The design of a high-density neural recording system targeting epilepsy monitoring is presented. Circuit challenges and techniques are discussed to optimize the amplifier topology and the included OTA. A new platform supporting active recording devices targeting wireless and high-resolution focus localization in epilepsy diagnosis is also proposed. The post-layout simulation results of an amplifier dedicated to this application are presented. The amplifier is designed in a UMC 0.18µm CMOS technology, has an NEF of 2.19 and occupies a silicon area of 0.038 mm(2), while consuming 5.8 µW from a 1.8-V supply
In this paper we discuss the challenges in designing high-density biomedical neural implants. We dis...
This brief presents a new architecture for an ultra-low power and area-efficient 8-channel prototype...
One percent of the world\u27s population, including over 3 million Americans, suffers from epilepsy....
Closed-loop implantable electronics offer a new trend in therapeutic systems aimed at controlling so...
Closed-loop implantable electronics offer a new trend in therapeutic systems aimed at controlling so...
Brain-machine interfaces (BMI) are electronic devices that form an interconnection between the users...
This dissertation presents the system architecture and implementation of two wireless systems-on-chi...
AbstractA device capable of recording single unit activity (SUA) deep within the brain is presented ...
This thesis focuses on integrated and miniaturized wireless neural recording systems for bio-instrum...
Abstract—To create a wireless neural recording system that can benefit from the continuous advanceme...
This thesis presents the design, testing, implantation and limitations of neural recording arrays wi...
Development of brain-machine interfaces and treatment of neurological diseases can benefit from anal...
To create a wireless neural recording system that can benefit from the continuous advancements being...
Neural signal recording systems are vital for understanding the working of the brain. With the growi...
Clinically viable and minimally invasive neural interfaces stand to revolutionize disease care for p...
In this paper we discuss the challenges in designing high-density biomedical neural implants. We dis...
This brief presents a new architecture for an ultra-low power and area-efficient 8-channel prototype...
One percent of the world\u27s population, including over 3 million Americans, suffers from epilepsy....
Closed-loop implantable electronics offer a new trend in therapeutic systems aimed at controlling so...
Closed-loop implantable electronics offer a new trend in therapeutic systems aimed at controlling so...
Brain-machine interfaces (BMI) are electronic devices that form an interconnection between the users...
This dissertation presents the system architecture and implementation of two wireless systems-on-chi...
AbstractA device capable of recording single unit activity (SUA) deep within the brain is presented ...
This thesis focuses on integrated and miniaturized wireless neural recording systems for bio-instrum...
Abstract—To create a wireless neural recording system that can benefit from the continuous advanceme...
This thesis presents the design, testing, implantation and limitations of neural recording arrays wi...
Development of brain-machine interfaces and treatment of neurological diseases can benefit from anal...
To create a wireless neural recording system that can benefit from the continuous advancements being...
Neural signal recording systems are vital for understanding the working of the brain. With the growi...
Clinically viable and minimally invasive neural interfaces stand to revolutionize disease care for p...
In this paper we discuss the challenges in designing high-density biomedical neural implants. We dis...
This brief presents a new architecture for an ultra-low power and area-efficient 8-channel prototype...
One percent of the world\u27s population, including over 3 million Americans, suffers from epilepsy....