Projects - User contributions [en]

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T07:17:44Z

A1670552:

== Project Title- Pacemaker Wireless Charging System ==

[[File:Pacemaker_system1.jpg]]

== Project team ==
Garth Fernandez

Tuo Jiang

Delana Seneviratne

Supervisor- Dr Andrew Allison

Advisor- Dr Said Al-Sarawi

== Abstract ==
Conventional pacemaker technology currently relies on non-rechargeable batteries to power a cardiac pacemaker. This technology has resulted in patient deaths due to the invasive surgery component of replacing the non-rechargeable battery when battery capacity diminishes. The project explores the benefits of a wireless charging system to power a rechargeable battery inside the body. These benefits include longevity and a reduced need for repetitive surgery. The pacemaker will be treated as a black box. The system needs to provide desirable voltage and current characteristics to charge the battery efficiently, such that the patient doesn’t have to wear the transmitter coil for extended lengths. The wireless charging system consists of a set of transmitter and receiver coils, electronics and a rechargeable battery. The transmitter coil will sit on the skin near the left shoulder while a smaller receiver will be implanted at a distance of up to 1cm in the skin.

== Background ==
[[File:Pacemaker_module_.jpg]]

Pacemaker consists of three main modules which are power source, pulse generator and electrodes. Pacemakers monitors heart activity through the electrode leads connected to the heart. The electrodes send a signal to the pulse generator to excite an electrical pulse to control abnormal heart rhythms.

== Aim ==
Develop wireless charging system for pacemaker

Utilize a simple circuit model for a pacemaker to build WPT charging system.

== System Design ==
The system includes three modules, which are transmitter module(with coil), receiver module(with coil) and battery charging module.

== Performance ==
The system can provide around 400mA to the rechargeable battery.

== Challenges ==
The feedback and the battery capacity are two main challenges for the project.

== Conclusion ==

== References ==

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T07:14:44Z

A1670552: /* Project Title- Pacemaker Wireless Charging System */

== Project Title- Pacemaker Wireless Charging System ==

[[File:Pacemaker_system1.jpg]]

== Project team ==
Garth Fernandez (a1670552), Tuo Jiang (a1656056) and Delana Seneviratne (1670515)

Supervisor- Dr Andrew Allison

Advisor- Dr Said Al-Sarawi

== Abstract ==
Conventional pacemaker technology currently relies on non-rechargeable batteries to power a cardiac pacemaker. This technology has resulted in patient deaths due to the invasive surgery component of replacing the non-rechargeable battery when battery capacity diminishes. The project explores the benefits of a wireless charging system to power a rechargeable battery inside the body. These benefits include longevity and a reduced need for repetitive surgery. The pacemaker will be treated as a black box. The system needs to provide desirable voltage and current characteristics to charge the battery efficiently, such that the patient doesn’t have to wear the transmitter coil for extended lengths. The wireless charging system consists of a set of transmitter and receiver coils, electronics and a rechargeable battery. The transmitter coil will sit on the skin near the left shoulder while a smaller receiver will be implanted at a distance of up to 1cm in the skin.

== Background ==
[[File:Pacemaker_module_.jpg]]

Pacemaker consists of three main modules which are power source, pulse generator and electrodes. Pacemakers monitors heart activity through the electrode leads connected to the heart. The electrodes send a signal to the pulse generator to excite an electrical pulse to control abnormal heart rhythms.

== Aim ==
Develop wireless charging system for pacemaker

Utilize a simple circuit model for a pacemaker to build WPT charging system.

== System Design ==
The system includes three modules, which are transmitter module(with coil), receiver module(with coil) and battery charging module.

== Performance ==
The system can provide around 400mA to the rechargeable battery.

== Challenges ==
The feedback and the battery capacity are two main challenges for the project.

