CN217507717U - Cable connection structure, probe block, signal expansion device and semiconductor tester - Google Patents

Abstract

The application relates to a cable connection structure, a probe block, a signal expansion device and a semiconductor tester. The cable connection structure includes: the coaxial cable comprises a substrate, a first through hole structure, a second through hole structure and a signal transmission line are arranged in the substrate, the signal transmission line is used for connecting the first through hole structure and the second through hole structure, the first through hole structure is used for enabling a wire core of the coaxial cable to penetrate through so as to be connected with a first signal type probe, and the second through hole structure is used for accommodating a second signal type probe; the conducting ring is arranged in the first through hole structure and is electrically connected with the signal transmission line, and the conducting ring is used for being electrically connected with the woven net layer of the coaxial cable. By adopting the cable connecting structure to connect the cable and the probe block, the continuity and the integrity of a signal return path can be kept.

Description

Cable connection structure, probe block, signal expansion device and semiconductor tester

Technical Field

The application relates to the technical field of signal transmission, in particular to a cable connecting structure, a probe block, a signal expansion device and a semiconductor tester.

Background

The coaxial cable comprises a cable core, a dielectric layer, a woven net layer and an insulating layer which are sequentially stacked from inside to outside, wherein when the cable is used for high-speed signal transmission, the cable core is used for transmitting signals, the dielectric layer is used for controlling impedance, the woven net layer is equivalent to a shielding ground and used as a return path of the signals and also used for shielding external noise, after the external signals are led in from the cable core, the signals are shielded to prevent the signals from leaking to the outside of the coaxial cable, and the insulating layer is equivalent to a protective sleeve and used for protecting each layer structure inside.

When an existing cable is connected with a probe on a probe block, a wire core is usually connected with a first signal type probe, a woven net is cut open and stroked into a burr line group, the burr line group is connected with an adjacent second signal type probe, namely, a signal ground end is connected to the second signal type probe through the burr line group, but the connection mode enables the first signal type probe to be matched with the second signal type probe only, the integrity of return signals is poor, and the phenomenon of signal crosstalk is easy to occur. Meanwhile, the burr line group is obliquely connected with the second signal type probe, and an air gap exists between the burr line group and the dielectric layer, so that the dielectric layer can introduce an air medium, the signal impedance is discontinuous, and the integrity of a return signal is further reduced.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is necessary to provide a cable connection structure, a probe block, a signal extension apparatus, and a semiconductor tester capable of ensuring the integrity of a return signal in response to the above-described technical problems.

A cable connection structure for connecting a coaxial cable and a probe block, the probe block including a first signal type probe and a second signal type probe, the cable connection structure comprising:

the coaxial cable comprises a substrate, a first through hole structure, a second through hole structure and a signal transmission line are arranged in the substrate, the signal transmission line is used for connecting the first through hole structure and the second through hole structure, the first through hole structure is used for enabling a wire core of the coaxial cable to penetrate through so as to be connected with a first signal type probe, and the second through hole structure is used for accommodating a second signal type probe;

and the conducting ring is arranged in the first through hole structure and is electrically connected with the signal transmission line, and the conducting ring is used for being electrically connected with the woven net layer of the coaxial cable.

Above-mentioned cable connection structure, through with conducting ring and woven stratum reticulare electric connection, and make conducting ring and the signal transmission line electric connection in the base plate, thereby make then the woven stratum reticulare of a coaxial cable can be connected with a plurality of second signal type probes adjacent simultaneously, a first signal type probe can match with a plurality of second signal type probes adjacent, and then in will returning the route and converting into a plurality of second signal type probes that encircle the sinle silk, so set up, can let return the route and keep continuity and integrality, improve return signal's integrality. In addition, the woven mesh does not need to be cut open and smoothed into a burr line group to be connected with the second signal type probe, and an air medium is not introduced into the medium layer, so that the problem of discontinuous signal impedance in the prior art is solved.

In one embodiment, the cable connection structure further includes:

and the insulating sleeve is arranged in the first through hole structure and is positioned on one axial side of the conducting ring.

In one embodiment, the conductive ring is connected to the first via structure in a manner including one or more of: welding, interference fit and clearance fit.

