WO2018166737A1 - Test socket and contacting device for contacting a high frequency signal - Google Patents

Abstract

The invention relates to a test socket having a plurality of contact elements, each for contacting an electrical signal or an electrical potential, and having at least one contacting device for contacting a high frequency signal each. The plurality of contact elements are each arranged in a first grid. Within the first grid, at least one adjacent contact element in each of the two arrangement directions, which are orthogonal relative to each other, of the first grid are replaced by each contacting device. Each contacting device extends along the axial extension of the contact elements, parallel to the contact elements. The at least one contacting device (4; 4₁'; 4₂'; 4' '; 4' ' ') is different from each contact element (3) in each case.

Description

 Test socket and contacting device for contacting a high-frequency signal

FIELD OF THE INVENTION

The present invention relates to a test socket with a plurality of contact elements for contacting each of an electrical signal or each one

electrical potential and at least one contacting device for contacting each one

High frequency signal.

BACKGROUND ART In order to test an integrated circuit having a plurality of in each case arranged in egg ^¬ nem grid contact surfaces, a test socket having a plurality of arranged in the same grid contact elements is required. When the contact elements han ^¬ delt it is through-contact, ie Kontak- sliding elements, of the contact plane with the Kontaktflä ^¬ surfaces of the test integrated circuit over the adjacent to the contact plane surface of the test socket to the ge ^¬ genüberliegende surface of the test socket and is extend over the opposite face against ^¬ addition of the test socket. The contact elements are in particular pin-shaped Kontaktele ^¬ elements, ie contact pins. Instead of an integrated one

Circuit is also a circuit board with electronics or je ^¬ de other expression of an electronic module with electronic contact surfaces covered. The integrated circuit is typically inserted into the test socket so that a contacting end of one contact ^element reliably electrically contacts an associated contact surface of the integrated circuit. The other end of each con ^¬ tact element is in each case connected via a so-called loadboard (German: charging plate) with a measuring device. Respectively to measure the individual contact surfaces of the test inte ^¬ grated circuit only a DC ^stabilized or low-frequency signal, then for the contacting of only usually a pin sufficient. However, are high-frequency signals to be measured at the individual contact ^¬ surfaces of the integrated circuit, a contact is required, which is adapted to the radio frequency physics of the measured high-frequency signal.

US Pat. No. 7,173,442 B2 discloses a test device for testing integrated circuits with which DC voltage and / or low-frequency signals and high-frequency signals can be contacted in parallel at individual contact surfaces of the integrated circuit. For contacting the

High frequency signals are each a coplanar Streifenlei ^¬ tion used. The coplanar strip line extends in egg ^¬ ner plane parallel to the contact plane of the test inte grated circuit ^¬. Since a coplanar strip line has a certain extent in the plane, which is typically greater than the pitch of the individual contact surfaces, such a coplanar strip line can be disadvantageously contacted only high-frequency signals at the edges of the grid.

This is a condition to be improved.

SUMMARY OF THE INVENTION Against this background, the object of the present invention is to provide a test socket with which not only DC voltage signals but also high-frequency signals can be contacted at any contact surface of the integrated circuit to be tested. According to the invention this object is tierungsvorrichtung by a test socket having the features of patent claim 1, by a Kontak- with the features of claim 18 and by a method for fabricating a contact-making device having the features of claim ge solves ^¬ 29th

Accordingly, there is provided: - a test socket having a plurality of contact elements for contacting a respective electrical signal or by a respective electric potential and Minim ^¬ least one contacting device for contacting a respective high-frequency signal, wherein the plurality of contact elements angeord respectively in a first grid ^¬ are net and within the first grid through each contacting at least a Benach ^¬ bartes contact element in each of the two to one another or ^¬ thogonalen arrangement directions of the first raster re- placed, wherein each contacting device along the axial extent of the contact elements extends parallel to the contact elements, wherein the at least one contacting device is in each case different from each ^¬ the contact ^element ,

- a contacting device for contacting each ^¬ weils a high frequency signal having an outer sleeve, guided in the outer sleeve in the axial direction of the inner sleeve, a spring that is positioned between the inner sleeve and a radially directed on the outer sleeve to the inside web, one with the

electrically conductive inner sleeve connected Außenlei ^¬ ter a high-frequency cable, a contact with a innenlei ^¬ ter of the high-frequency cable connected inner conductor contact side contact element and at least an outer conductor contact side arranged contact element and with the inner sleeve

- a process for preparing a Kontaktierungsvor- direction for contacting a respective Hochfre ^¬-frequency signal comprising the steps of: inserting a spring and an inner sleeve of the contact-making device which is connected to an outer conductor of a Hochfre ^¬ frequency cable, in an outer sleeve of Kon - timing device; Connecting an inner conductor contact side arranged contact element with an inner ^¬ conductor of the high-frequency cable; Connecting at least one outer conductor contact side arranged Kontaktele ^¬ ment with an inner sleeve of Kontaktierungsvorrich- device and shaping a directed to the contact plane axial boundary of the outer sleeve of the contacting ^¬ device.

The of the present invention is based insights nis / idea is to provide a contacting device for contacting a Hochfre ^¬ quenzsignals, which is arranged parallel to the axial extension of the individual arranged in a Ras ^¬ ter contact elements, each of which is preferably a DC or Low frequency signal is contacted. In this way, a Hochfre ^¬ frequency signal can be contacted not only at the edges of the grid, but also in the interior of the grid. Clocking of the con- of the RF signal is thus dependent to replace only a certain number of adjacent Kontak ^¬ tele elements from realized miniaturization of Kontaktierungsvor- direction. Additional contact members are located between the actual contact area of the high-frequency signal within the grid and the next ge ^¬ superior edge of the grid, thus wetting must in delimi- to a plane parallel to the plane of contact arrange- Advantageously, the contacting device is not replaced and thus sacrificed.

The number of adjacent contact elements is formed by a contacting device within the grid, which is hereinafter referred to as the first grid, he ^¬ sets, obtained as a function of the realized miniaturization and the type of contact, such as coaxial contacting or differentiel- le or Twinax contacting.

Advantageous embodiments and developments emerge from the further subclaims and from the loading ^¬ scription with reference to the figures of the drawing.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination indicated, but also in other combinations or in isolation, without departing from the scope of the present invention.

In the case of an unbalanced high-frequency signal (eng ^¬ lisch: single-ended signal) is the Kontak- invention tierungsvorrichtung coaxially carried out, and thus has a sleeve-like shape with respect to a minimized volume. This sleeve-shaped contacting device has egg ^¬ ne outer sleeve which is fixed in the contacting region of the high-frequency signal to be contacted in the test socket according to the invention. In the outer sleeve, an inner sleeve is guided in the axial direction. Between the inner

Sleeve and a radially inwardly directed web of äuße ^¬ ren sleeve is a spring positioned elastically supports the inner sleeve in the outer sleeve in the axial direction. The contacting ^device according to the invention is thus embodied such that it is exchangeable from the test socket according to the invention. The inner sleeve is axially movable over the outer sleeve out through a first implementation, given in a ^¬ to test the integrated circuit end surface of the äuße ^¬ ren sleeve is arranged. The movement of the inner sleeve is limited in the direction of the test integrated circuit by the interaction of a radially outwardly directed web of the inner sleeve and a radially inward boundary of the outer sleeve, the first limited by ^¬ management. An outer conductor of a contacting device with the ver ^¬-bound high frequency cable is electrically and mechanically connected to the inner sleeve. In each case at least one inner conductor of the high-frequency cable is connected to an associated inner conductor contact side arranged contact element of the inventive contacting device. Minim ^¬ least an outer conductor contact side arranged Kontaktele ^¬ ment is verbun with the electrically conductive inner sleeve ^¬. Under the inner-conductor-contact side and außenleiterkon- clock-sided contact element and is understood to mean a contact element in the following, which with the associated inner conductor contact surface and the associated outer conductor contact surface of the detected high-frequency signal on the integrated circuit ^¬ is advantage in the direction of the contacting of orien.

In this way a contacting reali ^¬ Siert contacting at a under test integrated circuit belonging to a high-frequency signal to be measured ^¬ inner conductor and outer conductor contact surfaces and the associated inner conductor and outer conductor is a potential off supplying high-frequency cables. The elastic guide the inner sleeve in the outer sleeve of the contacting device allows a variable distance between the inner conductor and outer conductor contact surfaces of on the integrated circuit to be measured high-frequency signal and the associated contacting the test socket from ^¬ zugleichen.

