Carlos De

US Patent:

20070019162, Jan 25, 2007

Filed:

Jul 25, 2005

Appl. No.:

11/188316

Inventors:

Carlos Gomez de Llarena - New York NY, US

International Classification:

G03B 21/00

US Classification:

353013000

Abstract:

An apparatus and method for selectively displaying data. The apparatus includes an aerial support mechanism, such as a helium balloon, adapted to be positioned at a desired location, which may be changed based on a user preference. The apparatus also includes a processor, coupled to the aerial support mechanism, which accesses, retrieves and stores display data. A projection module is coupled to the processing module. The projection module displays portions of the data, as a function of the processor. The projection module displays the portions of the data on a surface such as the ground, side of a building or screen. User-input commands determine the portions of the data displayed by the projection module and the projection module displays different data over a predetermined period of time. Also, a mobile display, mounted on a bus or taxi, can be used to display data based on the location of the mobile display.

US Patent:

20220304567, Sep 29, 2022

Filed:

May 25, 2022

Appl. No.:

17/824209

Inventors:

- Etagnières, CH
Thierry Varidel - Ecublens, CH
Raphael Fritschi - Lausanne, CH
Carlos Gustavo De Moraes - New York NY, US

International Classification:

A61B 3/00
A61B 3/024
A61B 3/107
A61B 3/16

Abstract:

This disclosure provides a method for determining the likelihood of being at or beyond a certain rate and/or risk of visual field progression (VFP) of a user, that may include measuring ocular biomechanical properties (OBP) through a continuous-wear sensor placed on or implanted in the eye; recording the user's ocular biomechanical properties in the form of at least one OBP time series plot in a recorder, a processing step wherein at least one of a plurality of OBP parameters are extracted from the recorded OBP time series plot; a calculation step wherein the at least one of a plurality of OBP parameters are associated to VFP, and a determining step wherein one determines whether the visual field progression is at or beyond a certain VFP threshold and/or the probability that the said visual field progression is comprised within a specific range.

US Patent:

20210250232, Aug 12, 2021

Filed:

Jan 25, 2021

Appl. No.:

17/157558

Inventors:

- Atlanta GA, US
Carlos Eduardo De Andrade - Highland Park NJ, US
Weiyi Zhang - Edison NJ, US
Robert Riding - Bothell WA, US

International Classification:

H04L 12/24
H04N 21/462

Abstract:

A new scalable approach to conflict-free deployment of changes across networks. The conflict rules or constraints may be modeled using policies and algorithms to determine an optimized schedule for change deployment.

US Patent:

20210022013, Jan 21, 2021

Filed:

Oct 1, 2020

Appl. No.:

17/060963

Inventors:

- Atlanta GA, US
Yuning Yang - Basking Ridge NJ, US
Carlos Eduardo De Andrade - Gainesville FL, US
Nemmara Shankaranarayanan - Bridgewater NJ, US
Sarat Puthenpura - Berkeley Heights NJ, US
Wenjie Zhao - Princeton NJ, US
Slawomir Stawiarski - Carpentersville IL, US

International Classification:

H04W 16/18
H04W 24/02

Abstract:

Facilitating model-driven automated cell allocation in advanced networks (e.g., 5G and beyond) is provided herein. Operations of a method can comprise determining, by a system comprising a processor, a solution to an integer programming problem based on input data associated with a network inventory and configuration data for network devices of a group of network devices included in a communications network. Also, the method can comprise determining, by the system, respective cell identities and respective root sequence index assignments for the network devices. Further, the method can comprise implementing, by the system, a deployment of the respective cell identities and respective root sequence index assignments at the network devices.

US Patent:

20200267052, Aug 20, 2020

Filed:

Feb 15, 2019

Appl. No.:

16/277347

Inventors:

- Atlanta GA, US
Carlos Eduardo De Andrade - Highland Park NJ, US
Weiyi Zhang - Edison NJ, US
Robert Riding - Bothell WA, US

International Classification:

H04L 12/24

Abstract:

A new scalable approach to conflict-free deployment of changes across networks. The conflict rules or constraints may be modeled using policies and algorithms to determine an optimized schedule for change deployment.