A probe block is used for being connected with a coaxial cable, the coaxial cable comprises a wire core, a dielectric layer, a woven net layer and an insulating layer which are sequentially stacked from inside to outside, and the probe block comprises:

an insulating base;

the substrate is arranged on the back surface of the insulating base, a first through hole structure, a second through hole structure and a signal transmission line are arranged in the substrate, the signal transmission line is used for connecting the first through hole structure and the second through hole structure, and the first through hole structure is used for allowing the wire core to penetrate through;

the first signal type probe penetrates through the front surface of the insulating base and is used for being connected with a wire core of a coaxial cable penetrating through the first through hole structure;

the second signal type probe penetrates through the front surface of the insulating base and is adjacent to the first signal type probe, the part of the second signal type probe penetrating through the insulating base penetrates through the second through hole structure, and the second signal type probe is electrically connected with the signal transmission line;

the conducting ring is arranged in the first through hole structure and electrically connected with the signal transmission line, and the conducting ring is used for allowing a wire core of the coaxial cable to penetrate through and electrically connected with a woven net layer of the coaxial cable.

The advantages of the probe block over the prior art are the same as the advantages of the cable connection structure over the prior art, and are not described herein again.

In one embodiment, each of the first signal type probes and each of the second signal type probes are arranged in an array, and when the first signal type probes are at edge positions, one of the first signal type probes is adjacent to two or three of the second signal type probes; when the first signal type probe is not in an edge position, one of the first signal type probes is adjacent to four of the second signal type probes.

In one embodiment, the substrate is a printed circuit board, and the second signal type probe is connected to the substrate through a portion of the second via structure by solder.

A signal expansion apparatus, the signal expansion apparatus comprising:

the coaxial cable comprises a wire core, a dielectric layer, a woven net layer and an insulating layer which are sequentially stacked from inside to outside;

the probe block comprises a substrate, an insulating base, a first signal type probe and a second signal type probe, wherein the substrate is arranged on the back of the insulating base, a first through hole structure, a second through hole structure and a signal transmission line are arranged in the substrate, and the signal transmission line is used for connecting the first through hole structure and the second through hole structure; the first signal type probe and the second signal type probe penetrate through the front surface of the insulating base, the first signal type probe is adjacent to the second signal type probe, and the first signal type probe is used for being connected with a wire core penetrating through the first through hole structure; the part of the second signal type probe penetrating out of the insulating base penetrates through the second through hole structure, and the second signal type probe is electrically connected with the signal transmission line;

and the conducting ring is positioned in the first through hole structure and is respectively and electrically connected with the woven net layer and the signal transmission line.

The advantages of the signal expansion device over the prior art are the same as the advantages of the cable connection structure over the prior art, and are not described herein again.

In one embodiment, the coaxial cable further includes a conductor cap, the conductor cap is sleeved on the exposed core, the conductor cap is electrically connected with the core, and the conductor cap is electrically connected with the inner wall of the needle sleeve of the first signal type probe.

In one embodiment, the conductive ring is sleeved on the woven mesh layer.

A semiconductor tester comprising a signal spreading device as described above.

The advantages of the semiconductor tester over the prior art are the same as the advantages of the signal expansion device over the prior art, and are not described herein again.

Drawings

FIG. 1 is a schematic diagram of a coaxial cable according to one embodiment;

FIG. 2 is a diagram illustrating a connection relationship between a coaxial cable and a probe block according to the prior art;

FIG. 3 is a graph showing the relationship between the position of a probe of a first signal type and a probe of a second signal type in the prior art;

FIG. 4 is a schematic structural view of a cable connection structure according to an embodiment;

FIG. 5 is a schematic structural view of a cable connection structure in another embodiment;

FIG. 6 is a schematic diagram of a coaxial cable and probe block connected by a cable connection structure in one embodiment;

FIG. 7 is a schematic diagram of the connection of coaxial cables to corresponding probes in one embodiment;

FIG. 8 is a graph illustrating the position of probes of a first signal type and a second signal type in one embodiment;

fig. 9 is a schematic view of a connection structure of a coaxial cable according to another embodiment.

Description of reference numerals:

1-coaxial cable, 11-wire core, 12-dielectric layer, 13-woven mesh layer, 14-insulating layer, 15-conductor cap, 2-probe block, 21-insulating base, 22-first signal type probe, 23-second signal type probe, 3-cable connection structure, 31-substrate, 311-first through hole structure, 312-second through hole structure, 313-signal transmission line, 32-conductive ring and 33-insulating sleeve.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application.