As the high frequency cable is connected to the elastically table guided in the outer sleeve inner sleeve, the high ^¬ frequency cable in accordance with the respective spacing of the Kon ^¬ clock-plane is mounted to the outer sleeve of the contacting device within the outer sleeve movable and follows so ^¬ with the movement of contact level. In this context, the term "contact plane" refers to the plane in which the contact between the inner conductor and outer conductor contact side contact elements of the contacting device and the inner conductor or outer conductor contact surfaces of the high-frequency signal to be measured on the integrated circuit takes place.

In addition, in such invention exporting ^¬ tion of contacting the high-frequency cable, in particular the inner conductor of the high-frequency cable, liehst possible close to the contact elements and thus guided to the contact ^¬ level. Finally, the number of Übergän ^¬ gene is minimized to the high frequency signal path between the under test integrated circuit and the high-frequency cable, thus improving the impedance matching at the high frequency signal path.

Preferably, a plurality of outer conductor contact side Kontaktele ^¬ elements are provided, which are designed to be elastic. In this way, distance differences between individual surface areas of the associated outer conductor contact surface can occur the integrated circuit and the individual outer conductor contact side contact elements are compensated.

The elastic contact elements are realized in particular as contact elements with spring arms. In this way, read ^¬ is resilient contact members sen with a very low expansion and thus a contacting the con- clocking of a high frequency signal in a miniaturized ^¬ th execution realized. As a manufacturing technology for such contact elements with spring arm is offered in ^¬ example, the so-called lithographic electroplating (LIGA) process.

If a plurality of outer conductor contact-side contact elements are seen upstream, these are, in a preferred execution ^¬ form in the same grid as the contact elements, that is, arranged in ers ^¬ th raster in the inventive test socket. The individual contact elements for contacting each egg ^¬ nem electrical signal or each of an electrical potential are preferably also realized as elastic Federkon ^¬ contact pins.

The inner conductor contact-side contact element is executed in a first embodiment of the contacting device according to the invention as an elastic contact element, in particular as a contact element with spring arm. In a second embodiment of the present invention Kontaktierungsvorrich ^¬ tung the inner-conductor-contact-side contact member is implemented as a rigid contact element. Differences in distance be- seen, the inner conductor contact surface and the Außenleiterkon- clock-face of the measured high-frequency signal on the tegrated in ^¬ circuit and the inner conductor or outer conductor ^¬ contact-side contact elements are of reasonable by the cooperation ^¬ play of elasticity within the outer sleeve arranged spring and the elasticity of the outer conductor contact side elastic spring elements balanced.

A third embodiment of a Kontak- invention is realized by a single-sided contact element außenleiterkon- clock tierungsvorrichtung, the approach direction in Kontaktie- has a cylindrical inner bore and a Elas ^¬ ticity. The single contact-side contact element on the contact side is preferably annular in shape.

In a fourth embodiment of a contacting device according to the invention the contacting device according to the invention has two inner-conductor-contact side Contacts- ELEMENTS on for detecting a differential Hochfrequenzsig ^¬ nal on the under test integrated circuit. These two inner conductor contact-side contact elements are each connected to an associated inner conductor of the high-frequency cable (so-called Twinax high-frequency cable or differential high-frequency cable).

In view of the best possible miniaturization of the contacting device is the high frequency cable as a so-called ^¬ micro-coaxial cables, that is realized as a coaxial cable with egg nem compared to conventional coaxial cables clearly ge ^¬ ringeren outer diameter. Thus, the diameter of the inner and outer sleeve blank Kontaktie- reasoning apparatus and thus minimize the radial extent of Kon ^¬ taktierungsvorrichtung significantly. The space required in the inventive test socket for such of miniaturization ^¬ catalyzed contacting device, ie the number of be ^¬ neighboring contact pins that are to be replaced by the miniaturized he ^¬-making proper contact device is therefore advantageously minimized. In a first variant of an external Hochfrequenzan ^¬ circuit for the inventive contacting device the high frequency cable is guided via a second passage in the outer sleeve from the contacting hinaus- and directly or indirectly connected to a high-frequency measuring ^¬ device. This second implementation is preferably provided on the contact plane opposite end face of the Kon ^¬ taktierungsvorrichtung, ie on the side facing away from the test ^¬ integrated circuit th, and limited by the provided on the outer sleeve and radially inwardly court ^¬ teten web.

In a second variant of an external Hochfrequenzan ^¬ circuit for the contact- ^{making device} according to the invention the contacting ^device according to the invention is formed at its opposite end of the contact plane as a coupling unit for receiving a connector. This plug ^¬ connector can be connected to an end of another Hochfrequenzka ^¬ bels, it is advised directly or indirectly connected with a Hochfrequenzmessge- be secured. Alternatively, this connector can also be attached to an assembly, preferably on a printed circuit board, which contacts the individual Kontaktele ^¬ elements and the individual Kontaktierungsvor- invention of the test socket according to the invention. Between the spring and the coupling unit of the contacting device there is for this purpose a radially inwardly directed web of the outer sleeve, which is a second one

Making passage for the high frequency cable. The Hochfre ^¬ quenzkabel extends within the coupling unit through a fraction of the longitudinal extent of the Kopplungsein ^¬ unit.

In a third variant of an external Hochfrequenzan ^¬ circuit for the contacting ^device according to the invention, the contacting between the in the erfindungsge- proper contacting high-frequency cable and a connector outside the contacting device according to the invention. For this purpose, in the invention ^shown SEN test socket is a board, preferably a printed circuit board, inte grated ^¬ for contacting the individual contact elements and a ^¬ individual contact devices according to the invention. Within this module is in alignment with the

Longitudinal extension of the Kontaktierungsvor ^¬ invention provided direction as a coupling unit for the connector through hole. Mentioned in the OF INVENTION ^¬ to the invention contacting Hochfre ^¬ quenzkabel is serving a as a bushing and ra ^¬ dial inwardly web of the outer sleeve on the end ^¬ end of the invention Kontaktierungsvorrich ^¬ tung ge ^¬ leads into the associated through hole of the module and extends over a fraction of the Längser ^¬ stretching of the bore.

In a first sub-variant of Kontak- tierungsvorrichtung the invention, the inner conductor of the Hochfrequenzka ^¬ bels over the front end of the high-frequency cable projects out towards ^¬ and is positively or non-positively to the resilient or rigid inner-conductor-contact-side contact member ver ^¬ prevented.

In a second sub-variant of the invention Kontak- tierungsvorrichtung the inner conductor of the high-frequency cable with respect to the insulator of the high frequency cable is axially shortened at the front end of the Hochfre ^¬ frequency cable. The nenleiterkontaktseitige in ^¬ contact element is in this case firmly fixed to the insulator of the high-frequency cable and to the extent hineinge ^¬ advanced together with the inner conductor in the high frequency cable that only an upper portion of the inside ^¬ conductor contact-side contact member from the high-frequency ^¬ cable protrudes. For fixing the inner conductor contact side gene contact element in the insulator of the high-frequency cable, the inner conductor contact side contact element has at least one radially inwardly directed groove, preferably a plurality of radially inwardly directed grooves on. These grooves form together ^¬ men with the thermally foamed in the manufacture of insulator material that enter the grooves, an axial connection.

To produce such Kontak- device according to the invention, the spring and the inner sleeve are inserted into the outer sleeve. A high frequency cable is inserted into the inner sleeve via a passage in the outer sleeve and the outer conductor of the high frequency cable is connected to the inner sleeve. Subsequently, the at least one inner-conductor-contact-side contact member with the supplied ^¬ impaired inner conductor of the high-frequency cable and the Minim ^¬ least connected to an outer conductor contact-side contact member with the inner sleeve. Finally directed to the contact plane ^¬ axial boundary of the outer sleeve is formed ^¬.

In the first sub-variant of the invention Kontak- tierungsvorrichtung the inner conductor of Hochfrequenzka ^¬ bels is pushed at the front end of the high-frequency cable axially from the high-frequency cable, before the inner conductor is connected to the inner-conductor-contact-side contact member.

