduino as the brain system. On the module there is a selection of BPM from 60 to 240 BPM with an increase of 30 BPM displayed on 2x16 character LCDs. Based on BPM measurement 6 times using Fetal Doppler, the measurement error in a BPM of 60 to BPM 210 is 0%, while at BPM 240 an error is 0.2%. This module has been compared with the standard devices (Fetal Simulator Brand Fluke Biomedical Ps320), the results of the comparison modules with the comparison tool has the same error value in 240 BPM is 0.2% and in BPM 210 there is a difference in the result of module Fetal Doppler reading of 210 BPM while in the comparison tool is 209 BPM. Of the measurement data and analysis, it can be concluded that the tool can work and the tool has the same accuracy as the standard device.]]>
<![CDATA[Syringe Pump With Nearly Empty Based Microcontroller Atmega328 ]]>
<![CDATA[Lely Erica Putri]]>;
<![CDATA[Muhammad Ridha Mak'ruf]]>;
<![CDATA[Abd Kholiq]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 1 No 2 (2019): October ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v1i2.5
<![CDATA[Syringe Pump is a tool used to give liquid medicine or food liquid into the patient's body in a certain amount and within a certain period of time on a regular basis. The purpose of this study is to facilitate monitoring of fluid in the syringe so that the hose is not installed continuously when the liquid has run out. The circuit consists of an Atmega328 microcontroller, a motor driver, and an optocoupler sensor. Setting the syringe, volume and flowrate is done at the beginning. To insert liquid, the motor must be run by the way the settings have been done and press the start button. Tools need supply from PLN grids. Calibration is done using IDA 4 Plus. This tool is equipped with the addition of alarms nearly empty and the bolus button. From the measurements taken, at the 20 ml syringe the biggest error occurred at the 5 ml volume point of 0.4% and at the 50 ml syringe the biggest error occurred at the 5 ml volume point of 0.280%.This module can be used according to its function, because the% error is still below the ± 5% standard.]]>
<![CDATA[DC SHOCK SIMULATOR ]]>
<![CDATA[Muhammad Amir Maruf]]>;
<![CDATA[Bambang Guruh Irianto]]>;
<![CDATA[Tri Bowo Indrato]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 1 No 2 (2019): October ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v1i2.4
<![CDATA[Defibrillators are electronic devices that carry shock electrical signals (pulses) to the heart muscle to maintain myocardial depolarization that is undergoing cardiac fibrillation (ventricular fibrillation or atrial fibrillation) (Bronzino, 2000). There are several conditions that must be met for the occurrence of shock processes including shock time, energy to be provided, patient and operator safety. In this defibrillator the use of selectors / energy selection is linear in the range 1-30 Joules with the use of tools at 10, 15, 20, 25, 30 Joules. The energy will then be discarded or given to the patient via a paddle when pressed the Discharge / shock button. The result of the signal given to the patient is monophasic. This study used a pre-experimental type with a One Group post test design research design. Measurements were made 5 times the volt meter at the test points determined by the compiler.]]>
<![CDATA[Effect of Temperature on pH Meter Based on Arduino Uno With Internal Calibration ]]>
<![CDATA[lilia wati dewi pratami]]>;
<![CDATA[Her Gumiwang Ariswati]]>;
<![CDATA[Dyah Titisari]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 2 No 1 (2020): January ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v2i1.5
<![CDATA[pH Meter is a device used to express the level of acidity or basicity possessed by a substance or solution. Normal pH has a value of 7 while the pH value> 7 indicates that the substance has alkaline properties while the pH value <7 indicates acidic properties. pH 0 shows a high degree of acidity, and pH 14 shows the highest degree of alkalinity. pH Meter reads the pH and temperature values in a sample. The author uses glass electrodes as a pH sensor, DS18B20 as a temperature sensor and LCD to make pH and temperature values. This module is equipped with an internal calibration that is used to set the module to read the pH value properly and correctly using a pH buffer and equipped with internal storage and this module facilitates battery usage. Based on pH measurements on the module the error value in buffer 4 calibration is 5.39%, in buffer 7 is 1.76%, in buffer 10 is 1.04%. The highest error value in the measurement sample is 3.54% and the lowest error value is 0.03%. The temperature of the sample is very influential on the reading of the pH value because the higher the temperature the pH value also increases even though it is not so significant.]]>
<![CDATA[Calculation Of Fetal Weight Estimation Displayed With TFT LCD ]]>
<![CDATA[Nadhia Regitasari]]>;
<![CDATA[M. Ridha Mak'ruf]]>;
<![CDATA[Endang Dian Setioningsih]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 2 No 1 (2020): January ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v2i1.4