It will be understood that, as used herein, the terms "first," "second," and the like may be used herein to describe various elements, but these elements are not limited by these terms. These terms are only used to distinguish one element from another.

Spatial relational terms, such as "under," "below," "under," "over," and the like may be used herein to describe one element or feature's relationship to another element or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements or features described as "below" or "beneath" other elements or features would then be oriented "above" the other elements or features. Thus, the exemplary terms "under" and "under" can encompass both an orientation of above and below. In addition, the device may also include additional orientations (e.g., rotated 90 degrees or other orientations) and the spatial descriptors used herein interpreted accordingly.

It will be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element or be connected to the other element through intervening elements. In addition, the "connection" in the following embodiments is understood to be "electrical connection", "communication connection", or the like if there is a transfer of electrical signals or data between the connected objects.

As used herein, the singular forms "a", "an" and "the" may include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms "comprises/comprising," "includes" or "including," etc., specify the presence of stated features, integers, steps, operations, components, parts, or combinations thereof, but do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof. Also, as used in this specification, the term "and/or" includes any and all combinations of the associated listed items.

As in the background art, as shown in fig. 1, a coaxial cable includes a core 11, a dielectric layer 12, a braided mesh layer 13, and an insulating layer 14, which are sequentially stacked from the inside to the outside. In the prior art, as shown in fig. 2, when a coaxial cable is connected to a probe on a probe block 2, a wire core 11 is usually connected to a first signal type probe 22, a braided net is split and stroked into a burr group (the braided net cannot be split into a plurality of burr groups due to the brittle material of the braided net), and the burr group is connected to another adjacent second signal type probe 23.

The structure of the groups of burred lines of the woven mesh can only be connected to one second signal type probe 23, i.e. the first signal type probe 22 corresponding to the wire core 11 has only one corresponding second signal type probe 23 as a reference. Meanwhile, since the burr line group is obliquely connected to the second signal type probe 23, there is an air gap between the burr line group and the dielectric layer 12, so that the dielectric layer 12 introduces an air dielectric. Therefore, the above connection method also has a problem of discontinuous signal impedance, and the air medium existing in the return path causes abrupt impedance change. As shown in fig. 3, in the prior art, since the first signal type probe 22 only matches one corresponding second signal type probe 23, the first signal type probe 22 and the second signal type probe 23 are distributed in a 1 to 1 manner, where S represents the first signal type probe 22, and G represents the second signal type probe 23, for the first signal type probe 22 at the central position (circled part in fig. 3), a case where one S corresponds to three G also occurs, that is, the first signal type probe 22 at the non-edge position cannot guarantee that 1S always corresponds to four G. Since the impedance can be controlled well only by adopting the case of 4G around one S, the case of one S for three G is not favorable for controlling the impedance to be continuous. In the case where a plurality of coaxial cables 1 are connected simultaneously, for example, one of two adjacent coaxial cables 1 is a first cable and the other is a second cable, the first cable is connected to one first signal type probe 22 and one second signal type probe 23, respectively, the second cable adjacent to the first cable is also connected to one first signal type probe 22 and one second signal type probe 23, and the first signal type probe 22 connected to the first cable is also adjacent to the other second signal type probe 23 connected to the second cable. The first signal type probe 22 is used for transmitting signals as S-terminal signals, the second signal type probe 23 is used for transmitting signals as G-terminal signals, the S-terminal signals transmitted by the first cable can refer to the corresponding G-terminal signals and can also refer to the G-terminal signals transmitted by the second cable, but as the burr line group formed by the woven mesh used for transmitting the G-terminal signals of the second cable is only exposed in a small section, and the other parts of the burr line group are wrapped and shielded by the insulating layer 14, the first cable can break the return current signals after receiving a small part of the G-terminal signals due to the influence of the insulating layer 14. Then the signal at the S end transmitted by the first cable cannot completely refer to the signal at the G end transmitted by the second cable, and the signal at the S end transmitted by the first cable can actually refer to only one signal at the G end, so that the integrity of the returned signal is poor. In addition, because the G-end signal transmitted by the second cable cannot be completely referred to, even if one S corresponds to four G, the signal integrity still exists in the prior art. In addition, the impedance may suddenly change due to the existence of a part of the air medium in the return path, which affects the signal transmission process, and further degrades the integrity of the return signal.