In the second sub-variant of Kontak- invention tierungsvorrichtung the inner conductor connected to the innenleiterkontaktsei ^¬-stage contact member is pushed back into the high frequency cable with heating of the front end of the high-frequency cable, protrudes to only the tip of the inner-conductor-contact-side contact member of the front end of the high frequency cable. The Heating serves for easier insertion of the inner conductor connected to the inner conductor contact side contact element into the high frequency cable and for foaming the insulator material of the high frequency cable. The foamed insulator material penetrates into the inner conductor contact side

Contact element provided grooves and thus fixes the ^¬ nenleiterkontaktseitige contact element in the high-frequency cable. After cooling phase is present an axially fixed Verbin ^¬ connection between the inner conductor contact-side contact member and the insulator at the front end of the Hochfrequenzsig ^¬ Nals.

In a preferred extension of the test socket according to the invention in the test socket ^¬ a module is integrated, which is connected to those contact ends of the contact elements which are located on the integrated circuit to be tested abge ^¬ facing side. For contacting with the contacts ^¬ the contact ^elements , this assembly has associated first contact points, which are arranged in the same grid spacing as the first grid of the individual contact elements. Within the assembly is an implementation of this first contact points in corresponding second contact points which are angeord ^¬ net in a second grid with a grid spacing which is greater than the grid spacing of the first Ras-ester is effected. In this way, each contacted by the single ^¬ NEN contact elements DC ^¬ and low frequency signals to the associated second Kon ^¬ cyclically make the assembly easier to by a further construction ^¬ group, for example, a load board, or a bundle of cables contact.

Typically, the second contact point against the first contact points are arranged offset so that the abge ^¬ rising high-frequency cable and the outgoing of radiofrequency can be dissipated with the use of a very space ^¬ filling the bend parallel to the test socket.

The above embodiments and developments can, if appropriate, combine with each other as desired. Further possible refinements, developments and imple ^¬ conclusions of the invention also include not explicitly mentioned combinations of previously or below with respect to the off ^¬ exemplary embodiments described features of the invention. In particular, the expert is also individual aspects as

Add improvements or additions to the respective basic form of the present invention.

CONTENT OF THE DRAWING

The present invention will be explained in more detail with reference to the execution ^¬ examples given in the schematic figures of the drawing. These show: Figure 1A is a three dimensional representation of an OF INVENTION ^¬ to the invention the test socket having a first exporting ^¬ approximate shape of a contact-making device of the invention for one high-frequency signal, Figure 1B is a three dimensional representation of an OF INVENTION ^¬ to the invention the test receptacle with a second exporting ^¬ approximate shape of a present invention.. contact-making device for each of a high frequency signal, Fig. IC is a three dimensional representation of an oF iNVENTION ^¬ to the invention the test receptacle with a third exporting ^¬ approximate shape of a contact-making device according to the invention for one high-frequency signal, Fig. 1D is a three dimensional representation of an OF INVENTION ^¬ to the invention the test receptacle with a fourth exporting ^¬ approximate shape of a contact-making device according to the invention for one high-frequency signal,

Fig. 2A is a cross-sectional view of a first exporting ^¬ approximate shape of a contact-making device according to the invention for one high-frequency signal in an inventive test socket,

2B is a cross-sectional view of a first Unterva ^¬ variant of a second embodiment of a Kontak- tierungsvorrichtung for a differential high-frequency ^¬ signal in a test ood according to the invention,

2C is a cross-sectional view of a second sub ^¬ variant of a second embodiment of a Kon ^¬ taktierungsvorrichtung for a high-frequency signal in a test socket according to the invention,

FIG. 2D is a cross-sectional view of a third exporting ^¬ approximate shape of an inventive Kontaktierungs ^¬ apparatus for a high frequency signal in an inventive test socket,

FIG. 2E is a cross-sectional view of a fourth exporting ^¬ approximate shape of an inventive Kontaktierungs ^¬ apparatus for a high frequency signal in an inventive test socket,

Fig. 3 is a cross sectional view of a test socket according to the invention ^¬ SEN with a first variant of the ex ternal ^¬ high frequency connection to the inventiveness proper contacting device, FIG. 4A is a cross sectional view of an inventive ^¬ SEN test socket with a second variant of the ex ^¬ ternal high-frequency terminal in the non-plugged state of the inventive contact-making device, a cross-sectional view of an inventive ^¬ SEN test socket with a second variant of the ex ^¬ ternal high frequency connection when plugged in to ^¬ standing by the invention Kontaktierungsvor- direction, a cross-sectional view of an inventive ^¬ SEN test socket with a third variant of the ex ^¬ ternal high-frequency terminal in the non-plugged state of the inventive contact-making device, and FIG. 5B is a cross sectional view of an inventive ^¬ SEN test socket with a third variant of the ex ^¬ ternary high-frequency connection in the plugged Zu ^¬ stand on the contacting device according to the invention and

Fig. 6 is a flowchart of an inventive procedural ^¬ proceedings for the preparation of an inventive con ^¬ taktierungsVorrichtung.

The accompanying figures of the drawing are intended to convey a further understanding of the embodiments of the invention. They illustrate embodiments and serve together ^¬ menhang with the description of the declaration of principles and concepts of the invention. Other embodiments and many of the advantages mentioned arise with regard to the painting. The elements of the drawings are not necessarily shown to scale to each other.

In the figures of the drawing are the same, functionally identical and same-acting elements, features and components - so far ^¬ nothing else ^¬ provided - each provided with the same reference numerals.

In the following, the figures are described coherently and comprehensively.

DESCRIPTION OF EMBODIMENTS

1, a first embodiment of a test socket 1 according to the invention with a first embodiment of a contacting device 4 according to the invention for contacting a high-frequency signal is explained in detail. The test socket 1 according to the invention is typically designed as a block-shaped body 2 made of plastic, which meh ^¬ rere arranged in a certain grid Durchgangsboh ^¬ ments has. In these through holes are respectively contact elements 3, preferably contact pins 3, arranged mechanically fi xed, each preferably as a spring contact pins ^¬ executed as indicated in the following FIG. 2. For contacting each of an electrical ^¬ contact surface on a to be tested and not shown in Fig. 1 integrated circuit, the individual contact pins 3 are beyond a surface of the cuboid body 2 of the test socket 1 according to the invention. For contacting the individual contact pins 3 with further signal lines, which are connected directly or indirectly to the measuring device, the individual contact pins 3 are up to the opposite surface of the parallelepiped body 2 GE. leads or stand over this opposite surface ^¬ out. These contact pins 3 each detect a DC-recorders and low-frequency signal to the associated to kon ^¬ lactating electrical contact surface of the integrated circuit.

Within this grid of contact pins 3 is an be ^¬ certain number of mutually adjacent contact ^¬ pins 3 in each arrangement direction of the grid in each case by an inventive Kontaktlerungsvorrichtung 4 for contacting a respective high-frequency signal to supplied ^¬ impaired electrical contact surfaces of the inte to be tested ^¬ replaced circuit. In this case, a contactor device 4 for contacting a high-frequency signal replaces at least one contact pin. For the two in Fig. 1 by way of example Darge ^¬ presented contacting devices 4 each 3 * 3 = 9 pins are replaced. Each Kontak- are preferred tierungsvorrichtungen 4 respectively at its edges depending ^¬ weils adjacent to or surrounded by contact pins. 3 Al ternatively ^¬ two or more contact devices 4 may be adjacent to each other directly without the interposition of contact pins 3 to ^¬. Finally, contact-making devices 4 may be positioned at an edge or at a corner of the grid of contact pins 3 and thus be adjacent to only three edges or on two edges each of the contact pins 3 ^¬ or enclosed. Each contactor 4 for contacting a

High-frequency signal has in each case a contact element 5 for contacting the inner conductor of the high-frequency signal and min ^¬ least one contact element for contacting the outer conductor hochfre ^¬-frequency signal. In the illustrated in Fig. 1 th first embodiment of a contactor 4 For example, eight contact elements 61, 62, 63, 64, 65, 6δ, 67 and 6s are provided for contacting the high-frequency outer-conductor signal. These individual contact elements 5, 6 ₁ , 6 ₂ , 63, 64, 65, 6 ₆ , 67 and 63 in the first embodiment of the contact ierungs- device 4 and 4 are each designed as a resilient contact elements to compensate for contact in each direction of the present tolerances that can occur between the associated outer conductor contact points on the electrical contact surface to be contacted of the integrated circuit. Due to the small dimensions of the contact elements 61, 62, 63, 64, 65, 6 ₆ , 67 and 6 ₈ , these are each manufactured as micromechanical components with spring arms in, for example, LIGA technology.

