Ark L Lew

6388422, May 14, 2002

May 18, 1998

09/080650

Ark L. Lew - Ellicott City MD

The Johns Hopkins University - Baltimore MD

H02J 700

320107, 320112, 307 11, 2102

Apparel and sensor coverings comprising a material suitable for use therein and a laminate integrated therein, the laminate comprising a plurality of layers comprising an energy conversion means for delivering electrical energy, electrical energy storing means, and charge management and control circuitry. The invention is used to power electronic applications either integrated with the charge management and control circuitry or incorporated into the laminate as a separate layer to create âsmartâ apparel and sensors. External electronic devices and various types of sensors can be connected and powered using one or more outlets integrated into the material. Antenna(s) and infrared port(s) also integrated into the material permit communications with other wearers of the smart apparel, with and between smart sensors, with local command and control centers on the ground or in the air and with distant headquarters via satellite(s).

6476581, Nov 5, 2002

Mar 14, 2002

10/099035

Ark L. Lew - Ellicott City MD

The Johns Hopkins University - Baltimore MD

H02J 700

320107, 320112, 307 11, 2102

Apparel and sensor coverings comprising a material suitable for use therein and a laminate integrated therein, the laminate comprising a plurality of layers comprising an energy conversion means for delivering electrical energy, electrical energy storing means, and charge management and control circuitry. The invention is used to power electronic applications either integrated with the charge management and control circuitry or incorporated into the laminate as a separate layer to create âsmartâ apparel and sensors. External electronic devices and various types of sensors can be connected and powered using one or more outlets integrated into the material. Antenna(s) and infrared port(s) also integrated into the material permit communications with other wearers of the smart apparel, with and between smart sensors, with local command and control centers on the ground or in the air and with distant headquarters via satellite(s).

6608464, Aug 19, 2003

Jun 30, 1997

08/884714

Ark L. Lew - Ellicott City MD
Joseph J. Suter - Clarksville MD
Binh Q. Le - Vienna VA

The Johns Hopkins University - Baltimore MD

H07J 700

320107, 320101, 320108

A self-contained, small, lightweight, portable, renewable, modular integrated power source. The power source consists of a recharging means such as solar cells that are laminated onto a rechargeable energy source such as a solid state polymer battery which in turn is laminated onto a substrate containing circuits which manage the polymer battery charging. Charging of the battery can occur via solar energy or, alternatively, via RF coupling using external RF charging equipment or a hand held generator. For added support, the integrated power source is then bonded to an applications housing or structure. This integrated power source can independently power the electronic application. It can also serve as casing or housing by taking the shape of the application enclosure.

6847913, Jan 25, 2005

Oct 4, 2002

10/264442

Fredrick M. Wigley - Baltimore MD, US
Robert A. Wise - Baltimore MD, US
Paul D. Schwartz - Arnold MD, US
Ark L. Lew - Ellicott City MD, US
David D. Scott - Columbia MD, US
Binh Q. Le - Vienna VA, US

The Johns Hopkins University - Baltimore MD

G01K 1300

702131, 600349, 600549, 374100, 374101, 374109

An ambulatory skin temperature monitoring system. A flexible band is attachable to a patient. The flexible band also secures an electronics assembly that comprises the various electrical components that monitor and operate the ambulatory skin temperature monitoring system. At least one skin temperature sensor is positioned so that it is in contact with the patients skin when the system is attached to the patient. There is also an ambient temperature sensor positioned on the top surface of the electronics assembly housing for measuring and contrasting the ambient temperature to the skin temperature. The electronics assembly positioned within generally comprises a power source and a micro-controller. The micro-controller is coupled with the skin temperature sensor and the ambient temperature sensor. The micro-controller also includes a memory unit for storing temperature data obtained from the skin temperature sensor and the ambient temperature sensor.