US Patent:

20200214551, Jul 9, 2020

Filed:

Jun 14, 2017

Appl. No.:

16/622598

Inventors:

- Lausanne, CH
Thierry Varidel - Ecublens, CH
Raphael Fritschi - Lausanne, CH
Carlos Gustavo De Moraes - New York NY, US

International Classification:

A61B 3/00
A61B 3/024
A61B 3/107
A61B 3/16

Abstract:

The invention relates to a method for determining the likelihood of being at or beyond a certain rate and/or risk of visual field progression (VFP) of a user, comprising the following steps: an installing step (S) comprising placing or implanting a continuous-wear sensor on or in an eye of a user; a measuring step (S) comprising measuring ocular biomechanical properties (OBP) through the continuous-wear sensor placed on or implanted in the eye, with said measurement comprising repeated data capture at regular time intervals; a recording step (S) comprising recording the user's ocular biomechanical properties in the form of at least one OBP time series plot in a recorder; a processing step (S) wherein at least one of a plurality of OBP parameters are extracted from the at least one recorded OBP time series plot; a calculation step (S) wherein the at least one of a plurality of OBP parameters are associated to VFP; a determining step (S) wherein one determines whether the visual field progression is at or beyond a certain VFP threshold and/or the probability that the said visual field progression is comprised within a specific range; a predicting step (S) wherein based on the determined VFP, one predicts the probability of a patient to develop a glaucoma, and a judging step (S) for judging of a specific medical treatment based on the above prediction result.

US Patent:

20200126033, Apr 23, 2020

Filed:

Oct 3, 2019

Appl. No.:

16/591736

Inventors:

- Erlangen, DE
Quoc-Viet NGUYEN - Erlangen, DE
Anton BAUMANN - Berg Bei Neumarkt In Der Oberpfalz, DE
Herbert PERTL - Erlangen, DE
Manuel BERBIG - Hirschaid, DE
Julian WAGNER - Nuernberg, DE
Carlos J. DE OLIVEIRA - New York NY, US
Marc SCHWENGER - Herzogenaurach, DE
Anne HORST - Erlangen, DE
Markus JECHOW - Erlangen, DE
Igor RABYNOVYCH - Fuerth, DE
Edgar SCHULLER - Erlangen, DE

Assignee:

Siemens Healthcare GmbH - Erlangen

International Classification:

G06Q 10/08
G06N 20/00

Abstract:

A method of an embodiment includes obtaining first measurement data indicative of one or more environmental conditions of field devices during a shipment of the field devices; obtaining second measurement data indicative of one or more operational conditions of the field devices during an operation of the of field devices; and performing a comparison of the first measurement data and the second measurement data to obtain correlation data indicative of an impact of the one or more environmental conditions on the operation of the field devices.

US Patent:

20200022147, Jan 16, 2020

Filed:

Sep 26, 2019

Appl. No.:

16/584102

Inventors:

- Atlanta GA, US
Simon D. Byers - Summit NJ, US
Carlos Eduardo De Andrade - Highland Park NJ, US
Emir Halepovic - Somerset NJ, US
David John Poole - Maplewood NJ, US
Christopher T. Volinsky - Morristown NJ, US

International Classification:

H04W 72/04
H04L 29/08

Abstract:

A more efficient over-the-air software push can be facilitated by leveraging a smart scheduling system for vehicles. The smart scheduling system can use location and network capacity data to prioritize over-the-air software pushes for vehicles. For instance, a vehicle, which is only operational during off-peak wireless network hours can receive a software push during the off-peak times because wireless network capacity is not an issue. However, vehicles, which are used primarily during heavy peak wireless network times can receive software in a prioritized manner based on location data, frequency of use, network capacity, etc.