In a second embodiment of a test socket 1 ^'of the invention with a second embodiment of he ^¬ inventive contact ierungsvorrichtung ^4' for the contacting of a high frequency signal according to Fig. 1B, only the contact elements 61, 62, 63, 64, 65, 6E, 67 and 63 executed for the outer conductor contact as a resilient contact element, while the contact element 5 is realized for the inner conductor contact as a rigid contact element. In this case, the tolerance compensation is ensured at the inner conductor contact by the spring element 14 still described below.

In a third embodiment of a test socket according to the invention 1 ^'' with a third embodiment of a contact according to the invention ierungsvorrichtung 4 ^'' to the contacting of a high frequency signal shown in Fig. IC is the sum of all the individual resilient contact members 61, 6 _2, 63, 64, 65 , 6δ, 67 and 63 for external conductor contact ierung by a single in the direction of contact ierungsrichtung resilient annular contact element 6 replaced. This contactor device is elastic. see annular contact element 6 may be, for example, a corrugated ring or an annular member made of an elastomer, are contained in the conductive particles in a certain Konzent ^¬ ration.

In a fourth embodiment of a test socket 1 ^'of the invention with a fourth embodiment of he ^¬ inventive contact ierungsvorrichtung ^4' for the contacting of a differential high-frequency signal of FIG. 1D are two resilient contact elements 5i and 5 ₂ to the inner conductor contact ation of the differential high-frequency signal and 1D, for example, ten fe ^¬- reducing contact elements 6i, 62, 63, 64, 65, 6e, 67, 6s, 69 and 6 ₁₀ ierung provided for Außenleiterkontakt.

The first embodiment of a present invention approximately Kontaktie- device 4 for contact ation of a Hochfrequenzsig ^¬ Nals and its electrical and mechanical connection to a high-frequency cable 7 will be explained below with reference to FIG. 2:

The contact element 5 for Innenleiterkontakt tion is directly and directly connected by means of, for example, a press fit with the inner conductor 8 of the high-frequency cable 7. The inner conductor 8 is led out for this purpose from the high-frequency cable 7 and arranged opposite the st irnseit igen end of the high frequency ^¬ cable 7. Instead of a press fit and a solder joint between the inner ^¬ conductor 8 of the high-frequency cable 7 and the contact element 5 for Innenleiterkontakt is possible.

All contact _elements 6 _lr 6 ₂ , 6 ₃ , 6 ₄ , 6 ₅ , 6 ₆ , 6 ₇ and 6 ₈ for outer conductor contact ierung are directly and directly with ei ^¬ ner electrically conductive inner sleeve 9, in which the high-frequency cable 7 is guided , each with a frontal Contact electrically and mechanically connected. Preferably, this connection between the individual Kontaktele ^¬ elements 6 ₁ , 6 ₂ , 6 ₃ , 6 ₄ , 6 ₅ , 6 e, 6 ₇ and 6s and the inner sleeve 9 by means of a solder joint. Alternatively, a screw or a connector by means of

Press fit conceivable.

The outer diameter of the outer conductor 10 of the Hochfrequenzka ^¬ lever 7 is smaller than the inner diameter of the inner sleeve 9, so that the high-frequency cable 7 and the inner sleeve 9 can be easily joined. As a connection technique Zvi ^¬ rule the high-frequency cable 7 and the inner sleeve 9 coming cohesive compounds, for example soldering, or positive or non-positive connections, such as crimping, in question. In Fig. 2A, the solder joint between the outer conductor 10 of the high-frequency cable 7 and the inner sleeve 9 is indicated by a thick line. For a secure electrical and mechanical connection between the outer conductor 10 of the high-frequency cable 7 and the Kontaktele- elements 6 ₁ , 6 ₂ , 6 ₃ , 6 ₄ , 6 ₅ , 6 ₆ , 6 ₇ and 6 ₈ for Außenleiterkontak- tion on the inner Sleeve 9 guaranteed.

Since the inner conductor contact ierungsbereich between the Kon ^¬ tact element 5 for Innenleiterkontakt tion and the Innenlei- ter 8 of the high-frequency cable 7 has a certain axial Erstre- ckung, the inner sleeve 9 relative to the front ^¬ end of the high-frequency cable 7 to this Kontaktie- extended range. In order to isolate in this extension region of the inner sleeve 9 acting as outer conductor inner sleeve 9 of the inner conductor contact ierungsbereichs, is at st irnseit igen En ^¬ de of the high-frequency cable 7 in analogy to the dielectric insulator 11 of the high-frequency cable 7, a dielectric iso- lator element 12 between the inner sleeve 9 and the inner ^¬ conductor contact ierungsbereich provided.

Only at the end of this extension, is the inner sleeve 9 electrically and mechanically connected to the individual contact elements 6i, 62, 63, 64, 65, 6, 6, 6 and 6 s for external conductor contact. The peculiarity of this design is the shortest possible axial extent of the ^¬ lectric insulator element 12, whereby the high-frequency cable 7 as close as possible to the contact plane 22 leads ^¬ leads and thus electrical impurities are considerably mini ^¬ mized. In this case, the contact plane 22 is the transition between the individual contact elements 5, 6 1, 62, 63, 64, 65, 6 e, 6 7 and 6 3 of the contact-making device 4 and the associated electrical contact areas of the integrated circuit to be tested Understood.

The entire contact ierungsvorrichtung 4 for a Hochfre ^¬-frequency signal comprises in analogy to the contact st iften 3 likewise apply an elasticity, on the one hand, a spring force of the contact is to electrical contact pads of the integrated circuit and on the other hand, Zvi ^¬ rule the individual electrical contact surfaces of the inte ^¬ grated circuit in the direction of contact ierungsrichtung compensate tolerances. For this purpose, the inner sleeve 7 is resiliently mounted in egg ^¬ ner outer sleeve 13. The resilient mounting of the inner sleeve 7 is effected by a spring element 14, which is within the outer sleeve 13 between a radially outwardly directed web 15 on st irnseit igen end of the inner sleeve 9 and a radially inwardly directed web 16 on st irnseit igen end of outer sleeve 13 is arranged. In this way, the contact is ierungsvorrichtung 4 for a high frequency signal in analogy to a spring contact st ift realized as an elastic contact component. The contact force of the spring element 14 is adapted to the contact ^¬ forces of the individual elastic contact elements 5, 6i, 6 ₂ , 6 ₃ , 6 ₄ , 6 ₅ , 6 ₆ , 6 ₇ and 6 ₈ ideally along the entire spring contact path. This means that the contact force of the spring element 14 approximately corresponds to the sum of the contact forces of the individual elastic contact elements 5, 6 ₁ , 6 ₂ , 63, 6 ₄ , 65, 6 _δ , 67 and 63 or preferably identical to the sum of the contact forces the individual elasti ^¬ rule contact elements 5, 6 _1, 6 _2, 6 _3, 6 _4, 6 _5, 6 ₆ 6 ₇ 6 and _8.

Instead of a spring element 14, any other, a pre ^¬ voltage generating technical mechanism such as pneumatic, hydraulic or elastomer can be used and is covered by the invention.

The inner sleeve 9 has an upper stop in the direction of the integrated circuit, which is provided by a Mittelbe ^¬ rich inner sleeve 9 radially outwardly directed web 18 and at the other st irnseit igen end of the outer sleeve 13 and bent radially inwardly Wall 19 of the outer sleeve 13 is realized.

The inwardly curved inner wall 19 of the outer sleeve 13 has an end-side passage 32, which is referred to below as the first passage 32, and allows axial movement of the inner sleeve 9 from the outer sleeve 13 out.

In the case of a first sub-variant of a second embodiment of a contact ierungsvorrichtung invention

4i ^'to the contact ation of a high-frequency signal of FIG. 2B, the inner conductor 8 of the high-frequency cable 7 is to Kon ^¬ clock element ^5' led to the inner conductor contact ation. Here, the inner conductor 8 of the high-frequency cable 7, as is apparent from Fig. 2B, over the front end of the Hochfre- Quenzkabels 7, ie over the front end of the Außenlei ^¬ ters 10 and beyond the frontal end of the dielectric insulator 11 of the high-frequency cable 7, led out. The hinaus- from the st irnseit strength end of the high frequency cable 7 guided inner conductor 8 is connected via a suitable stoffschlüs ^¬ fitting connection, for example by soldering, or egg ^¬ ne appropriate positive and / or non-positive connection, at ^¬ play, by means of press fit, directly and directly connected to the rigid contact element 5 ^' . For mechanical stabilization of the connection between the inner conductor 8 of the high-frequency cable 7 and the rigid contact element 5 ^' for Innenleiterkontakt tion, the additional insulator element 12 may be provided in the bore of the rigid contact element 5 ^' is anchored for Innenleiterkontakt ierung. Alternatively, however, it is also possible to dispense with the additional insulator element 12.