6881593, Apr 19, 2005

May 31, 2002

10/159682

Binh Q. Le - Vienna VA, US
Ark L. Lew - Ellicott City MD, US
Paul D. Schwartz - Arnold MD, US
Seppo J. Lehtonen - Columbia MD, US
Sharon X. Ling - Clarksville MD, US

The Johns Hopkins University - Baltimore MD

H01L021/66

438 14, 438 15, 438 18, 257 48, 257777, 257778, 257782, 257784

A semiconductor die adapter assembly includes a semiconductor die cut from a wafer, the die having an active surface including bond pads. A die adapter, also having bond pads, is bonded to the semiconductor die. Die-to-adapter connectors electrically connect the die bond pads to the adapter bond pads. Finally, adapter-to-substrate connectors electrically connect the adapter bond pads to a device substrate. Having bond pads on the die adapter eliminates the need to break and remake the electrical connections to the original bond pads on the die during burn-in testing of the die.

6967103, Nov 22, 2005

May 3, 2001

10/240902

Paul D. Schwartz - Arnold MD, US
George M. Murray - Columbia MD, US
O. Manuel Uy - Ellicott City MD, US
Binh Q. Le - Vienna VA, US
David D. Scott - Columbia MD, US
Ark L. Lew - Ellicott City MD, US
Sharon X. Ling - Clarksville MD, US
Joseph J. Suter - Ellicott City MD, US

The Johns Hopkins University - Baltimore MD

G01N021/64

436106, 436107, 436110, 436111, 436156, 436172

An explosive detector that utilizes an array of molecularly imprinted polymer (MIP) coated, bifurcated fiber optic cables to form an image of a target molecule source. Individual sensor fiber assemblies, each with a calibrated airflow, are used to expose the fibers to the target molecule. The detector energizes a dedicated excitation light source for each fiber, while simultaneously reading and processing the intensity of the resulting fluorescence that is indicative of the concentration of the target molecule. Processing electronics precisely controls the excitation current, and measures the detected signal from each narrow band pass filter and photodiode. A computer with display processes the data to form an image of the target molecule source that can be used to identify the source even when low level contamination of the same molecule is present. The detector can be used to detect multiple and/or non-explosive targets by varying the MIP coating.

20040210472, Oct 21, 2004

Jul 24, 2003

10/626154

Ark Lew - Ellicott City MD, US
Martin Fraeman - Olney MD, US
Binh Le - Vienna VA, US

G06F017/60

705/010000

A real-time feedback survey system and method allowing for responses to survey questions to be input by users and received by the surveyor in real-time is provided. This result is achieved by using a media player to provide a request for feedback information to a remote responding device, the remote responding device allowing response input and incorporating a transmitter for transmitting the response to a central facility.

62557998, Jul 3, 2001

Dec 29, 1999

9/474515

Binh Q. Le - Vienna VA
Ark L. Lew - Ellicott City MD
Paul D. Schwartz - Arnold MD
Albert C. Sadilek - Elkridge MD
Joseph J. Suter - Ellicott City MD
Jason E. Jenkins - Columbia MD
Sharon X. Ling - Clarksville MD

The Johns Hopkins University - Baltimore MD

H02J 700
H02K 500
A43B 702

320107

The invention comprises a means for generating energy while walking or running for storage in a rechargeable battery. One embodiment uses lever arm movement in the heel of a shoe resulting from normal walking or running to generate energy from a built-in generator. The linear or rotational motion of the lever arm engages the circular gear assembly and turns the generator/motor/turbine, thus generating power. The second embodiment uses fluid reservoirs embedded in the shoes. Pressure changes resulting from normal walking or running moves the fluid through a narrow channel connecting two reservoirs, thus generating power by rotating a flywheel and an attached motor/generator/turbine in the middle of the channel. Secondary (rechargeable) batteries are incorporated into the invention either in an integrated form or as an add-on design. Additional features include a digital diagnostic data output, which would serves as a "fuel gauge" for the secondary batteries, and a smart charging circuit that efficiently controls battery charging from a generator output that varies with step rate and force.