Abstract: A number of connectors and related methods that allow for high data rate transmissions are described. An example connector includes a housing and a wafer. The water includes signal conductors, a ground conductors, a flexible shield, and a rigid shield. The flexible shield includes terminal end portions, cantilever spring end portions, and a flexible shield body between the terminal end portions and the cantilever spring end portions. The flexible shield body covers a first portion of the ground conductors, and the rigid shield covers a second portion of the ground conductors.

Abstract: A number of connectors and related methods that allow for high data rate transmissions are described. An example connector includes a housing and a wafer. The water includes signal conductors, a ground conductors, a flexible shield, and a rigid shield. The flexible shield includes terminal end portions, cantilever spring end portions, and a flexible shield body between the terminal end portions and the cantilever spring end portions. The flexible shield body covers a first portion of the ground conductors, and the rigid shield covers a second portion of the ground conductors.

Abstract: A number of connectors and related methods that allow for high data rate transmissions are described. An example connector includes a housing and a wafer. The water includes signal conductors, a ground conductors, a flexible shield, and a rigid shield. The flexible shield includes terminal end portions, cantilever spring end portions, and a flexible shield body between the terminal end portions and the cantilever spring end portions. The flexible shield body covers a first portion of the ground conductors, and the rigid shield covers a second portion of the ground conductors.

Abstract: Input/output (I/O) connectors (1) for conducting data at high data rates, (e.g. 112 gigabits per second or more) are provided with protective shields (4, 5, 6) to provide increased mechanical strength and signal integrity.

Abstract: An autonomous vehicle having a lidar sensor system is described. A computing system is configured to determine that the lidar sensor system is to update a code that is included in light signals emitted by the lidar sensor system. The computing system transmits a command signal to the lidar sensor system, wherein the command signal causes the lidar sensor system to transition from emitting light signals with a first code therein to emitting light signals with a second code therein, wherein the first code is different from the second code.

Abstract: An autonomous vehicle having a lidar sensor system is described. A computing system is configured to determine that the lidar sensor system is to update a code that is included in light signals emitted by the lidar sensor system. The computing system transmits a command signal to the lidar sensor system, wherein the command signal causes the lidar sensor system to transition from emitting light signals with a first code therein to emitting light signals with a second code therein, wherein the first code is different from the second code.

Abstract: An inflator assembly arranged in an airbag system for use in a vehicle includes an elongated inflator with at least one mounting stud for mounting the inflator assembly in the vehicle and a gas deflector having a back plate and a front cover with at least one opening to diffuse gas generated from the inflator. The front cover is slid on the back plate along a longitudinal axis of the inflator such that the front cover is slidably engaged with the back plate to enclose a portion of the inflator. Further, the front cover and the back plate are securely engaged with each other by a crimp process to prevent opening or deforming of the gas deflector.

Abstract: An autonomous vehicle having a lidar sensor system is described. A computing system is configured to determine that the lidar sensor system is to update a code that is included in light signals emitted by the lidar sensor system. The computing system transmits a command signal to the lidar sensor system, wherein the command signal causes the lidar sensor system to transition from emitting light signals with a first code therein to emitting light signals with a second code therein, wherein the first code is different from the second code.

Abstract: Input/output (I/O) connectors (1) for conducting data at high data rates, (e.g. 112 gigabits per second or more) are provided with protective shields (4, 5, 6) to provide increased mechanical strength and signal integrity.

Abstract: An autonomous vehicle having a lidar sensor system is described. A computing system is configured to determine that the lidar sensor system is to update a code that is included in light signals emitted by the lidar sensor system. The computing system transmits a command signal to the lidar sensor system, wherein the command signal causes the lidar sensor system to transition from emitting light signals with a first code therein to emitting light signals with a second code therein, wherein the first code is different from the second code.

Abstract: An autonomous vehicle having a lidar sensor system is described. A computing system is configured to determine that the lidar sensor system is to update a code that is included in light signals emitted by the lidar sensor system. The computing system transmits a command signal to the lidar sensor system, wherein the command signal causes the lidar sensor system to transition from emitting light signals with a first code therein to emitting light signals with a second code therein, wherein the first code is different from the second code.

Abstract: An inflator including a chamber that houses a quantity of inflation gas. The chamber is sealed by a burst disk. A punch is also added. The punch is positioned proximate the burst disk. An initiator is also added to the inflator. The initiator includes a cylinder storing a quantity of ignitable material. The cylinder also includes a folded wall with a closed end, wherein upon ignition of the ignitable material, the folded wall unfolds causing the punch to fail the burst disk. The inflator may also be designed such that the folded wall and the closed end retain all of the products formed by ignition of the ignitable material within the cylinder. The inflator may also be designed such that actuation of the initiator does not cause a flash.

Abstract: The present invention provides an airbag inflator assembled, in part, using ultrasonic welding. The inflator includes a housing adapted to receive an initiator assembly and an adaptor socket to connect the inflator to the electronic systems of the vehicle. The initiator and the adaptor socket are welded together at a point of interface through the housing of the inflator using an ultrasound welding process. Joint seals are provided that allow the production of a gas-tight seal upon completion of assembly of the airbag inflator.

Abstract: The present invention provides an airbag inflator assembled, in part, using ultrasonic welding. The inflator includes a housing adapted to receive an initiator assembly and an adaptor socket to connect the inflator to the electronic systems of the vehicle. The initiator and the adaptor socket are welded together at a point of interface through the housing of the inflator using an ultrasound welding process. Joint seals are provided that allow the production of a gas-tight seal upon completion of assembly of the airbag inflator.