In a further embodiment of the first sub-variant of the second embodiment of a contact ierungsvorrichtung for the high-frequency signal, which is not shown, the inner conductor 8 of the high-frequency cable 7 is guided to the contact plane 22 without the use of a contact element 5. This is at Ver ^¬ strengthening of the inner conductor 8 of the high-frequency cable 7 in Kon ^¬ clock domain tet suitable coating in the contact region. In this case, the outer conductor 10 of the high ^¬ frequency cable 7 can be led to the individual contact elements 6i, 62, 63, 6 ₄ , 65, 6e, 67 and 6s.

In the case of a second sub-variant of the second embodiment of a contact ierungsvorrichtung 4 ₂ ^' according to the invention for contacting a high-frequency signal according to FIG. 2C, the inner conductor 8 of the high-frequency cable 7 is not led to st irnseit igen end of the high-frequency cable 7, but is in a certain Distance to st irnseit end of the high-frequency cable 7 shortened. In the resulting miserable recess 22 within the dielectric insulator 10 of the high-frequency cable 7 is a contact element 5 ^'' fixed to the Innenleiterkontaktierung. For fixing, the contact element 5 ^'' for Innenleiterkontaktierung at least one groove 23, preferably a plurality of grooves 23, into which or in which is foamed material of the dielectric Isola ^¬ sector 10 of the high-frequency cable 7. The enhancement of fixation, the depth of each groove 23 within the contact element 5 ^'' for Innenleiterkontaktierung thereby enlarged to the outer diameter of the substantially cylindrical contact element 5 ^'' for Innenleiterkontaktie ^¬ tion outside each of the slots 23 is larger than the outer ^¬ diameter of the High-frequency cable 7 belonging Innenlei ^¬ ters 8 and within the individual grooves 23 is smaller than the outer diameter of the high-frequency cable 7 associated In ^¬ nenleiters 8 dimensioned.

The fixation of the contact element 5 ^'' for Innenleiterkontak- tion at the front end of the high-frequency cable 7 is realized that the inner conductor 8 of Hochfre ^¬ quenzkabel 7 pushed out of the high-frequency cable 7 at the front end of the high-frequency cable 7 and with the Kon ^¬ tact element 5 ^'' Suitably - for example by means of soldering - is connected. Subsequently, the inner conductor 8 of the high-frequency cable 8 with the connected Kontaktele ^¬ ment 5 ^'' while heating the front end of the high ^¬ frequency cable 8 hineinein pushed ^¬ back into the high-frequency cable until only a tip of the contact element 5 ^' from the front end of the High-frequency cable 8 stands out. The contact element 5 ^'' is located in a that forms the recess 22 of the high-frequency cable 7. Due to the heating of the front end of the high-frequency cable 8, the pushing in of the contacts ^¬ lement 5 simplifies ^'connected' inner conductor, the insulating 7. In addition, foamed by heating Material of the dielectric see insulator 10 in the vicinity of the individual grooves 23, enters the individual grooves 23 and fills these ^¬ individual grooves 23 completely. In a third embodiment of an inventive

Contact ierungsvorrichtung 4 ^{'' of} FIG. 2D is the outer conductor contact tion a single contact element 6 is used. With a view to realizing a coaxial structure with the associated contact element 5 ^' for contacting the inner conductor, this contact element 6 has a cylindrical inner bore in the direction of contact with respect to the outer conductor contact. Preferably, the only contact element 6 for outer conductor contact tion in the direction of contact ringför ^¬ mig formed. In addition, the single contact element 6 for the outer conductor contact has an elasticity in the contact direction. The contact element 6 to the outer conductor ^¬ contact tion is connected to the st irnseit igen end of the inner sleeve 9 with a suitable connection technology, for example ^¬ by means of soldering, screwing or interference fit, connected.

In a fourth embodiment of a contact device ierungsvor ^¬ 4 ^'''according to Fig. 2E are two resilient Contacts- to the contact ation of a differential high-frequency signal ELEMENTS ation provided 5i and 5 ₂ to the inner conductor contact.

These resilient contact elements 5i and 5 ₂ for the inner conductor contact are each connected to an inner conductor 8i and 8 _{2 of} the differential high-frequency cable 7 ^' . The two inner conductors 8 ₁ and 8 ₂ are surrounded within the outer conductor 10 of the differential high-frequency cable 7 ^' by a respective belonging to ^¬ dielectric insulator Iii and II ₂ . The two inner conductors 8 ₁ and 8 _{2 of} the differential Hochfre ^¬ quenzkabel 7 ^' are each led beyond the associated dielectric ^¬ 's insulator Iii and II ₂ and by an associated bore within the insulator element 12 with the associated resilient contact element 5i and 5 ₂ to the inner conductor contact tion electrically connected. The resilient Kon ^¬ clock elements 5i and 5 ₂ are ation to the inner conductor contact connected in play ^¬ by press fitting or screwing opinion within the associated bore with the insulator element 12th Instead of the illustrated in Fig. 2E resilient contact elements 5i and 5 ₂ for Innenleiterkontakt tion rigid contact elements can be used. In a first variant of an external Hochfrequenzan ^¬ statements to the invention contact according ierungsvorrichtung Fig. 3, the reasoning apparatus in the inventive Kontaktie- 4, 4ι ^', 4 ^_2', 4 ^'' and 4 ^'''guided Hochfre ^¬ quenzkabel 7 from the Contact ierungsvorrichtung led out and directly or indirectly connected to a high-frequency meter:

For this purpose, the high-frequency cable 7 through a bore, which is hereinafter referred to as a second passage 17 and which is formed by the web 16 at st irnseit igen end of the outer Hül ^¬ se 13, in the outer space of the Kontaktvorrich ^¬ device 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' out. In this case, the high-frequency ^cable 7 can be routed directly to a high-frequency measuring device or indirectly via an interconnected printed circuit board, for example a sample card (German: measuring adapter module), or an adapter or an adapter module interposed therebetween to a high-frequency measuring device. From Fig. 3, a module 20, preferably a Lei ^¬ terplatte 20, shown, which is integrated either in the cuboid body 2 of the test socket 1, 1 ^' , 1 ^'' and 1 ^' according to the invention or directly to the test socket 1, 1 according to the invention ^' , 1 ^'' and \ ^{''' is} affiliated. This group 20 implements an electrical and mechanical Bond between the contact pins 3, which are arranged in a ver ^¬ like small grid spacing from each other, in associated further contact pins 21, which are arranged at a greater distance to each other. In DIE se manner, the DC and Niederfre ^acid sequence signals at the ends of the individual further contact pins ^¬ blank 21 by a simple to realize probe card, tap. It can also be seen that the contacting device 4, 4 ^'' , 4 ₂ ^' , 4 ^'' and 4 ^''' according to the invention for contacting a high-frequency signal with respect to the longitudinal extension of the contact pins 3 is extended and passed through a bore 26 in the assembly 20 is. The assembly 20 imple- mented a spatial separation between the individual Kon ^¬ clock pins 21 and the depending ^¬ weils also guided from the individual bores 26 contact devices 4, 4i ^', 4 ^_2', 4 ^'' and 4 ^'''for contacting a Hochfrequenzsig ^¬ nals. A deflection, ie a bend, the individual high-frequency cable 7 by a certain angle, preferably an angle of 90 °, which requires a certain space can be realized in this way.

Within the grid of contact pins 3, which are arranged in a relatively small grid spacing, the individual contacting devices 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^' for contacting each of a high-frequency ^¬ signal and the electrically and mechanically connected thereto High-frequency cable 7 parallel to the individual pins 3, ie in contacting direction, out. The single ones

Contact terminals 4 and the associated high-frequency cable 7 are oriented in particular along the entire axial extent of the contact pins 3 parallel to the individual contact pins 3. In addition to the solution shown in Fig. 3 also from ^¬ guides without the assembly 20 are possible. Also embodiments in which dispense with the additional contact pins 21 ^¬ to, are conceivable.

Due to the small pitches in tenths of a millimeter range, the respective high-frequency cables 7 are adapted accordingly in their cross-sectional extent. Be used as a high-frequency cable 7 coaxial cable, so come Because of the low pitch intervals so-called micro ^¬ coaxial cable, that is coaxial with a small cable cross-section ^¬ used.