In order to solve the above problem, as shown in fig. 4, the present application provides a cable connection structure 3, where the cable connection structure 3 is used to connect a coaxial cable 1 and a probe block 2, the probe block 2 includes a first signal type probe 22 and a second signal type probe 23, the cable connection structure 3 includes a substrate 31 and a conductive ring 32, the substrate 31 is internally provided with a first through hole structure 311, a second through hole structure 312 and a signal transmission line 313, the signal transmission line 313 is used to connect the first through hole structure 311 and the second through hole structure 312, the first through hole structure 311 is used to pass through a wire core 11 of the coaxial cable 1 to connect with the first signal type probe 22, and the second through hole structure 312 is used to accommodate the second signal type probe 23; the conductive ring 32 is disposed in the first through hole structure 311 and electrically connected to the signal transmission line 313, and the conductive ring 32 is used for electrically connecting to the woven mesh layer 13.

The substrate 31 may be a printed circuit board. The conductive ring 32 may be in the shape of a circular ring, a hollow polygon, a ring with a boss, or the like.

It can be understood that the conductive ring 32 is conductive as a whole, and the inner wall of the conductive ring 32 is in contact with the woven mesh layer 13, and the two are electrically connected when signal transmission is performed between the cable and the probe block 2. The woven mesh layer 13 is electrically connected with the signal transmission line 313 in the substrate 31 through the conductive ring 32, the second signal type probes 23 penetrate through the second through hole structure 312 and are electrically connected with the signal transmission line 313, and as the signal transmission line 313 is connected with each adjacent second signal type probe 23, the woven mesh layer 13 is connected with each adjacent second signal type probe 23, and the arrangement is such that one cable corresponds to a plurality of second signal type probes 23, the plurality of second signal type probes 23 return reference signals, and therefore the integrity of the signals is improved. In addition, in the above mode, the braided mesh layer 13 does not need to be cut open, and the braided mesh layer 13 in the cable can be kept complete, so that an air medium is not introduced into the medium layer 12, the problem of discontinuous signal impedance is avoided, abrupt impedance change is avoided, and the integrity of the transmission process of the return signal is further ensured.

In application, the first signal type probe 22 and the second signal type probe 23 are penetrated on the front surface of the insulating base 21, that is, the substrate 31 is connected to the rear surface of the probe block 2 when the coaxial cable 1 and the probe block 2 are connected by the cable connection structure 3 by penetrating the insulating base 21 from the front surface and being provided on the insulating base 21, and the second signal type probe 23 is inserted into the second via structure 312 to electrically connect with the signal transmission line 313, then the coaxial cable 1 is stripped off the insulating layer 14 to expose a small section of the woven mesh, then the woven mesh and the dielectric layer 12 are stripped to expose a small section of the wire core 11, the exposed wire core 11 is then connected to the first signal type probe 22 through the first via structure 311, when the wire core 11 is connected with the first signal type probe 22, the conductive ring 32 is electrically connected with the woven mesh layer 13, so that the woven mesh layer 13 of one coaxial cable 1 is connected to the adjacent second signal type probes 23 through the conductive ring 32. When the substrate 31 is connected to the back surface of the probe block 2, there is no gap between the substrate 31 and the probe block 2, so that the exposed wire core 11 is not exposed to the outside air.

The conductive ring 32 and the substrate 31 may be connected by a direct connection manner such as interference fit or clearance fit; the connecting structure can also adopt a conductive auxiliary connecting piece for indirect connection and can also adopt a welding mode for connection. It should be noted that the above-mentioned modes are only exemplary and do not limit the present embodiment, and other modes besides the above-mentioned modes can be adopted.

In the cable connection structure 3, the conductive ring 32 is electrically connected to the woven mesh layer 13, and the conductive ring 32 is electrically connected to the signal transmission line 313 in the substrate 31, so that the woven mesh layer 13 of one coaxial cable 1 can be simultaneously connected to the adjacent second signal type probes 23, one first signal type probe 22 can be matched with the adjacent second signal type probes 23, and the return path is converted into the second signal type probes 23 surrounding the core 11. In addition, the woven mesh does not need to be cut open and divided into burr line groups to be connected with the second signal type probe 23, and an air medium is not introduced into the medium layer 12, so that the problem of discontinuous signal impedance in the prior art is solved.