== Conclusion ==

== References ==

File:Pacemaker system1.jpg

2017-09-18T07:14:17Z

A1670552:

File:Pacemaker module1 .jpg

2017-09-18T07:13:12Z

A1670552:

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T07:12:38Z

A1670552: /* Project Title- Pacemaker Wireless Charging System */

== Project Title- Pacemaker Wireless Charging System ==

== Project team ==
Garth Fernandez (a1670552), Tuo Jiang (a1656056) and Delana Seneviratne (1670515)

Supervisor- Dr Andrew Allison

Advisor- Dr Said Al-Sarawi

== Abstract ==
Conventional pacemaker technology currently relies on non-rechargeable batteries to power a cardiac pacemaker. This technology has resulted in patient deaths due to the invasive surgery component of replacing the non-rechargeable battery when battery capacity diminishes. The project explores the benefits of a wireless charging system to power a rechargeable battery inside the body. These benefits include longevity and a reduced need for repetitive surgery. The pacemaker will be treated as a black box. The system needs to provide desirable voltage and current characteristics to charge the battery efficiently, such that the patient doesn’t have to wear the transmitter coil for extended lengths. The wireless charging system consists of a set of transmitter and receiver coils, electronics and a rechargeable battery. The transmitter coil will sit on the skin near the left shoulder while a smaller receiver will be implanted at a distance of up to 1cm in the skin.

== Background ==
[[File:Pacemaker_module_.jpg]]

Pacemaker consists of three main modules which are power source, pulse generator and electrodes. Pacemakers monitors heart activity through the electrode leads connected to the heart. The electrodes send a signal to the pulse generator to excite an electrical pulse to control abnormal heart rhythms.

== Aim ==
Develop wireless charging system for pacemaker

Utilize a simple circuit model for a pacemaker to build WPT charging system.

== System Design ==
The system includes three modules, which are transmitter module(with coil), receiver module(with coil) and battery charging module.

== Performance ==
The system can provide around 400mA to the rechargeable battery.

== Challenges ==
The feedback and the battery capacity are two main challenges for the project.

== Conclusion ==

== References ==

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T07:12:16Z

A1670552: /* Project Title- Pacemaker Wireless Charging System */

== Project Title- Pacemaker Wireless Charging System ==
[[File:Pacemakersystem.jpeg]]

== Project team ==
Garth Fernandez (a1670552), Tuo Jiang (a1656056) and Delana Seneviratne (1670515)

Supervisor- Dr Andrew Allison

Advisor- Dr Said Al-Sarawi

== Abstract ==
Conventional pacemaker technology currently relies on non-rechargeable batteries to power a cardiac pacemaker. This technology has resulted in patient deaths due to the invasive surgery component of replacing the non-rechargeable battery when battery capacity diminishes. The project explores the benefits of a wireless charging system to power a rechargeable battery inside the body. These benefits include longevity and a reduced need for repetitive surgery. The pacemaker will be treated as a black box. The system needs to provide desirable voltage and current characteristics to charge the battery efficiently, such that the patient doesn’t have to wear the transmitter coil for extended lengths. The wireless charging system consists of a set of transmitter and receiver coils, electronics and a rechargeable battery. The transmitter coil will sit on the skin near the left shoulder while a smaller receiver will be implanted at a distance of up to 1cm in the skin.

== Background ==
[[File:Pacemaker_module_.jpg]]

Pacemaker consists of three main modules which are power source, pulse generator and electrodes. Pacemakers monitors heart activity through the electrode leads connected to the heart. The electrodes send a signal to the pulse generator to excite an electrical pulse to control abnormal heart rhythms.

== Aim ==
Develop wireless charging system for pacemaker

Utilize a simple circuit model for a pacemaker to build WPT charging system.

== System Design ==
The system includes three modules, which are transmitter module(with coil), receiver module(with coil) and battery charging module.

== Performance ==
The system can provide around 400mA to the rechargeable battery.

== Challenges ==
The feedback and the battery capacity are two main challenges for the project.

== Conclusion ==

== References ==

File:Pacemaker system.jpg

2017-09-18T07:09:55Z

A1670552:

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T07:08:37Z

A1670552: /* Background */

File:Pacemaker module .jpg

2017-09-18T07:07:04Z

A1670552:

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T07:06:36Z

A1670552: /* Background */

== Project Title- Pacemaker Wireless Charging System ==

== Project team ==
Garth Fernandez (a1670552), Tuo Jiang (a1656056) and Delana Seneviratne (1670515)

Supervisor- Dr Andrew Allison

Advisor- Dr Said Al-Sarawi

== Abstract ==
Conventional pacemaker technology currently relies on non-rechargeable batteries to power a cardiac pacemaker. This technology has resulted in patient deaths due to the invasive surgery component of replacing the non-rechargeable battery when battery capacity diminishes. The project explores the benefits of a wireless charging system to power a rechargeable battery inside the body. These benefits include longevity and a reduced need for repetitive surgery. The pacemaker will be treated as a black box. The system needs to provide desirable voltage and current characteristics to charge the battery efficiently, such that the patient doesn’t have to wear the transmitter coil for extended lengths. The wireless charging system consists of a set of transmitter and receiver coils, electronics and a rechargeable battery. The transmitter coil will sit on the skin near the left shoulder while a smaller receiver will be implanted at a distance of up to 1cm in the skin.