In a second variant of an external Hochfrequenzan- circuit according to the figures 4A and 4B is that in the OF INVENTION ^¬ to the invention contacting device 4, 4χ ^', 4 ^_2', 4 ^'' and 4 ^'run high-frequency cable 7 on to an external high ^¬ frequency cable over a front end of the external high-frequency cable mechanically and electrically connected connectors:

For this purpose, in the Kontaktierungsvor ^¬ direction 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' guided high-frequency cable 7 is also by a second passage 17, which by a web 16 at the front end of the outer sleeve 13th is formed ^{¬ out} in the outer space of the contacting device 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' out. Each contact pin 3 and each contacting device 4, 4χ ^' , 4 ₂ ^' , 4 ^'' and 4 ^'''of the test socket 1, 1 ^' , 1 ^'' and 1 ^''' ends on a surface 24 of the cuboid body 2, the a surface ^¬ che 25 of the cuboid body 2 is opposite, which is located immediately adjacent to the contact plane 22 of the erfindungsge ^¬ MAESSEN contacting device 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' with the integrated circuit to be tested. At this surface 25 of the cuboid body 2 closes immediately telbar the assembly 20, preferably a circuit board 20, which realizes an increase of the grid spacing of the individual Kon ^¬ clock pins. 3 In this assembly 20, a through bore is aligned with the longitudinal extent of the contacting device 4 according to the invention, 4ι ^', 4 ^_2', 4 ^'' and 4 ^'''provided 26th In this through-hole 26 which is from the inventive Kon ^¬ taktierungsvorrichtung 4, 4ι ^', 4 ^_2', 4 ^'' and 4 ^'''hinausge- led high-frequency cable 7 through a fraction of the Längser ^¬ stretching of the through hole extended 26th The Innenlei ^¬ ter 8 of the high-frequency cable 7 is in this case additionally slightly extended relative to the dielectric insulator 11 and the outer conductor 10 of the high ^¬ frequency ^cable 7. The through hole 26 is dimensioned to be as

Coupling element for receiving a at a front end of another high-frequency cable 7 ^' attached plug- ^connector 27 can serve. In the inserted state of the connector 27 in the as

Coupling element serving through hole 26 of the Baugrup ^¬ pe 20 of FIG. 4B abuts the connector 27 preferably with its front end at the front end of he ^¬ inventive contacting device 4, 4χ ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' to. Via a snap connection, as indicated in Fi ^¬ guren 4A and 4B, is selected from the Inventive ^¬ proper contacting device 4, 4ι ^', 4 ^_2', 4 ^'' and 4 ^'''also guided high-frequency cable 7 with the connector 27 mechanically connected and thus with the other high-frequency cable 7 ^' electrically inside and outside conductor kon ^¬ clocked. The completed with the connector 27 high frequency ^¬ cable 7 ^' is directly to a high-frequency meter or to an interconnected circuit board, example ^¬ a sample card (German: measuring adapter assembly), or to an interposed adapter or Adapterbaugrup ^¬ pe passed.

In order to allow easier removal of the completed connector 27 with the high-frequency cable 7 ^'from the Durchgangsboh ^¬ tion 26 of the assembly 20, the diameter of the through hole 26 is enlarged on the output side over a certain length. Alternatively, the connector 27, the end of a further high-frequency cable 7 ^'is attached may also be a with an assembly ^20', preferably with a circuit board 20 ^', verbun ^¬ Dener connector 29 (so-called Leiterplattensteckver ^¬ binder) as further untern reference to the Figures 5A and 5B is presented, serving as the coupling element

Through hole 26 of the assembly 20 may be plugged.

In a third variant of an external Hochfrequenzan ^¬ circuit according to the figures 5A and 5B in the inventive contacting device 4, 4χ ^' , 4 ₂ ^' , 4 ^'' and 4 ^' guided high-frequency cable 7 with a on a ^¬ construction group, preferred a circuit board, fixed Steckver ^¬ binder electrically and mechanically connected: For this purpose, the within the contacting device 4,

4 ^'' , 4 ₂ ^' , 4 ^'' and 4 ^''' guided high-frequency cable 7 also through a second passage 17 in a web 16 of äuße ^¬ ren sleeve 13 in the outer space of the contacting device 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' out. The longitudinal extent of each contact pin 3 and each contacting device 4, 4i ^' , 4 ₂ ^' , 4 ^'' and 4 ^'''of the test socket 1, 1 ^' , 1 ^'' and 1 ^' according to the invention is not analogous to the second variant of an external high-frequency connection contacted state ^¬ identical. In contrast to the second variant of an external high-frequency connection, the web 16 is the outer one Sleeve 13 is not attached to the front end of the Kontaktierungsvor- direction 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' , but is by a certain distance in the direction of the contact elements 5, 5i, 5 ₂ , 5 ^' , 5 ^'' , 6, 6i, 6 ₂ , 6 ₃ , 6 ₄ , 6 ₅ , 6 ₆ , 6 ₇ , 6 ₈ , 6 ₉ and 6 _i0 staggered. The area between the web 16 and the front end of the outer sleeve 13 is provided as a Kopp ^¬ development element for receiving a plug connector 29 being shaped and dimensioned ^¬. Which is a fraction of the distance between the web 16 and the front end of the outer sleeve 13 of the inventive contacting device 4, 4χ ^', 4 ^_2', 4 ^'' and 4 ^'''also guided high-frequency cable 7 extends. The inner conductor 8 of the high-frequency cable 7 is in this case compared to the dielectric insulator 11 and the outer conductor 10 of the high-frequency cable 7 also additionally slightly extended ^¬ ver. The coupling ^element formed at the front end of the outer sleeve 13 is dimensioned such that a plug connector 29, which is fastened on an opposite surface 30 of an assembly 20 ^' , preferably a printed circuit board 20 ^' , in the inserted state according to FIG from the contacting device according to the invention 4, 4i ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' out high-frequency cable 7 inside and outside conductor safely mechanically and electrically connected is connected. In addition, the connector 29 pushes in the plugged ^¬ th state preferably on the web 16 of the outer sleeve of he ^¬ inventive contacting device 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^' . The connector 29 is electrically and mechanically connected on the inside and outside conductors with corresponding contact surfaces of a high-frequency connection, which are applied to the surface 30 of the assembly 20 ^' . Analog contact in the inserted state of the connector 29, the individual contact pins 3 associated contact surfaces 28, each on suitable position on the surface 30 of the assembly 20 ^{'are placed} on ^¬ .

As an alternative to using an assembly 20 ^{'electrically} and mechanically connected to connector 29 can also at a further high-frequency cable ^7' mounted Termina ^¬ 27, as is above-illustrated in the figures 4A and 4B, in the formed as a coupling element front end of the invention Contacting device 4, 4i ^' , 4 ₂ ^' , 4 ^'' and 4 ^'''are plugged.

Finally it should be noted that the erfindungsge ^¬ Permitted test socket 1, 1 ^{', 1''and] _'''} in the area of each rasterized arranged contact pins 3 for contacting an electrical signal or an electric potential and the respectively adjacently arranged Kontaktierungsvor - Directions 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' for contacting a high-frequency signal a tempered air duct 31 for Küh ^¬ treatment or heating of the individual pins 3 and the individual contacting devices 4, 4χ ^' , 4 ₂ ^' 4 ^" and 4 ^" optionally may have.

The advantage of the thus finally described exporting ^¬ approximately forms a contacting device 4, 4χ ^', 4 ^_2', 4 ^'' and 4 ^'for contacting a high-frequency signal is as ^¬ rin to see that each contacting device for contacting a high-frequency signal separately to be ^¬ belonging test socket 1, 1 ^' , 1 ^'' and] _ ^''' can be manufactured and is interchangeable in case of error.

Finally, the inventive method for producing a Kontaktierungsvor ^¬ invention 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' is explained in detail below with reference to the flowchart in Fig. 6: In a first method step S10, the spring element 14, the inner sleeve 9 in the outer sleeve 13 of the contacting tion device 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' inserted. On closing ^¬ the high-frequency cable 7 is inserted through the second passage 17 in the web 16 of the contacting device 4, 4ι ^' , 4 ₂ ^' , 4 ^'' and 4 ^''' associated outer sleeve 13 in the inner region of the inner sleeve 9. The outer conductor 10 of the high-frequency cable 7 is connected to the inner sleeve 9 either with a cohesive connection method, for example by means of soldering, or with a positive and / or non-positive connection method, for example with ^{¬ means} crimping.

