A probing apparatus includes a frame, a testing device, a rotatable testing platform, and a probe module. The testing device is disposed on the frame and is displaceable along an X direction and a Y direction perpendicular to the X direction. The rotatable testing platform is disposed on the frame and is rotatable around a rotating axis extending in the X direction. A direction perpendicular to the X direction and the Y direction is a Z direction, and the rotatable testing platform and the testing device are located at different positions of the Z direction. The probe module is disposed on the rotatable testing platform.

A probe installation circuit board includes an insulating layer provided on upper and lower surfaces thereof with a trace structure including two grounding traces and a signal trace located therebetween, and a grounding layer. Each grounding trace is connected with the grounding layer by at least one conductive via including a through hole penetrating through the grounding trace and the insulating layer, and a conductive layer disposed therein to electrically connect the grounding trace and layer. The signal trace and the conductive layers are made of a metal material. The grounding layer and traces are made of another metal material. A probe device includes the circuit board and three probes disposed on the traces respectively. The present invention is capable of thin copper traces and lowered trace surface roughness, easy in control of trace distance, width and thickness, and beneficial to achieve the fine pitch requirement.

A circuit board for semiconductor test includes first and second sub-circuit boards, and an insulating dielectric layer therebetween. Each sub-circuit board includes a substrate and circuits including upper and lower contacts. The insulating dielectric layer includes through holes, and connecting conductors disposed therein and electrically connected with the upper and lower contacts of two sub-circuit boards. The circuit board is defined with central and peripheral regions. The lower contacts of the first sub-circuit board in the central region are electrically connected with a probe head. The upper contacts of the second sub-circuit board in the peripheral region are electrically connected with a tester, larger in pitch than the lower contacts of the first sub-circuit board in the central region, and larger in amount than the lower contacts of the first sub-circuit board in the peripheral region. The circuit board has great power test uniformity.

A circuit board inspection apparatus includes an inspection processing portion that inspects an electric circuit of a board to be inspected, an inspection jig, and a position detector used to position the inspection processing portion relative to the board to be inspected. The inspection jig includes a probe unit having a probe, a first board, a second board located in parallel with the first board in a thickness direction of the first board, an electrical connection portion that electrically connects the first board and the second board, and a second board holding portion that holds the second board from the first board and holds the probe unit on a side opposite to the first board side. The second board holding portion has a position detection opening penetrating in the thickness direction, at a position overlapping the position detector as viewed from the thickness direction of the second board holding portion.

The probe assembly operates with a circuit board test apparatus and includes a main test probe and a secondary test probes. The probe assembly is capable of moving in X, Y and Z directions relative to a circuit board being tested (UUT). The two test probes are movable linearly relative to each other and rotatable together so as to accurately locate the two probes on selected pins on the UUT, for receiving signals from the selected pins. The received signals are transmitted to a display apparatus.

A test device for testing an electronic device has a base, a first mounting plane, a first support element, a plurality of second support elements, a plurality of test elements, and a control unit. The first mounting plane is mounted on the base. The first support element is slidable on the first mounting plane, the second support elements are slidable on the first support element, and the test elements are slidable on the second support elements. The control unit electrically coupled to the test elements controls the test elements to provide impact force on the electronic device.

The probe assembly operates with a circuit board test apparatus and includes a main test probe and a secondary test probes. The probe assembly is capable of moving in X, Y and Z directions relative to a circuit board being tested (UUT). The two test probes are movable linearly relative to each other and rotatable together so as to accurately locate the two probes on selected pins on the UUT, for receiving signals from the selected pins, The received signals are transmitted to a display apparatus.

A testing system for electrical interconnects having a removable device under test printed circuit board (DUT PCB) that electrically connects with the electrical testing components of the system. A removable top plate is placed on top of the DUT PCB and is locked in place by a plurality of locking posts that selectively connect to cam surfaces in the top plate that pull the top plate down sandwiching the DUT PCB between the top plate and the electrical testing components of the system. An actuator is also presented that presses the device under test into the electrical interconnect at increments where tests are performed on one, some or all of the contact points of the electrical interconnect. This information is then analyzed and graphed to assist with determine the optimum force and/or height to use during actual use.

A method includes measuring a first calibration kit in a wafer to obtain a first performance data. The wafer includes a substrate, and a plurality of dielectric layers over the substrate. The first calibration kit includes a first passive device over the plurality of dielectric layers, wherein substantially no metal feature is disposed in the plurality of dielectric layers and overlapped by the first passive device. The method further includes measuring a second calibration kit in the wafer to obtain a second performance data. The second calibration kit includes a second passive device identical to the first device and over the plurality of dielectric layers, and dummy patterns in the plurality of dielectric layers and overlapped by the second passive device. The first performance data and the second performance data are de-embedded to determine an effect of metal patterns in the plurality of dielectric layers to overlying passive devices.

A printed circuit board (PCB) test fixture includes a substrate, a first insulation layer formed on the substrate, a conductor layer formed on the first insulation layer and electrically connected to the upper electrodes through at least one first connection member, a second insulation layer formed on the first insulation layer, and multiple conductive cones arranged on the second insulation layer in a matrix form. A part of the conductive cones is electrically connected to the conductor layer through at least one second connection member. The circuit layout of the conductor layer, the at least one first connection member and the at least one second connection member is employed to supply testing power to a part of the conductive cones and an adjustable arrangement of the conductive cones to enhance density of test probes upon electrical testing.