Xi Chen

20220370810, Nov 24, 2022

Mar 2, 2022

17/684969

- Sylmar CA, US
Xi Lin Chen - Stevenson Ranch CA, US
Xiyao Xin - Northridge CA, US
Xin Huang - Fremont CA, US

Pacesetter, Inc. - Sylmar CA

A61N 1/372
A61N 1/375
A61N 1/39
A61N 1/378

Certain embodiments described herein related to methods, devices, and systems that provide improved communications between first and second IMDs remotely located relative to one another and capable of communicating using both conductive communication and RF communication. Such a method can include the first IMD using conductive communication to transmit message(s) intended for the second IMD, without using RF communication, during a first period of time that a first trigger event is not detected. The method can also include the first IMD detecting the first trigger event, and in response thereto, the first IMD using RF communication to transmit message(s) intended for the second IMD during a second period of time. Thereafter, in response to first IMD detecting a second trigger event, the first IMD uses conductive communication to transmit one or more messages intended for the second IMD, without using RF communication, during a third period of time.

20220338809, Oct 27, 2022

Feb 11, 2022

17/669968

- Sylmar CA, US
Yash Vardhan Tiwari - Valencia CA, US
Xi Lin Chen - Stevenson Ranch CA, US
Xiyao Xin - North Ridge CA, US

A61B 5/00
A61B 5/024
A61B 5/055
A61B 5/07

An implantable medical device (IMD) is provided and includes sensing circuitry coupled to electrodes. The sensing circuitry is configured to sense electrical biological signals indicative of a non-physiologic condition of interest experienced by a patient during a magnetic resonance imaging (MRI) procedure, and in the presence of an MRI scanning sequence, the MRI scanning sequence includes at least one of radio frequency (RF) or gradient fields that are in an active state for active field intervals. The device includes memory to store the biological signals and to store program instructions and includes a processor that, when executing the program instructions, is configured to: determine start times for the active field intervals when the at least one of RF or gradient fields switch to the active state and manage generation of MRI-induced-noise corrected (MRI-INC) biological signals, based on the start times for the active field intervals, by at least one of: 1) applying a blanking interval to the sensing circuitry to blank a sensing operation during at least portions of the active field interval or 2) modifying segments of the biological signal sensed during at least the portions of the active field interval, and 3) comparing biologic signal sensed during at least the portions of the active field interval to a template. The device analyzes the biological signals for an indication that the patient is experiencing the non-physiologic condition.

20220339452, Oct 27, 2022

Feb 11, 2022

17/670005

- Sylmar CA, US
Xi Lin Chen - Stevenson Ranch CA, US
Xiyao Xin - Northridge CA, US
Yash Vardhan Tiwari - Valencia CA, US

A61N 1/37
G01R 33/28
G01R 33/34
A61B 5/33
A61B 5/29
A61N 1/372
A61N 1/365

An implantable medical device (IMD) includes electronic circuitry, and one or more processors configured to switch operation of a first coil of the electronic circuitry between the first and second modes. When in the first mode, the one or more processors are configured to manage operation of the electronic circuitry and the first coil to at least one of sense biological signals, deliver treatment for a non-physiologic condition, or wirelessly communicate with at least one of an external device or second implanted device. When in the second mode, the one or more processors are configured to manage operation of the electronic circuitry and the first coil to detect the time varying MR generated gradient field along the first axis.

20210069908, Mar 11, 2021

Sep 8, 2020

17/014321

- Berkeley CA, US
Nikhil Mishra - Irvine CA, US
Yu Xuan Liu - Sugar Lane TX, US
Yan Duan - Berkeley CA, US
Andrew Amir Vaziri - Lutherville MD, US
Xi Chen - Berkeley CA, US

B25J 9/16
B25J 13/08

Various embodiments of the present technology generally relate to robotic devices, computer-vision systems, and artificial intelligence. More specifically, some embodiments relate to a computer-vision system for robotic devices. In some implementations, a computer-vision is coupled to a robotic arm for picking items from a bin and perturbing items in a bin. A computer-vision system, in accordance with the present technology, may use at least two two-dimensional (2D) images to generate three-dimensional (3D) information about the bin and items in the bin. A method of training artificial neural networks to generate 3D information from 2D images includes obtaining ground truth data for a scene, obtaining at least two images of the scene, and providing the ground truth data and the at least two images to the artificial neural network configured to generate a depth map from the images based on the ground truth data.

20160338624, Nov 24, 2016

May 18, 2015

14/715385

- Sylmar CA, US
Xi Lin Chen - Valencia CA, US

A61B 5/1473
A61B 5/00
A61B 5/145

In accordance with one embodiment, a blood glucose sensing device is provided that comprises a house having of an exterior surface and that defines an interior space. The housing is configured to be located within a cardiovascular pathway of a patient. An inductor-capacitor (LC) circuit is located within the interior space defined by the housing. The inductor-capacitor circuit comprises an inductive circuit and a capacitive circuit electronically coupled to one another. The inductive and capacitive circuit has inductance and capacitance values that define a blood glucose sensitive resonant frequency such that a resonant frequency of the LC resonant circuit varies in response to changes in blood glucose levels within the blood in the cardiovascular pathway surrounding the housing.

20160338625, Nov 24, 2016

May 18, 2015

14/715390

- Sylmar CA, US
Xi Lin Chen - Valencia CA, US

A61B 5/1473
A61B 5/00
A61B 5/145

A blood glucose sensing device is provided that comprises a house having an exterior surface and that defines an interior space. The housing is configures to be located within a cardiovascular pathway of a patient. A resonant antenna is located within the interior space defined by the housing. The resonant antenna comprises an inductive reactance and a capacitive reactance. The inductive and capacitive reactance have values that define a blood glucose sensitive resonant frequency such that a resonant frequency of the resonant antenna varies in response to changes in blood glucose levels within the blood in the cardiovascular pathway surrounding the housing.

20150084690, Mar 26, 2015

Oct 9, 2013

14/049588

- Irvine CA, US
Xi Chen - Irvine CA, US
Ramon Alejandro Gomez - San Juan Capistrano CA, US

Broadcom Corporation - Irvine CA

H03F 3/21
H03F 3/217

330251, 330291

A system includes a weighting element, a transconductance circuit, a feedback loop, and an auxiliary loop. In some implementations, the transconductance circuit may accept an input and provide a first portion of an output for amplification at a variable amplification level to generate an amplifier output. The feedback loop may provide a portion of the amplifier output as a first feedback to the input. The first feedback may be associated with an impedance that may vary with the amplification level. The auxiliary loop may provide a second feedback to the input to reduce the dependence of the impedance on the amplification level.