== Background ==
Pacemaker consists of three main modules which are power source, pulse generator and electrodes. Pacemakers monitors heart activity through the electrode leads connected to the heart. The electrodes send a signal to the pulse generator to excite an electrical pulse to control abnormal heart rhythms.

== Aim ==
Develop wireless charging system for pacemaker

Utilize a simple circuit model for a pacemaker to build WPT charging system.

== System Design ==
The system includes three modules, which are transmitter module(with coil), receiver module(with coil) and battery charging module.

== Performance ==
The system can provide around 400mA to the rechargeable battery.

== Challenges ==
The feedback and the battery capacity are two main challenges for the project.

== Conclusion ==

== References ==

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T07:01:22Z

A1670552:

== Project Title- Pacemaker Wireless Charging System ==

== Project team ==
Garth Fernandez (a1670552), Tuo Jiang (a1656056) and Delana Seneviratne (1670515)

Supervisor- Dr Andrew Allison

Advisor- Dr Said Al-Sarawi

== Abstract ==
Conventional pacemaker technology currently relies on non-rechargeable batteries to power a cardiac pacemaker. This technology has resulted in patient deaths due to the invasive surgery component of replacing the non-rechargeable battery when battery capacity diminishes. The project explores the benefits of a wireless charging system to power a rechargeable battery inside the body. These benefits include longevity and a reduced need for repetitive surgery. The pacemaker will be treated as a black box. The system needs to provide desirable voltage and current characteristics to charge the battery efficiently, such that the patient doesn’t have to wear the transmitter coil for extended lengths. The wireless charging system consists of a set of transmitter and receiver coils, electronics and a rechargeable battery. The transmitter coil will sit on the skin near the left shoulder while a smaller receiver will be implanted at a distance of up to 1cm in the skin.

== Background ==
Pacemaker consists of three main modules which are power source, pulse generator and electrodes. Pacemakers monitors heart activity through the electrode leads connected to the heart. The electrodes send a signal to the pulse generator to excite an electrical pulse to control abnormal heart rhythms.

== Aim ==
Develop wireless charging system for pacemaker

Utilize a simple circuit model for a pacemaker to build WPT charging system.

== System Design ==
The system includes three modules, which are transmitter module(with coil), receiver module(with coil) and battery charging module.

== Performance ==
The system can provide around 400mA to the rechargeable battery.

== Challenges ==
The feedback and the battery capacity are two main challenges for the project.

== Conclusion ==

== References ==

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T06:53:33Z

A1670552:

== Project Title- Pacemaker Wireless Charging System ==

== Project team ==
Garth Fernandez (a1670552), Tuo Jiang (a1656056) and Delana Seneviratne (1670515)

Supervisor- Dr Andrew Allison

Advisor- Dr Said Al-Sarawi

== Abstract ==
Conventional pacemaker technology currently relies on non-rechargeable batteries to power a cardiac pacemaker. This technology has resulted in patient deaths due to the invasive surgery component of replacing the non-rechargeable battery when battery capacity diminishes. The project explores the benefits of a wireless charging system to power a rechargeable battery inside the body. These benefits include longevity and a reduced need for repetitive surgery. The pacemaker will be treated as a black box. The system needs to provide desirable voltage and current characteristics to charge the battery efficiently, such that the patient doesn’t have to wear the transmitter coil for extended lengths. The wireless charging system consists of a set of transmitter and receiver coils, electronics and a rechargeable battery. The transmitter coil will sit on the skin near the left shoulder while a smaller receiver will be implanted at a distance of up to 1cm in the skin.

== Aim ==
Develop wireless charging system for pacemaker

Utilize a simple circuit model for a pacemaker to build WPT charging system.

== System Design ==
The system includes three modules, which are transmitter module(with coil), receiver module(with coil) and battery charging module.

== Performance ==
The system can provide around 400mA to the rechargeable battery.

== Challenges ==
The feedback and the battery capacity are two main challenges for the project.