In one embodiment, as shown in fig. 5, the cable connection structure 3 further includes an insulating sleeve 33, and the insulating sleeve 33 is disposed in the first through hole structure 311 and located at one axial side of the conductive ring 32.

It can be understood that when the conductive ring 32 is sleeved on the exposed woven mesh layer 13, the conductive ring 32 may contact with the core 11, and when the conductive ring 32 contacts with the core 11, the woven mesh layer 13 is electrically connected to the core 11, and a short circuit occurs between the signal line and the signal ground.

Specifically, as shown in fig. 6 and 7, the insulating sleeve 33 is disposed in the first through hole structure 311 and located at one axial side of the conductive ring 32, and when the coaxial cable 1 and the probe block 2 are connected by the cable connection structure 3, the exposed core 11 of the cable penetrates the first through hole structure 311 from a side close to the conductive ring 32, and sequentially penetrates the conductive ring 32 and the insulating sleeve 33 to be connected with the first signal type probe 22. At this time, the insulating sleeve 33 is located on a side of the grounding ring close to the exposed core 11, and the insulating sleeve 33 is located between the core 11 and the conductive ring 32 to separate the core 11 from the conductive ring 32, so as to avoid electrical connection between the woven mesh layer 13 and the core 11.

In this embodiment, the insulation sleeve 33 is disposed in the first through hole structure 311 and located on one side of the conductive ring 32, so that the core 11 and the conductive ring 32 can be separated by the insulation sleeve 33, the woven mesh layer 13 and the core 11 are prevented from being electrically connected, and the signal line and the signal ground are prevented from being shorted.

In one embodiment, as shown in fig. 6, the present application further provides a probe block 2 for connecting with a coaxial cable 1, the coaxial cable 1 includes a wire core 11, a dielectric layer 12, a braided mesh layer 13 and an insulating layer 14, which are sequentially stacked from inside to outside, and the probe block 2 includes: an insulating base 21, a substrate 31, first and second signal type probes 22 and 23, and a conductive ring 32. The substrate 31 is arranged on the back surface of the insulating base 21, a first through hole structure 311, a second through hole structure 312 and a signal transmission line 313 are arranged in the substrate, the signal transmission line 313 is used for connecting the first through hole structure 311 and the second through hole structure 312, and the first through hole structure 311 is used for the wire core 11 to pass through; the first signal type probe 22 penetrates through the front surface of the insulating base 21 and is used for being connected with the wire core 11 of the coaxial cable 1 penetrating through the first through hole structure 311; the second signal type probe 23 penetrates through the front surface of the insulating base 21 and is adjacent to the first signal type probe 22, a part of the second signal type probe 23 penetrating out of the insulating base 21 penetrates through the second through hole structure 312, and the second signal type probe 23 is electrically connected with the signal transmission line 313; the conductive ring 32 is disposed in the first through hole structure 311 and electrically connected to the signal transmission line 313, and the conductive ring 32 is used for the core 11 of the coaxial cable 1 to pass through and electrically connected to the braided mesh layer 13 of the coaxial cable 1.

The insulating base 21 is made of an insulating material at least in a partial region, so that when the first signal type probe 22 and the second signal type probe 23 are disposed on the insulating base 21, the first signal type probe 22 and the second signal type probe 23 are not electrically connected only through the insulating base 21. The first via structure 311 and the second via structure 312 may be metalized holes, that is, the hole walls of the first via structure 311 and the second via structure 312 are plated with a conductive metal layer, so that the conductive ring 32 is electrically connected to the signal transmission line 313, and the second signal type probe 23 is electrically connected to the signal transmission line 313.