<![CDATA[Fetal weight estimation during pregnancy is one of the beneficial ways to solve morbidity and death during labor problem. Manually, the fundal height is measured from the edge of the pubic symphysis to the top of the uterine fundus by following the arch of the uterus, using a measuring tape. The purpose of this study is to develop an easy way to count fetal weight estimation so midwives don’t have to count manually. The calculation of fetal weight estimation tool uses a variable resistor (potentiometer) as a sensor to measure the fundal height. Then it will be processed in microcontroller. The measurement results are fundal height and estimation fetal weight that will be displayed on the TFT LCD. Based on the results of measuring the fundus uterine height as much as 6 times against the measuring tool (ruler), there is no error in the device so it can be concluded that this tool can be used according to its function. This calculation of fetal weight estimation tool is portable and easy to use to help midwives count the fetal weight estimation quickly.]]>
<![CDATA[Design of Respiration Rate Meter Using Flexible Sensor ]]>
<![CDATA[Sarah Aghnia Miyagi]]>;
<![CDATA[Muhammad Ridha Mak’ruf]]>;
<![CDATA[Endang Dian Setioningsih]]>;
<![CDATA[Tark Das]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 2 No 1 (2020): January ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v2i1.3
<![CDATA[Respiration rate is an important physiological parameter that helps to provide important information about the patient's health status, especially from the human respiratory system. So it is necessary to measure the human respiratory rate by calculating the number of respiratory frequencies within 1 minute. The respiratory rate meter is a tool used to calculate the respiratory rate by counting the number of breaths for 1 minute. The author makes a tool to detect human respiratory rate by using a sensor that detects the ascend and descend of the chest cavity based on a microcontroller so that the operator can measure the breathing rate more practically and accurately. Component tool contains analog signal conditioning circuit and microcontroller circuit accompanied by display in the form of LCD TFT. The results of measurement data on 10 respondents obtained an average error value, namely the position of the right chest cavity 6.6%, middle chest cavity 7.92%, and left chest cavity 6.85%. This value is still below the error tolerance limit of 10%. It can be concluded that to obtain the best measurement results, the sensor is placed in the position of the right chest cavity.]]>
<![CDATA[Peak Flow Meter Equipped with Inspection Results Indicator ]]>
<![CDATA[Nadiya Garnis Sallyfan]]>;
<![CDATA[Endro Yulianto]]>;
<![CDATA[Torib Hamzah]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 2 No 1 (2020): January ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v2i1.2
<![CDATA[Peak Flow Meter (PFM) is a tool to measure the Peak Flow of Air Expiration in the road (PFR) or commonly referred to as Peak Expiration Flow (PEF) and to connect asthma. The value of PEF can help a number of factors in age, respiratory muscle strength, height and gender. Airway measurements are used to measure patients suffering from asthma. This peak flow meter tool works based on the air pressure produced from the patient's puff using the MPX5100GP pressure sensor in the range of 0 to 100 kPa and the voltage output is 0.2 to 4.7 VDC to increase wind pressure in the patient. From the pressure converted to voltage and enter the 0 from the Arduino nano minimum system circuit to be processed into analog data and then put into units of liters / second, the value of the flow meter is sent and replaced to a PC with the Delphi7 application. The measurement results of PEF values at peak flow meters have an error value of less than 5% This peak flow meter tool also has a consideration value of 0.095475 so that this tool can be said to be very certain to be used as asthma. Then it can be concluded that the peak flow meter is feasible and meets the specified requirements]]>
<![CDATA[A Two-Mode Digital Pressure Meter Equipped With An Automatic Leak Test Using MPX5050gp And MPXv4115vc6u Sensors ]]>
<![CDATA[Fita Florensa Rooswita]]>;
<![CDATA[Triana Rahmawati]]>;
<![CDATA[Syaifudin Syaifudin]]>
<![CDATA[ Journal of Electronics, Electromedical Engineering, and Medical Informatics Vol 2 No 2 (2020): July ]]>
Publisher : <![CDATA[Department of Electromedical Engineering, POLTEKKES KEMENKES SURABAYA and IKATEMI ]]>
Show Abstract
|
Download Original
|
Original Source
|
Check in Google Scholar
|
DOI: 10.35882/jeeemi.v2i2.7
<![CDATA[The calibration process aims to guarantee that a measurement device is to follow the established standards. The purpose of this study is to design an automatic leak test for digital pressure meter in which the function of this device is to measure pressure on the sphygmomanometer and suction pump or other devices that use pressure parameters for measurement. This study used the Arduino as a control system, and to process the analog data into digital. Signal conditioning, based on the amplifier circuit, was also applied for the MPX5050GP and MPXV4115VC6U sensor. The proposed design used a 4x20 liquid crystal display to show the parameters in this design ware also equipped with a selector of mmHg or kPa units. The result shows that the fluctuating resolution is 0.25 mmHg. In this design, an automatic leak feature was also equipped for the sphygmomanometer. The results obtained an average error of 7.3 mmHg for sphygmomanometers. On the other hand, the suction pumps have an accuracy of less than 1.5 kPa. From these results, it was concluded that this design could be used for the measurement of devices that use positive pressure and negative pressure]]>