== Conclusion ==

== References ==

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T06:37:56Z

A1670552:

Projects:2017s1-191 Power Electronics for Inductive Power Transfer (IPT)

2017-09-18T06:31:07Z

A1670552: Created page with " == Project Title- Pacemaker Wireless Charging System == == Project team == Garth Fernandez (a1670552), Tuo Jiang (a1656056) and Delana Seneviratne (1670515) Supervisor- Dr..."

Literature Search Training

2017-02-28T04:34:07Z

A1670552:

== 2017 Semester 1 ==

Please enter your project group number in the confirmed LST slot.

{| class="wikitable"
|-
! Week 1 !! Sunday !! Monday !! Tuesday !! Wednesday !! Thursday !! Friday !! Saturday
|-
! 8am || 00 || || || || || ||
|-
! 9am || || || || || || ||
|-
!10am || || || || || 106 || ||
|-
!11am || || || || 140 || ||183 ||
|-
!12pm || || || || Briefing || ||176 ||
|-
! 1pm || || || || Briefing || || ||
|-
! 2pm || || || || 105 || || ||
|-
! 3pm || || || || || || ||
|-
! 4pm || || || 135 (4:30 - 5:30) || || || ||
|-
! 5pm || || || || || || ||
|}

{| class="wikitable"
|-
! Week 2 !! Sunday !! Monday !! Tuesday !! Wednesday !! Thursday !! Friday !! Saturday
|-
! 8am || || || || || || ||
|-
! 9am || || || || || || ||
|-
!10am || || || 109 || || || ||
|-
!11am || || || || || || ||
|-
!12pm || || || || || || ||
|-
! 1pm || || || 103 || || || ||
|-
! 2pm || || || || || || ||
|-
! 3pm || || || || || || ||
|-
! 4pm || || 107 || || || ||
|-
! 5pm || || || || || || ||
|}

{| class="wikitable"
|-
! Week 3 !! Sunday !! Monday !! Tuesday !! Wednesday !! Thursday !! Friday !! Saturday
|-
! 8am || || || || || || ||
|-
! 9am || || || || || || ||
|-
!10am || || || || || || ||
|-
!11am || || || || || || ||
|-
!12pm || || || || Workshop || || ||
|-
! 1pm || || || || Workshop || || ||
|-
! 2pm || || || || || || ||
|-
! 3pm || || || || || || ||
|-
! 4pm || || || || || || ||
|-
! 5pm || || || || || || ||
|}

Literature Search Training

2017-02-28T04:13:40Z

A1670552:

== 2017 Semester 1 ==

Please enter your project group number in the confirmed LST slot.

{| class="wikitable"
|-
! Week 1 !! Sunday !! Monday !! Tuesday !! Wednesday !! Thursday !! Friday !! Saturday
|-
! 8am || 00 || || || || || ||
|-
! 9am || || || || || 191 || ||
|-
!10am || || || || || 106 || ||
|-
!11am || || || || 140 || ||183 ||
|-
!12pm || || || || Briefing || ||176 ||
|-
! 1pm || || || || Briefing || || ||
|-
! 2pm || || || || 105 || || ||
|-
! 3pm || || || || || || ||
|-
! 4pm || || || 135 (4:30 - 5:30) || || || ||
|-
! 5pm || || || || || || ||
|}

{| class="wikitable"
|-
! Week 2 !! Sunday !! Monday !! Tuesday !! Wednesday !! Thursday !! Friday !! Saturday
|-
! 8am || || || || || || ||
|-
! 9am || || || || || || ||
|-
!10am || || || 109 || || || ||
|-
!11am || || || || || || ||
|-
!12pm || || || || || || ||
|-
! 1pm || || || 103 || || || ||
|-
! 2pm || || || || || || ||
|-
! 3pm || || || || || || ||
|-
! 4pm || || 107 || || || ||
|-
! 5pm || || || || || || ||
|}

{| class="wikitable"
|-
! Week 3 !! Sunday !! Monday !! Tuesday !! Wednesday !! Thursday !! Friday !! Saturday
|-
! 8am || || || || || || ||
|-
! 9am || || || || || || ||
|-
!10am || || || || || || ||
|-
!11am || || || || || || ||
|-
!12pm || || || || Workshop || || ||
|-
! 1pm || || || || Workshop || || ||
|-
! 2pm || || || || || || ||
|-
! 3pm || || || || || || ||
|-
! 4pm || || || || || || ||
|-
! 5pm || || || || || || ||
|}