Device and method for analyzing a probe, in particular for analyzing a symmetrical, differential probe. A ground-based test signal is provided to a main signal line, wherein the main signal line is terminated by a predetermined impedance. Furthermore, at least one additional signal line is provided, wherein a further impedance is arranged between the additional signal line and the ground. Accordingly, a differential probe may measure a differential signal between the main signal line and the additional signal line. Hence, no grounded signal is provided to the probe. This measurement of the probe can be compared with a reference signal directly acquired on the main signal line. In this way, characteristic values such as impedance and/or frequency response of the probe can be determined.

An oscilloscope probe includes a tip network, a low-loss signal cable, and a terminating assembly. The tip network is connected to the signal cable and is configured to electrically connect to a device under test via a tip network node. The terminating assembly includes an amplifier, a feedback network and a terminating attenuator. The amplifier has an inverting input, a non-inverting input connected to ground, and an amplifier output configured to connect to an oscilloscope input. The feedback network is connected between the inverting input and the amplifier output. The terminating attenuator includes a first loop circuit and a second loop circuit. The first loop circuit is provided between the signal cable and the inverting input of the amplifier. The second loop circuit is provided between the signal cable, and ground. Resistance of terminating resistors in the loop circuits are selected to match characteristic impedance of the signal cable.

A test adapter apparatus comprising at least one device under test, DUT, holder adapted to hold a device under test, DUT and adapted to be plugged in into a docking station of said test adapter apparatus, wherein the docking station has RF and data interfaces used for connecting at least one external test device through said docking station with the device under test, DUT, held by said device under test holder.

The inspection jig includes a rigid substrate, a flexible substrate connected to the rigid substrate, a support for supporting a part of the flexible substrate in a state that the part of the flexible substrate is protruded with respect to the rigid substrate, and a stretchable contactor provided on a protruding portion of the flexible substrate.

An interconnect structure is provided which includes: a member having a first end coupled to a test card, and a second end opposite the first end; and a contact tip at the second end of the member, the contact tip to removably attach to another interconnect structure of a device under test, where a modulus of elasticity of the member varies along a length of the member.

The present invention relates to systems and methods that enable a connection to be made to a high speed, packaged or unpackaged semiconductor device that preserves signal integrity using probes that exhibit the properties of a coaxial transmission line so as to provide an accurate representation of the environment in which the device under test will be used. The coaxial structure further reduces capacitive coupling between probes resulting in significantly improved crosstalk performance.

A high-frequency testing probe having a probe substrate and at least two probe tips. The probe substrate is a printed circuit board and the probe tips are coupled to and extend outward from the printed circuit board. The first and second probe tips are each communicatively coupled to respective first and second probe connectors through respective first and second conducting traces disposed upon the printed circuit board. The probe connectors are configured to couple the testing probe to at least one of a high-frequency vector network analyzer and a high-frequency time domain reflectometer. The probe tips translate along their respective central longitudinal axes through respective adjustable couplings to modify respective distances the probe tips extend outward from the printed circuit board.

A transmission line arrangement having a first end and a second end, the transmission line arrangement being configured to transmit a signal between the first end and the second end, the transmission line arrangement comprising a signal conductor extending between the first end and the second end of the transmission line arrangement, a first conducting sheet and a second conducting sheet positioned on two opposing sides of the signal conductor, an insulating material separating the first and second conducting sheets from the signal conductor and a plurality of pieces of conducting material extending between the first and second conducting sheets and arranged at different positions between the first and second ends of the transmission line arrangement, wherein the pieces of conducting material and the conducting sheets are arranged to substantially surround the signal conductor for at least part of its length between the first and second ends of the transmission line arrangement.

A probe card device includes an upper die unit, a lower die unit, a spacer sandwiched between the upper and lower die units, an impedance adjusting member, and conductive probes. The upper die unit includes a first die and a second die spaced apart from the first die. The first die has a penetrating hole, and the second die has a circuit layer. The impedance adjusting member is disposed on the second die and is electrically coupled to the circuit layer. Each of the conductive probes passes through the upper die unit, the spacer, and the lower die unit. At least one of the conductive probes includes an upper contacting segment protruding from the upper die unit and an extending arm connected to the upper contacting segment. The extending arm is abutted against the circuit layer by passing through the penetrating hole.

A probe carrier of a probe card device includes an upper die unit, a lower die unit, a spacer sandwiched between the upper and lower die units, and an impedance adjusting member. The upper die unit includes a first die, a second die spaced apart from the first die, and a flexible board disposed on the second die and arranged away from the first die. The flexible board includes a plurality of penetrating holes and a circuit layer. The impedance adjusting member is disposed on the flexible board and is electrically coupled to the circuit layer. The circuit layer includes at least one plated wall arranged in at least one of the penetrating holes, a part of the flexible board having the at least one plated wall is separable from the second die by receiving an internal force.