In the next method step S20, the inner conductor contact side contact element 5 is connected to the inner conductor 8 of the high ^¬ frequency cable 7 or the two inner conductor contact side contact elements 5i and 5 ₂ with the associated inner conductors 8i and 8 _{2 of} the high-frequency cable 7 with a suitable conne ^¬ tion method.

In the case of the first embodiment, the first sub-variant of the second embodiment, the third embodiment and the fourth embodiment of the contacting device 4, 4χ ^' , 4 ^'' and 4 ^''' according to the invention, the inner conductor 8 of the high-frequency cable 7 is used for this purpose led out stirnseiti ^¬ towards the end of the high-frequency cable 7 and with egg ^¬ nem cohesive connection methods, for example by soldering, or with a positive and / or frictional connection method, for example by interference fit, with the inner-conductor-contact-side contact member 5 and 5i and 5 ₂ for the realization of a safe connected electrical contact.

In the case of the second sub-variant of the second embodiment of the contacting device 4 ₂ ^' according to the invention the inner conductor 8 of the high-frequency cable 7 is for this purpose the inner conductor 8 of the high-frequency cable 7 also opposite the st irnseit igen end of the high-frequency cable 7 hinausge ^¬ leads and with a material connection method, for example by means of soldering, or with a positive and / or non-positive connection method, for example by means of interference fit, with the inner conductor contact since iges Kontaktele ^¬ ment 5 or 5i and 5 _{2 connected} to the realization of a secure electrical contact.

Subsequently, the front end of the Hochfrequenzka ^¬ lever 7 is heated over a certain period of time. During the heating phase, the inner conductor 8 of the Hochfrequenzka ^¬ lever 8 with the attached inner conductor contact since igen contact element 5 ^'' pushed back into the high-frequency cable 7 ^¬ until only a certain portion of the inner ^¬ conductor contact seit igen contact element 5 ^'' from the stirnsei ^¬ end of the high-frequency cable 7 protrudes. The heating simplifies the shifting and foams the insulating material of the dielectric insulator 11 and penetrates into the originally empty intermediate space within the grooves 23 of the inner conductor contact since contact element 5 ^' . Are the spaces filled with insulation material completeness, ^¬ dig within the grooves 23, the heating process can be adjusted. After a cooling phase, the inner conductor contact is permanently fixed in the high-frequency cable 7 since contact element 5 ^" .

In the subsequent method step S30, the individual outer conductor contact side contact elements 6, 6i, 6 ₂ , 6 ₃ , 6 ₄ , 6 ₅ , 6 e, 6 ₇ , 6s, 6 ₉ and 6 ₁₀ with the inner sleeve 9 of he ^¬ inventive Contact ierungsvorrichtung 4, 4χ ^' , 4 ^'' and 4 ^' either cohesively, for example by means of soldering, or positive or non-positive, for example by means

Press fit, connected. In the final step S40, the outer Sleeve Shirt ^¬ se 9 of the contacting device 4, 4i invention ^{', 4''and 4'} is integrated in the direction to be tested

Circuit, ie in the direction of the contact ^plane 22, ^{abgeschlos ¬} sen. For this purpose is formed, for example, with ^¬ means of bending, a radially inwardly of the outer sleeve 9 at the front end and inwardly bent web 19 by means of cold forming.

An inventive Kontaktierungsvor ^¬ direction 4, 4i ^' , 4 ^'' and 4 ^''' is made in a suitable dimensioned ^¬ bore within the associated test socket according to the invention 1, 1 ^' , 1 ^'' and] _ ^''', for example by means

Press fit in adjacent position and in parallel Ori ^¬ entierung to the individual raster arranged arranged Kontakt ^¬ pins 3 inserted.

Although the present invention has been fully described above by means of preferred embodiments, it is not limited thereto, but modifiable in a variety of ways.

LIST OF REFERENCE NUMBERS

test socket

 cuboid body

Contact ^element , in particular contact ^pin

 Contacting device

inner-conductor contact-page Kontaktele ^¬ rnent

 Outside conductor contact side contact element

 RF cable

 Inner conductor of high frequency cable inner sleeve

Outer conductor of the high frequency cable dielectric insulator of Hochfre ^¬ quenzkabels

 Insulator element

 outer sleeve

 spring element

 Bridge of the inner sleeve

 Bridge of the outer sleeve

 second implementation

 Bridge of the inner sleeve

 inwardly curved inner wall of the outer sleeve

 module

 another contact pin

 Contact level

 groove

facing away from the integrated circuit surface of the cuboid body to the integrated circuit directed surface of the cuboid body 26 Through hole of the module

 27 High Frequency Cable Connector

28 contact surfaces of the module

 29 connector on module

5 30 Surface of the assembly

 31 air duct

 32 first implementation

Claims

1. Test socket (1, 1 ^' , 1 ^'' , 1 ^''' ) with a plurality of contact elements ^¬ (3) for contacting each of an electrical signal or each of an electrical potential and at least one contact ierungsvorrichtung (4; ^'; 4 ^_2'; 4 ^''; 4 ^''') for contact ation of each of a Hochfrequenzsig ^¬ nal, wherein the plurality of contact elements (3) are respectively arranged in a first grid within the first Ras ters ierungsvorrichtung through each contact (4; 4ι ^'; 4 ^_2'; 4 ^''; 4 ^''') each have at least one adjacent contact element (3) is replaced in each of the two mutually orthogonal arrangement Rich ^¬ obligations of the first raster, each Kontaktie- approximately device (4; 4ι ^'; 4 ^_2'; 4 ^''; 4 ^')''extends along the axial extent of the contact elements (3) parallel to the Kontakt ^¬ tele elements (3), wherein the at least one Kontak- tierungsvorrichtung (4; ^4ι'; 4 ₂ ^{', 4''; 4''')} in each case under ^¬ differently to each Contact element (3) is.

2. test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 1, characterized in that

that each contact ierungsvorrichtung (4, 4 ^'' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) is designed in each case sleeve-shaped.

3. Test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 2, characterized

each sleeve-shaped contact ierungsvorrichtung (4; 4i ^' ; 4 ₂ ^' ; 4 ^'' ; 4 ^''' ) each with an associated Hochfrequenzka ^¬ bel (7) is connected, wherein the associated Hochfrequenzka- at (7) each within the respective sleeve-shaped Kon ^¬ takt ierungsvorrichtung (4; 4ι ^' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) is guided.

4. test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 3, characterized each sleeve-shaped contacting device (4; 4i ^' ; 4 ₂ ^' ; 4 ^'' ; 4 ^''' ) has a respective one in the test socket (1; 1 ^' ; 1 ^'' ;

1 ^''' ) fixed outer sleeve (13) and in the outer sleeve (13) in the axial direction elastically guided inner sleeve (9), wherein the inner sleeve (9) on the outer sleeve ^¬ (13) through a first passage (32) provided on an end face of the outer sleeve (13) is movable in the axial direction.

5. Test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 4, characterized

an outer conductor (10) of the associated high-frequency cable (7) is connected to the electrically conductive inner sleeve (9).

6. test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 4 or 5,

characterized ,

the associated high-frequency cable (7) is guided out of the outer sleeve (13) by a second passage (17) provided in the outer sleeve (13).

7. test socket (1; 1 ^' ; 1 ^''; 1 ^''' ) according to claim 6, characterized

the sleeve-shaped contacting device (4; 4i ^' ;

4 ₂ ^' ; 4 ^'' ; 4 ^''' ) between the second passage in a web (16) of the outer sleeve (13) and an end En ^¬ de the outer sleeve (13) as a coupling element for receiving a connector (27, 29) is formed.

8. A test socket (1; 1 ^{'; 1''; 1''')} according to one of patent applica ^¬ claims 4 to 7,

characterized ,

in that at least one inner conductor contact side contact element (5, 5i, 5 ₂ , 5 ^' , 5 ^" ) is provided with in each case one inner conductor of the High-frequency cable (7) and at least one outer conductor contact side contact element (6, 6i, 6 ₂ , 63, 6 ₄ , 65, 6 _δ , 67, 6s, 6 ₉ , 6 ₁₀ ) are connected to the inner sleeve (9).

9. test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 8, characterized in that

in that the contacting device (4; 4 ^'' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) has a plurality of external conductor contact side elastic contact ^elements (6 ₁ , 6 ₂ , 63, 6 ₄ , 65, 6 _δ , 67, 6s, 69 , 6 ₁ 0).

