A temporary bond method and apparatus for allowing wafers, chips or chiplets. To be tested, the temporary bond method and apparatus comprising: a temporary connection apparatus having one of more knife-edged microstructures, wherein the temporary connection apparatus serves, in use, as a probe device for probing the chiplets, each chiplet including a die having one or more flat contact pads which mate with the one of more knife-edged microstructures of the temporary connection apparatus; a press apparatus for applying pressure between the one or more flat contact pads on the chiplet with the one of more knife-edged microstructures of the temporary connection apparatus thereby forming a temporary bond between the temporary connection pad with the knife-edged microstructure in contact with the one or more flat wafer pads; the press being able to apply a pressure to maintain the temporary bond connection during or prior to testing of the chiplet.

A method of testing an integrated circuit of a device is described. Air is allowed through a fluid line to modify a size of a volume defined between the first and second components of an actuator to move a contactor support structure relative to the apparatus and urge terminals on the contactor support structure against contacts on the device. Air is automatically released from the fluid line through a pressure relief valve when a pressure of the air in the fluid line reaches a predetermined value. The holder is moved relative to the apparatus frame to disengage the terminals from the contacts while maintaining the first and second components of the actuator in a substantially stationary relationship with one another. A connecting arrangement is provided including first and second connecting pieces with complementary interengaging formations that restricts movement of the contactor substrate relative to the distribution board substrate in a tangential direction.

As a semiconductor device is miniaturized, a scribe area on a wafer also tends to decrease. Accordingly, it is necessary to reduce the size of a TEG arranged in the scribe area, and efficiently arrange an electrode pad for probe contact. Therefore, it is necessary to associate probes and the efficient layout of the electrode pad. The purpose of the present invention is to provide a technique for associating probes and the layout of the electrode pads of a TEG so as to facilitate the evaluation of electrical characteristics. According to an evaluation apparatus for a semiconductor device of the present invention, the above described problems can be solved by providing a plurality of probes arranged in a fan shape or probes manufactured by Micro Electro Mechanical Systems (MEMS) technology.

A wafer inspection system is provided. The wafer inspection system comprises: a transfer region in which a transfer device is arranged; an inspection region in which test heads for inspecting a substrate are arranged; and a maintenance region in which the test heads are maintained. The inspection region is located between the transfer region and the maintenance region, a plurality of inspection rooms accommodating the test heads are adjacent to each other in the inspection region, and the test heads are configured to be unloaded from the inspection region to the maintenance region.

A semiconductor device for testing a semiconductor wafer includes a circuit board, a probe disposed below the circuit board and facing the semiconductor wafer, an integrated substrate disposed between the circuit board and the probe, and signal-transmitting module disposed on the circuit board and next to the integrated substrate. The probe is electrically coupled to the circuit board through the integrated substrate, and the signal-transmitting module transmits a test signal to the probe through the integrated substrate and the circuit board to perform a test to the semiconductor wafer. Another semiconductor device including the integrated substrate and a manufacturing method thereof are provided.

An intermediate connecting member according to one aspect of the present disclosure is provided between a first member including multiple first terminals and a second member including multiple second terminals. The intermediate connecting member includes multiple connection parts configured to electrically connect the first terminals to the second terminals, and a retainer holding the multiple connection parts. Each of the multiple connection parts is formed of an elastic member to which an electrically conductive property is given at least on a surface of the elastic member.

A wafer test device and methods of assembling a wafer test device involve a first laminate structure, and a second laminate structure arranged to interface with a microcircuit of the wafer. The wafer test device includes a compliant layer between the first laminate structure and the second laminate structure. The compliant layer includes an elastomer that exhibits compliance within a limited range of movement.

A testing module for a semiconductor wafer-form package includes a circuit board structure, first connectors, a first connecting structure, second connectors, third connectors and a first bridge connector. The circuit board structure includes two edge regions and a main region located therebetween. The first connectors are located over the edge regions and connected to the circuit board structure. The first connecting structure is located over and distant from the circuit board structure. The second connectors and third connectors are located over and connected to the first connecting structure, where the third connectors are configured to transmit electric signals for testing the semiconductor wafer-form package being placed over the main region. The first bridge connector is electrically coupling the circuit board structure and the first connecting structure by connecting the second connectors and the first connectors.

A testing module for a semiconductor wafer-form package includes a circuit board structure, first connectors, a first connecting structure, second connectors, third connectors and a first bridge connector. The circuit board structure includes two edge regions and a main region located therebetween. The first connectors are located over the edge regions and connected to the circuit board structure. The first connecting structure is located over and distant from the circuit board structure. The second connectors and third connectors are located over and connected to the first connecting structure, where the third connectors are configured to transmit electric signals for testing the semiconductor wafer-form package being placed over the main region. The first bridge connector is electrically coupling the circuit board structure and the first connecting structure by connecting the second connectors and the first connectors.

A testing module for a semiconductor wafer-form package includes a circuit board structure, first connectors, a first connecting structure, second connectors, third connectors and a first bridge connector. The circuit board structure includes two edge regions and a main region located therebetween. The first connectors are located over the edge regions and connected to the circuit board structure. The first connecting structure is located over and distant from the circuit board structure. The second connectors and third connectors are located over and connected to the first connecting structure, where the third connectors are configured to transmit electric signals for testing the semiconductor wafer-form package being placed over the main region. The first bridge connector is electrically coupling the circuit board structure and the first connecting structure by connecting the second connectors and the first connectors.