In this embodiment, with the above arrangement, only the exposed core 11 of the coaxial cable 1 is connected to the first signal type probe 22 through the first through hole structure 311, the exposed braided mesh layer 13 of the coaxial cable 1 is abutted against the conductive ring 32, so that the conductive ring 32 is electrically connected with the braided mesh layer 13, since the conductive ring 32 is electrically connected to the signal transmission line 313 in the substrate 31, the signal transmission line 313 is connected to the second signal type probe 23, the woven mesh layer 13 of one coaxial cable 1 can be simultaneously connected with the adjacent second signal type probes 23, so that the first signal-type probes 22 are matched with the adjacent plurality of second signal-type probes 23, thereby converting the return path into a plurality of second signal type probes 23 surrounding the core 11, by the arrangement, the continuity and the integrity of the return path can be maintained, and the integrity of the return signal is improved. In addition, the woven mesh does not need to be cut open and divided into burr line groups to be connected with the second signal type probe 23, and an air medium is not introduced into the medium layer 12, so that the problem of discontinuous signal impedance in the prior art is solved.

In one embodiment, as shown in fig. 8, each of the first signal type probes 22 and each of the second signal type probes 23 are arranged in an array, and when the first signal type probes 22 are at edge positions, one first signal type probe 22 is adjacent to two or three second signal type probes 23; when the first signal type probe 22 is not in the edge position, one first signal type probe 22 is adjacent to four second signal type probes 23.

In addition to the cross arrangement shown in fig. 8, the first signal type probe 22 and the second signal type probe 23 may be arranged in an X-shape, the midpoint position is S, and the four points on the edge are G, so that one first signal type probe 22 and four second signal type probes 23 are adjacent to each other. And may even be arranged in a "meter" fashion, one first signal-type probe 22 may be adjacent to more second signal-type probes 23. In the present application, the arrangement of the first signal type probe 22 and the second signal type probe 23 is not limited to the above-described exemplary manner, and may be other manners, and only one first signal type probe 22 may be adjacent to a plurality of second signal type probes 23.

It is understood that the first signal-type probes 22 and the second signal-type probes 23 are arranged in an array. When the first signal type probe 22 is in both the edge row and the edge column, there is only one adjacent second signal type probe 23 in both the row direction and the column direction, one first signal type probe 22 being adjacent to two second signal type probes 23; when the first signal type probe 22 is in an edge row but not in an edge column, there are two adjacent second signal type probes 23 in the row direction, only one adjacent second signal type probe 23 in the column direction, and one first signal type probe 22 is adjacent to three second signal type probes 23; likewise, when the first signal type probe 22 is in an edge column and not in an edge row, there are two adjacent second signal type probes 23 in the column direction, and only one adjacent second signal type probe 23 in the row direction, one first signal type probe 22 being adjacent to three second signal type probes 23; when the first signal type probe 22 is not located at the edge position, two adjacent second signal type probes 23 exist in one first signal type probe 22 in both the row direction and the column direction, and one first signal type probe 22 is adjacent to four second signal type probes 23. As shown in fig. 8, the first signal type probe 22 at the center position is inevitably matched with four adjacent second signal type probes 23, but the problem that the first signal type probe 22 at the center position is only matched with three adjacent second signal type probes 23 in fig. 3 does not occur, so that the first signal type probe 22 at the center position is matched with four adjacent second signal type probes 23, the continuity and the integrity of a return path can be maintained, and the signal integrity is improved.

In this embodiment, each first signal type probe 22 and each second signal type probe 23 are arranged in an array, so that one first signal type probe 22 is adjacent to at least two second signal type probes 23, so that one first signal type probe 22 is matched with at least two adjacent second signal type probes 23, and the number of second signal type probes 23 included in the return path is large, thereby ensuring the integrity of the return signal.

In one embodiment, the portion of the second signal type probe 23 passing through the second via structure 312 is connected with the substrate 31 by solder.

The substrate 31 may be a printed circuit board, among others.

In this embodiment, the second signal type probe 23 is welded to the substrate 31 by passing through the second through hole structure 312, so that the second signal type probe 23 is prevented from shaking relative to the insulating base 21, and the second signal type probe 23 is stably connected to the signal transmission line 313.

