Your search keyword '"nRF24L01"' showing total 6 results

1. Hybrid Coils-Based Wireless Power Transfer for Intelligent Sensors

Author

Mustafa F. Mahmood, Saleem Lateef Mohammed, Sadik Kamel Gharghan, Ali Al-Naji, and Javaan Chahl

Subjects

arduino, heart rate sensor, nRF24L01, transfer efficiency, transfer power, Chemical technology, TP1-1185

Abstract

Most wearable intelligent biomedical sensors are battery-powered. The batteries are large and relatively heavy, adding to the volume of wearable sensors, especially when implanted. In addition, the batteries have limited capacity, requiring periodic charging, as well as a limited life, requiring potentially invasive replacement. This paper aims to design and implement a prototype energy harvesting technique based on wireless power transfer/magnetic resonator coupling (WPT/MRC) to overcome the battery power problem by supplying adequate power for a heart rate sensor. We optimized transfer power and efficiency at different distances between transmitter and receiver coils. The proposed MRC consists of three units: power, measurement, and monitoring. The power unit included transmitter and receiver coils. The measurement unit consisted of an Arduino Nano microcontroller, a heart rate sensor, and used the nRF24L01 wireless protocol. The experimental monitoring unit was supported by a laptop to monitor the heart rate measurement in real-time. Three coil topologies: spiral–spiral, spider–spider, and spiral–spider were implemented for testing. These topologies were examined to explore which would be the best for the application by providing the highest transfer power and efficiency. The spiral–spider topology achieved the highest transfer power and efficiency with 10 W at 87%, respectively over a 5 cm air gap between transmitter and receiver coils when a 200 Ω resistive load was considered. Whereas, the spider–spider topology accomplished 7 W and 93% transfer power and efficiency at the same airgap and resistive load. The proposed topologies were superior to previous studies in terms of transfer power, efficiency and distance.

Published

2020

2. Ultrasound Sensor-Based Wireless Power Transfer for Low-Power Medical Devices

Author

Mustafa F. Mahmood, Saleem Latteef Mohammed, and Sadik Kamel Gharghan

Subjects

Arduino, heart rate sensor, nRF24L01, super-capacitors, transfer efficiency, ultrasonic power transfer, Applications of electric power, TK4001-4102

Abstract

Ultrasonic power transfer (UPT) is a promising method for wireless power transfer technology for low-power medical applications. Most portable or wearable medical devices are battery-powered. Batteries cannot be used for a long time and require periodic charging or replacement. UPT is a candidate technology for solving this problem. In this work, a 40-KHz ultrasound transducer was used to design a new prototype for supplying power to a wearable heart rate sensor for medical application. The implemented system consists of a power unit and heart rate measurement unit. The power unit includes an ultrasonic transmitter and receiver, rectifier, boost converter and super-capacitors. The heart rate measurement unit comprises measurement and monitoring circuits. UPT-based transfer power and efficiency were achieved using 1-, 4- and 8-Farad (F) super-capacitors. At 4 F, the system achieved 69.4% transfer efficiency and 0.318 mW power at 4 cm. In addition, 97% heart rate measurement accuracy was achieved relative to the benchmark device. The heart rate measurements were validated with statistical analysis. Our results show that this work outperforms previous works in terms of transfer power and efficiency with a 4-cm gap between the ultrasound transmitter and receiver.

Published

2019

3. Hybrid Coils-Based Wireless Power Transfer for Intelligent Sensors

Author

Ali Al-Naji, Javaan Chahl, Sadik Kamel Gharghan, Mustafa F. Mahmood, Saleem Lateef Mohammed, Mahmood, Mustafa F, Mohammed, Saleem Lateef, Gharghan, Sadik Kamel, Al-Naji, Ali, and Chahl, Javaan

Subjects

Battery (electricity), Computer science, Topology (electrical circuits), 02 engineering and technology, nRF24L01, lcsh:Chemical technology, Biochemistry, Article, transfer power, Analytical Chemistry, Resonator, Intelligent sensor, 0202 electrical engineering, electronic engineering, information engineering, lcsh:TP1-1185, Wireless power transfer, Electrical and Electronic Engineering, Instrumentation, business.industry, 020208 electrical & electronic engineering, Transmitter, Electrical engineering, transfer efficiency, 020206 networking & telecommunications, Atomic and Molecular Physics, and Optics, Power (physics), Microcontroller, arduino, heart rate sensor, Electromagnetic coil, business, Energy harvesting

Abstract

Most wearable intelligent biomedical sensors are battery-powered. The batteries are large and relatively heavy, adding to the volume of wearable sensors, especially when implanted. In addition, the batteries have limited capacity, requiring periodic charging, as well as a limited life, requiring potentially invasive replacement. This paper aims to design and implement a prototype energy harvesting technique based on wireless power transfer/magnetic resonator coupling (WPT/MRC) to overcome the battery power problem by supplying adequate power for a heart rate sensor. We optimized transfer power and efficiency at different distances between transmitter and receiver coils. The proposed MRC consists of three units: power, measurement, and monitoring. The power unit included transmitter and receiver coils. The measurement unit consisted of an Arduino Nano microcontroller, a heart rate sensor, and used the nRF24L01 wireless protocol. The experimental monitoring unit was supported by a laptop to monitor the heart rate measurement in real-time. Three coil topologies: spiral&ndash, spiral, spider&ndash, spider, and spiral&ndash, spider were implemented for testing. These topologies were examined to explore which would be the best for the application by providing the highest transfer power and efficiency. The spiral&ndash, spider topology achieved the highest transfer power and efficiency with 10 W at 87%, respectively over a 5 cm air gap between transmitter and receiver coils when a 200 Ω resistive load was considered. Whereas, the spider&ndash, spider topology accomplished 7 W and 93% transfer power and efficiency at the same airgap and resistive load. The proposed topologies were superior to previous studies in terms of transfer power, efficiency and distance.

