OPTICAL-ELECTRICAL DEVICE USING HYBRID AUTOMATED TESTING EQUIPMENT

An optical-electrical device can implement a feedback-based control loop for temperature of the device during component calibration. The optical-electrical device can implement compressed air to vary the device temperature during calibration. Additionally, non-active components of the device can be provided current to vary the temperature of the device in concert with the provided compressed air. Additional calibration temperatures can be implemented by activating and deactivating additional non-active components in the device, such as light sources, optical amplifiers, and modulators.

OPTICAL-ELECTRICAL DEVICE USING HYBRID AUTOMATED TESTING EQUIPMENT

An optical-electrical device can implement a feedback-based control loop for temperature of the device during component calibration. The optical-electrical device can implement compressed air to vary the device temperature during calibration. Additionally, non-active components of the device can be provided current to vary the temperature of the device in concert with the provided compressed air. Additional calibration temperatures can be implemented by activating and deactivating additional non-active components in the device, such as light sources, optical amplifiers, and modulators.

OPTICAL INTERCONNECTIONS FOR HYBRID TESTING USING AUTOMATED TESTING EQUIPMENT

A hybrid optical-electrical automated testing equipment (ATE) system can implement a workpress assembly that can interface with a device under test (DUT) and a load board that holds the DUT during testing, analysis, and calibration. A test hand can actuate to position the DUT on a socket and align one or more alignment features. The workpress assembly can include two optical interfaces that are optically coupled such that light can be provided to a side of the DUT that is facing away from the load board, thereby enabling the ATE system to perform simultaneous optical and electrical testing of the DUT.

Optical interconnections for hybrid testing using automated testing equipment

A hybrid optical-electrical automated testing equipment (ATE) system can implement a workpress assembly that can interface with a device under test (DUT) and a load board that holds the DUT during testing, analysis, and calibration. A test hand can actuate to position the DUT on a socket and align one or more alignment features. The workpress assembly can include two optical interfaces that are optically coupled such that light can be provided to a side of the DUT that is facing away from the load board, thereby enabling the ATE system to perform simultaneous optical and electrical testing of the DUT.

Optical-electrical device using hybrid automated testing equipment

An optical-electrical device can implement a feedback-based control loop for temperature of the device during component calibration. The optical-electrical device can implement compressed air to vary the device temperature during calibration. Additionally, non-active components of the device can be provided current to vary the temperature of the device in concert with the provided compressed air. Additional calibration temperatures can be implemented by activating and deactivating additional non-active components in the device, such as light sources, optical amplifiers, and modulators.

自動試験装置を使用したハイブリッド試験のための光相互接続

【課題】試験、分析、較正中被試験デバイス（ＤＵＴ）を保持するロードボード及びＤＵＴとインターフェース接続可能なワークプレスアセンブリを実装することができるハイブリッド光電気自動試験装置（ＡＴＥ）システムを提供する。【解決手段】ハイブリッド光電気自動試験装置（ＡＴＥ）システム（光電気試験システム１００）は、試験、分析、較正中被試験デバイス（ＤＵＴ）を保持するロードボード及びＤＵＴ１２０とインターフェース接続可能なワークプレスアセンブリ１１０を実装する。ワークプレスアセンブリ１１０は、ロードボードから離れた方向を向いているＤＵＴの片側に光が提供されるように光学的に結合されている２つの光インターフェースを含む。それによって、ＡＴＥシステムがＤＵＴの光電気同時試験を実行することを可能にする。【選択図】図１

Calibration of optical-electrical devices using a hybrid automated testing equipment

An optical-electrical device can implement a feedback-based control loop for temperature of the device during component calibration. The optical-electrical device can implement compressed air to vary the device temperature during calibration. Additionally, non-active components of the device can be provided current to vary the temperature of the device in concert with the provided compressed air. Additional calibration temperatures can be implemented by activating and deactivating additional non-active components in the device, such as light sources, optical amplifiers, and modulators.

Optical interconnections for hybrid testing using automated testing equipment

Calibration of optical-electrical devices using a hybrid automated testing equipment

Calibration of optical-electrical devices using a hybrid automated testing equipment