In one embodiment, as shown in fig. 6, the present application further provides a signal spreading device, including: coaxial cable 1, probe block 2 and conductive ring 32. The coaxial cable 1 includes a core 11, a dielectric layer 12, a braided mesh layer 13, and an insulating layer 14, which are stacked in this order from the inside to the outside. The probe block 2 comprises a substrate 31, an insulating base 21, a first signal type probe 22 and a second signal type probe 23, wherein the substrate 31 is arranged on the back surface of the insulating base 21, a first through hole structure 311, a second through hole structure 312 and a signal transmission line 313 are arranged in the substrate 31, and the signal transmission line 313 is used for connecting the first through hole structure 311 and the second through hole structure 312; the first signal type probe 22 and the second signal type probe 23 penetrate through the front surface of the insulating base 21, the first signal type probe 22 is adjacent to the second signal type probe 23, and the first signal type probe 22 is used for being connected with the wire core 11 penetrating through the first through hole structure 311; the portion of the second signal type probe 23 penetrating the insulating base 21 passes through the second via structure 312, and the second signal type probe 23 is electrically connected to the signal transmission line 313. The conductive ring 32 is located in the first through hole structure 311, and is electrically connected to the woven mesh layer 13 and the signal transmission line 313, respectively.

The conductive ring 32 may be directly sleeved on the woven mesh layer 13, or may be abutted against or welded to the surface of the woven mesh layer 13 through an end surface.

In this embodiment, the conductive ring 32 is electrically connected to the woven mesh layer 13, and the conductive ring 32 is electrically connected to the signal transmission line 313 in the substrate 31, so that the woven mesh layer 13 of one coaxial cable 1 can be simultaneously connected to the adjacent second signal type probes 23, one first signal type probe 22 can be matched with the adjacent second signal type probes 23, and the return path is converted into the second signal type probes 23 surrounding the core 11. In addition, the woven mesh does not need to be cut open and divided into burr line groups to be connected with the second signal type probe 23, and an air medium is not introduced into the medium layer 12, so that the problem of discontinuous signal impedance in the prior art is solved.

In one embodiment, the coaxial cable 1 further includes a conductor cap 15, the conductor cap 15 is disposed on the exposed core 11, the conductor cap 15 is electrically connected to the core 11, and the conductor cap 15 is electrically connected to an inner wall of the sleeve of the first signal type probe 22.

As shown in fig. 9, specifically, the wire core 11 penetrating through the grounding ring and the insulating sleeve 33 is connected with the bullet-shaped conductor cap 15 shown in fig. 9, and is finally pressed into the probe sleeve of the first signal type probe 22 at the corresponding position through the corresponding fixture, and the outer wall of the bullet-shaped conductor cap 15 is connected with the inner wall of the needle sleeve of the first signal type in an interference fit manner.

Wherein, sinle silk 11 is yielding, directly is connected sinle silk 11 and first signal type probe 22, is difficult to guarantee connection stability, consequently, through conductor cap 15 auxiliary connection.

The wire core 11 and the conductor cap 15 can be connected in a welding connection mode, can also be connected in an interference fit connection mode, and can also be indirectly connected through an auxiliary conductor piece. In addition to the above-described connection, other ways, such as snap-in, are also possible.

In application, the connection process of the cable of the signal expansion device and the probe block 2 is as follows: firstly, the second signal type probe 23 passes through the second through hole structure 312 of the substrate 31, so that the second signal type probe 23 is electrically connected with the signal transmission line 313 inside the substrate 31, and the substrate 31 is fixed on the probe block 2; then stripping the insulating layer 14 at the end part of the cable to expose the braided net layer 13; stripping off part of the exposed woven mesh layer 13 to expose the dielectric layer 12; part of the exposed dielectric layer 12 is stripped to expose the wire core 11. Then, the conductive ring 32 is sleeved on the exposed braided mesh layer 13 of the cable, and after the conductive ring 32 is sleeved on the braided mesh layer 13, the insulating sleeve 33 is sleeved on the exposed dielectric layer 12 of the cable to isolate the conductive ring 32 from the cable core 11. After the conductive ring 32 and the insulating sleeve 33 are sleeved on the cable, the conductor cap 15 is sleeved on the exposed core 11, the conductor cap 15 is connected to the first signal type probe 22 through the first through hole structure 311, and in the process, the insulating sleeve 33 and the conductive ring 32 are inserted into the first through hole structure 311 of the substrate 31, so that the conductive ring 32 is electrically connected to the signal transmission line 313. Finally, solder covering the second via structure 312 is formed on a surface of the substrate 31 on a side away from the probe block 2 to fix the second signal type probe 23 passing through the second via structure 312.