Published

2020

4. Ultrasound Sensor-Based Wireless Power Transfer for Low-Power Medical Devices

Author

Sadik Kamel Gharghan, Mustafa F. Mahmood, and Saleem Latteef Mohammed

Subjects

Computer science, 02 engineering and technology, nRF24L01, 01 natural sciences, Rectifier, 0202 electrical engineering, electronic engineering, information engineering, Arduino, Maximum power transfer theorem, Wireless power transfer, Electrical and Electronic Engineering, Electronic circuit, ultrasonic power transfer, super-capacitors, business.industry, 020208 electrical & electronic engineering, 010401 analytical chemistry, Transmitter, transfer efficiency, Electrical engineering, lcsh:Applications of electric power, lcsh:TK4001-4102, 0104 chemical sciences, Power (physics), heart rate sensor, Boost converter, Ultrasonic sensor, business

Abstract

Ultrasonic power transfer (UPT) is a promising method for wireless power transfer technology for low-power medical applications. Most portable or wearable medical devices are battery-powered. Batteries cannot be used for a long time and require periodic charging or replacement. UPT is a candidate technology for solving this problem. In this work, a 40-KHz ultrasound transducer was used to design a new prototype for supplying power to a wearable heart rate sensor for medical application. The implemented system consists of a power unit and heart rate measurement unit. The power unit includes an ultrasonic transmitter and receiver, rectifier, boost converter and super-capacitors. The heart rate measurement unit comprises measurement and monitoring circuits. UPT-based transfer power and efficiency were achieved using 1-, 4- and 8-Farad (F) super-capacitors. At 4 F, the system achieved 69.4% transfer efficiency and 0.318 mW power at 4 cm. In addition, 97% heart rate measurement accuracy was achieved relative to the benchmark device. The heart rate measurements were validated with statistical analysis. Our results show that this work outperforms previous works in terms of transfer power and efficiency with a 4-cm gap between the ultrasound transmitter and receiver.

Published

2019

5. Hybrid Coils-Based Wireless Power Transfer for Intelligent Sensors.

Author

Mahmood, Mustafa F., Mohammed, Saleem Lateef, Gharghan, Sadik Kamel, Al-Naji, Ali, and Chahl, Javaan

Subjects

*WIRELESS power transmission, *INTELLIGENT sensors, *HEART rate monitors, *ARDUINO (Microcontroller), *BIOSENSORS, *AIR gap (Engineering), *INTELLIGENT transportation systems

Abstract

Most wearable intelligent biomedical sensors are battery-powered. The batteries are large and relatively heavy, adding to the volume of wearable sensors, especially when implanted. In addition, the batteries have limited capacity, requiring periodic charging, as well as a limited life, requiring potentially invasive replacement. This paper aims to design and implement a prototype energy harvesting technique based on wireless power transfer/magnetic resonator coupling (WPT/MRC) to overcome the battery power problem by supplying adequate power for a heart rate sensor. We optimized transfer power and efficiency at different distances between transmitter and receiver coils. The proposed MRC consists of three units: power, measurement, and monitoring. The power unit included transmitter and receiver coils. The measurement unit consisted of an Arduino Nano microcontroller, a heart rate sensor, and used the nRF24L01 wireless protocol. The experimental monitoring unit was supported by a laptop to monitor the heart rate measurement in real-time. Three coil topologies: spiral–spiral, spider–spider, and spiral–spider were implemented for testing. These topologies were examined to explore which would be the best for the application by providing the highest transfer power and efficiency. The spiral–spider topology achieved the highest transfer power and efficiency with 10 W at 87%, respectively over a 5 cm air gap between transmitter and receiver coils when a 200 Ω resistive load was considered. Whereas, the spider–spider topology accomplished 7 W and 93% transfer power and efficiency at the same airgap and resistive load. The proposed topologies were superior to previous studies in terms of transfer power, efficiency and distance. [ABSTRACT FROM AUTHOR]

Published

2020

6. Ultrasound Sensor-Based Wireless Power Transfer for Low-Power Medical Devices.

Author

Mahmood, Mustafa F., Mohammed, Saleem Latteef, and Gharghan, Sadik Kamel

Subjects

WIRELESS power transmission, MEDICAL equipment, ULTRASONIC transducers, HEART beat, TECHNOLOGY transfer, POLITICAL succession, MEDICAL supplies

Abstract

Ultrasonic power transfer (UPT) is a promising method for wireless power transfer technology for low-power medical applications. Most portable or wearable medical devices are battery-powered. Batteries cannot be used for a long time and require periodic charging or replacement. UPT is a candidate technology for solving this problem. In this work, a 40-KHz ultrasound transducer was used to design a new prototype for supplying power to a wearable heart rate sensor for medical application. The implemented system consists of a power unit and heart rate measurement unit. The power unit includes an ultrasonic transmitter and receiver, rectifier, boost converter and super-capacitors. The heart rate measurement unit comprises measurement and monitoring circuits. UPT-based transfer power and efficiency were achieved using 1-, 4- and 8-Farad (F) super-capacitors. At 4 F, the system achieved 69.4% transfer efficiency and 0.318 mW power at 4 cm. In addition, 97% heart rate measurement accuracy was achieved relative to the benchmark device. The heart rate measurements were validated with statistical analysis. Our results show that this work outperforms previous works in terms of transfer power and efficiency with a 4-cm gap between the ultrasound transmitter and receiver. [ABSTRACT FROM AUTHOR]

Published

2019