Abstract: An apparatus and method are provided for the automatic operation of a manipulator to move a test head or peripheral into position for proper alignment and docking of the test head with the peripheral. Examples of peripherals include a handler and a prober. Sensors are provided to obtain relative positional information of the test head in the relation to the peripheral, allowing a controller to issue instructions to the manipulator to correct differences in each of the six degrees of freedom between the mating surfaces of the test head and the manipulator.

Abstract: An apparatus and method are provided for the automatic operation of a manipulator to move a test head or peripheral into position for proper alignment and docking of the test head with the peripheral. Examples of peripherals include a handler and a prober. Sensors are provided to obtain relative positional information of the test head in the relation to the peripheral, allowing a controller to issue instructions to the manipulator to correct differences in each of the six degrees of freedom between the mating surfaces of the test head and the manipulator.

Abstract: A manipulator for supporting heavy as well as lighter test heads in a small footprint includes a body and an interface for supporting a test head from behind. The interface includes a first portion fixedly attached to the body and a second portion fixedly attached to the rear of the test head. The first and second portions of the interface are rotatably coupled together to allow rotation of the test head about its approximate center of mass. Although the weight of the test head is entirely borne from the rear, the test head can still be moved with relatively little applied force, thereby satisfying the requirements for compliant docking.

Abstract: A probe tower for an automatic test system includes an insulative retainer for holding an array of differential probe assemblies. Each differential probe assembly is an elongated structure having first and second ends and first and second coaxial portions. Each coaxial portion includes an outer conductor and a pair of annular insulators positioned therein for holding a center conductor. First and second contact pins extend from the center conductor at the first and second ends, respectively. First and second ground pins, which are electrically connected to the outer conductors of the first and second coaxial portions, extend from the first and second ends for conveying ground connections.

Abstract: A probe tower for an automatic test system includes an insulative retainer for holding an array of differential probe assemblies. Each differential probe assembly is an elongated structure having first and second ends and first and second coaxial portions. Each coaxial portion includes an outer conductor and a pair of annular insulators positioned therein for holding a center conductor. First and second contact pins extend from the center conductor at the first and second ends, respectively. First and second ground pins, which are electrically connected to the outer conductors of the first and second coaxial portions, extend from the first and second ends for conveying ground connections.

Abstract: A manipulator for supporting heavy as well as lighter test heads in a small footprint includes a body and an interface for supporting a test head from behind. The interface includes a first portion fixedly attached to the body and a second portion fixedly attached to the rear of the test head. The first and second portions of the interface are rotatably coupled together to allow rotation of the test head about its approximate center of mass. Although the weight of the test head is entirely borne from the rear, the test head can still be moved with relatively little applied force, thereby satisfying the requirements for compliant docking.

Abstract: An interface for making blind-mate connections between a test head of an automatic test system and a device interface board (DIB) includes floating brackets that are individually and compliantly coupled to the test head. The floating brackets each include a plurality of blind-mate connectors and alignment pins for engaging alignment holes within the DIB. When the DIB is pulled down against the test head, the floating brackets can individually move in compliance with applied forces to align the blind-mate connectors with complementary connectors on the DIB.

Abstract: A docking mechanism for docking a test head with a peripheral includes a latching mechanism that extends from a pneumatically actuated piston. The latching mechanism includes a latch barrel, a latchpin, and a biasing spring. The latchpin moves within the latch barrel for establishing latched and unlatched positions. An application of fluid pressure to the latchpin via a first fluid path causes the latchpin to advance to the latched position. A release of fluid pressure from the first path causes the latchpin to retract, in compliance with the biasing spring, to the unlatched position. An application of fluid pressure via a second fluid path to a surface of the piston causes the latching mechanism as a whole to retract. When the test head and peripheral are latched together, this retraction causes the peripheral to be pulled down against the test head, and thus causes electrical connections to be formed between the test head and a device under test.

Abstract: A docking mechanism for docking a test head with a peripheral includes a latching mechanism that extends from a pneumatically actuated piston. The latching mechanism includes a latch barrel, a latchpin, and a biasing spring. The latchpin moves within the latch barrel for establishing latched and unlatched positions. An application of fluid pressure to the latchpin via a first fluid path causes the latchpin to advance to the latched position. A release of fluid pressure from the first path causes the latchpin to retract, in compliance with the biasing spring, to the unlatched position. An application of fluid pressure via a second fluid path to a surface of the piston causes the latching mechanism as a whole to retract. When the test head and peripheral are latched together, this retraction causes the peripheral to be pulled down against the test head, and thus causes electrical connections to be formed between the test head and a device under test.

Abstract: A telephone status recognition and bypass system includes a plurality of status recognition units, and a controller. Each status recognition unit interfaces a subscriber's telecommunication line between a plurality of peripheral services and to a switch network, and includes status monitoring circuits and an SRU switch. The status monitoring circuits monitor status of calls incoming to and outgoing from the service subscriber, and produces status signals representative thereof. The SRU switch switchably interconnects the service subscriber, the switch network, and the peripheral services, for telecommunications in response to switching control signals. The controller is responsive to the status monitoring circuits, and produces switching control signals as a function of the status signals.