In one embodiment, the present application also provides a semiconductor tester including a signal spreading device as described above.

The advantages of the semiconductor tester over the prior art are the same as the advantages of the signal extension apparatus over the prior art, and are not described herein again.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present application shall be subject to the appended claims.

Claims (10)

1. A cable connection structure for connecting a coaxial cable and a probe block, the probe block including a first signal type probe and a second signal type probe, the cable connection structure comprising:

the coaxial cable comprises a substrate, a first through hole structure, a second through hole structure and a signal transmission line are arranged in the substrate, the signal transmission line is used for connecting the first through hole structure and the second through hole structure, the first through hole structure is used for enabling a wire core of the coaxial cable to penetrate through so as to be connected with a first signal type probe, and the second through hole structure is used for accommodating a second signal type probe;

the conducting ring is arranged in the first through hole structure and is electrically connected with the signal transmission line, and the conducting ring is used for being electrically connected with the woven net layer of the coaxial cable.

2. The cable connection structure according to claim 1, further comprising:

and the insulating sleeve is arranged in the first through hole structure and is positioned on one axial side of the conducting ring.

3. The cable connection according to claim 1, wherein the conductive ring is connected to the first via structure in a manner comprising one or more of: welding, interference fit and clearance fit.

4. A probe block, for connecting with a coaxial cable, the coaxial cable including a wire core, a dielectric layer, a woven mesh layer and an insulating layer stacked in sequence from inside to outside, the probe block comprising:

an insulating base;

the substrate is arranged on the back surface of the insulating base, a first through hole structure, a second through hole structure and a signal transmission line are arranged in the substrate, the signal transmission line is used for connecting the first through hole structure and the second through hole structure, and the first through hole structure is used for the wire core to penetrate through;

the first signal type probe penetrates through the front surface of the insulating base and is used for being connected with a wire core of a coaxial cable penetrating through the first through hole structure;

the second signal type probe penetrates through the front surface of the insulating base and is adjacent to the first signal type probe, the part of the second signal type probe penetrating out of the insulating base penetrates through the second through hole structure, and the second signal type probe is electrically connected with the signal transmission line;

the conducting ring is arranged in the first through hole structure and electrically connected with the signal transmission line, and the conducting ring is used for allowing a wire core of the coaxial cable to penetrate through and electrically connected with a woven net layer of the coaxial cable.

5. The probe block of claim 4, wherein each of the first signal type probes and each of the second signal type probes are arranged in an array, one of the first signal type probes being adjacent to two or three of the second signal type probes when the first signal type probe is in an edge position; when the first signal type probe is not in an edge position, one of the first signal type probes is adjacent to four of the second signal type probes.

6. The probe tile of claim 4, wherein the substrate is a printed circuit board and the second signal type probe is connected to the printed circuit board by solder through a portion of the second via structure.

7. A signal expansion apparatus, characterized in that the signal expansion apparatus comprises:

the coaxial cable comprises a wire core, a dielectric layer, a woven net layer and an insulating layer which are sequentially stacked from inside to outside;

the probe block comprises a substrate, an insulating base, a first signal type probe and a second signal type probe, wherein the substrate is arranged on the back of the insulating base, a first through hole structure, a second through hole structure and a signal transmission line are arranged in the substrate, and the signal transmission line is used for connecting the first through hole structure and the second through hole structure; the first signal type probe and the second signal type probe penetrate through the front surface of the insulating base, the first signal type probe is adjacent to the second signal type probe, and the first signal type probe is used for being connected with a wire core penetrating through the first through hole structure; the part of the second signal type probe penetrating out of the insulating base penetrates through the second through hole structure, and the second signal type probe is electrically connected with the signal transmission line;

and the conducting ring is positioned in the first through hole structure and is respectively and electrically connected with the woven net layer and the signal transmission line.

8. The signal extension device of claim 7, wherein the coaxial cable further comprises a conductor cap, the conductor cap is sleeved on the exposed core, the conductor cap is electrically connected with the core, and the conductor cap is electrically connected with an inner wall of the needle sleeve of the first signal type probe.

9. The signal extension device of claim 7, wherein the conductive ring is sleeved on the woven mesh layer.

10. A semiconductor tester comprising the signal expansion apparatus of any one of claims 7 to 9.

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