10. test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 9, characterized in that

in that the outer conductor contact side elastic contact ^elements (6 ₁ , 6 ₂ , 6 ₃ , 6 ₄ , 6 ₅ , 6 _δ , 6 ₇ , 6s, 6 ₉ , 6 ₁₀ ) are contact elements with a spring arm arranged in the first grid.

11. Test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 8, characterized in that

in that the contacting device (4, 4 ^'' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) has a contact element on the outside conductor side with a contact element

Has elasticity and a cylindrical bore in contacting direction.

12. test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 8, characterized in that

in that the contacting device (4, 4 ^'' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) has an inner conductor contact side elastic contact element (5, 5 i, 5 ₂ ).

13. Test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 8, characterized in that

in that the contacting device (4, 4 ^'' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) has an inner conductor contact-side, rigid contact element (5 ^' , 5 ^'' ).

14. A test socket (1; 1 ^{'; 1''; 1''')} according to one of patent applica ^¬ claims 8 to 13,

characterized ,

the inner sleeve (9) is connected to the at least one outer conductor contact since contact element (6i, 6 ₂ , 6 ₃ , 6 ₄ , 6 ₅ , 6 ₆ , 6 ₇ , 6 ₈ , 6 ₉ , 6 ₁₀ ).

15. A test socket (1; 1 ^{'; 1''; 1''')} according to one of patent applica ^¬ claims 8 to 14,

characterized,

that at least one inner conductor (8; 8 _1, 8 ₂₎ of the high frequency ^¬ cable (7) with the respectively associated innenleiterkontakt- side contact member (5; 5i, 5 _2; 5 ^{'; 5'')} is connected.

16 test socket (1; 1 ^' , 1 ^'' , 1 ^''' ) according to claim 15, characterized in that

the at least one inner conductor (8; 8 _1, 8 ₂₎ projects out of the Hochfre ^¬ frequency cable (7) made from a strength st irnseit end of Hochfre ^¬ frequency cable (7).

17. A test socket (1; 1 ^{'; 1''; 1''')} according to one of patent applica ^¬ claims 1 to 16,

characterized ,

is connected, in the egg ^¬ ne implementation of the in; that each contact element (3) ation to the contact of a respective electrical signal or by a respective electrical ^¬'s potential to a corresponding first contact point (28) on a module (20 ^'20) first grid each arranged Ers ^¬ th contact points (28) in associated, in a second grid ter respectively arranged second contact points takes place, the pitch of the second contact points relative to the grid spacing of the first contact points (28) is increased.

18. Contact ierungsvorrichtung (4; 4ι ^' ; 4 ₂ ^' ; 4 ^'' , 4 ^''' ) for contacting each of a high-frequency signal with a outer sleeve (13), in the outer sleeve (13) in axia ^¬ ler direction outwardly guided inner sleeve (9), a spring element (14) between the inner sleeve (9) and one on the outer sleeve (13) radially an inwardly directed web (16) is positioned, one connected to the electrically conductive inner sleeve (9) outer conductor (10) of a Hochfrequenzka ^¬ lever (7), at least one with an inner conductor (8, 8i, 8 ₂ ) of the high frequency cable (7 ) each connected inside conductor contact since igen contact element (5; 5 ^' , 5 ^'' , 5i, 5 ₂ ) and at least one with the inner sleeve (9) connected to the outside ^¬ conductor contact seit igen contact element (6, 6 ₁ , 6 ₂ , 6 ₃ , 6 ₄ , 6 ₅ ,

19. contacting device (4, 4 ^' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) according to claim 18,

characterized ,

that the inner sleeve (9) over the outer sleeve (13) also provided through an on one end face of the outer sleeve (13) ^¬ provided first passage (32) is movable in the axial direction, wherein movement of the inner sleeve (9) a radially outwardly directed web (18) of the inner sleeve (9) and a first passage (32) bounding and ra ^¬ dial inwardly directed axial boundary (19) of the äuße ^¬ ren sleeve (13) is axially limited.

20. contacting device (4; 4χ ^' ; 4 ₂ ^' ; 4 ^'' ; 4 ^''' ) according to claim 18 or 19,

characterized ,

in that the at least one outer conductor contact since each contact element (6, 61, 62, 63, 64, 65, 6e, 67, 63, 69, 610) is in each case an elastic contact element with a spring arm.

21. contacting device (4, 4 ^' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) according to claim 18 or 19,

characterized , the at least one outer conductor contact-side contacts ^¬ lement (6, 6 i, 6 _2, 63, 6 _4, 65, 6δ, 67, 6s, 69, 6 ₁ 0) is a Kontakt ^¬ wick member having a cylindrical bore and a Elastizi ^¬ ty in the contacting is.

22. contacting device (4, 4 ^'' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) according to one of the claims 18 to 21,

characterized ,

the at least one inner conductor contact side contact element (5; 5i, 5 ₂ ) is an elastic contact element.

23. contacting device (4; 4ι ^' ; 4 ₂ ^' ; 4 ^'' ; 4 ^''' ) according to one of the claims 18 to 21,

characterized ,

the at least one inner-conductor-contact-side contacts ^¬ lement (5; ^{'; 5'} 5 ^') is a rigid contact element.

24. contacting device (4, 4 ^' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) according to claim 22 or 23,

characterized,

the at least one inner conductor (8; 8 _1, 8 ₂₎ projects out of the Hochfre ^¬ frequency cable (7) from a front end of the Hochfre ^¬ frequency cable (7).

25. contacting device (4, 4 ^' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) according to claim 22 or 23,

characterized ,

the at least one inner conductor (8; 8 _1, 8 ₂₎ of the Hochfre ^¬ frequency cable (7) against a corresponding insulator (11; Iii, H ₂₎ of the high-frequency cable (7) is axially moved back and the (at least one inner-conductor-contact side Kon ^¬ clock element 5; 5i, 5 ₂₎ to the inner conductor (8; 8 _1, 8 ₂₎ is ver ^¬ connected and in a recess (22) in the associated Iso ^¬ lator (11; Iii, H is inserted ₂₎ of the high-frequency cable (7) ,

26. contacting device (4, 4 ^' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) according to claim 25,

characterized ,

that the contact element (5; 5i, 5 ₂₎ at least one groove (23), in which an insulator material of the associated Iso ^¬ lators (11; Iii, H2) is inserted.

27. contacting device (4, 4 ^' , 4 ₂ ^' , 4 ^'' , 4 ^''' ) according to one of the claims 19 to 26,

characterized ,

that the high-frequency cable (7) provided by one in the outer sleeve (13) second passage (17) from the externa ^¬ ßeren sleeve (13) is led out.

28. contacting device (4; 4χ ^' ; 4 ₂ ^' ; 4 ^'' ; 4 ^''' ) according to claim 27,

characterized ,

in that the sleeve-shaped contacting device (4; 4i ^' ; 4 ₂ ^' ; 4 ^'' ; 4 ^''' ) is formed between the second feedthrough and a front end as a coupling element for receiving a connector (27, 29).

29. A method for producing a Kontaktierungsvorrich- device (4; 4ι ^'; 4 ^_2'; 4 ^''; 4 ^''') according to one of the claims

18 to 28 for contacting each of a high-frequency ^¬ signal with the following process ^steps :

Inserting a spring element (14) and an inner sleeve (9) of the contacting device (4; 4ι ^' ; 4 ₂ ^' ; 4 ^'' ; 4 ^''' ) connected to an outer conductor (10) of a Hochfrequenzka ^¬ lever (7) is, in an outer sleeve (9) of the Kontak- tierungsvorrichtung (4; 4ι ^' ; 4 ₂ ^' ; 4 ^'' , 4 ^''' ),

Connecting at least one inner conductor contact side contact element (5, 5 ^' , 5 ^" , 5i, 5 ₂ ) to an associated inner conductor (8; 8 ₁ , 8 ₂ ) of the high frequency cable (7), Connecting at least one outer conductor contact side contact element (6, 6i, 6 ₂ , 63, 64, 65, 6δ, 67, 6s, 69, 610) to an inner sleeve (9) of the contacting device (4, 4 ^' , 4 ₂ ^' 4 ^" , 4 ^"' ) and

· 30. A method according to claim 29, forming a · to a targeted under test integrated circuit axial boundary (19) of the outer sleeve (9) of the contacting device (4; 4ι ^'; 4 ^_2';; 4 ^'' 4 ^"')

characterized ,

that the connecting of the at least one innenleiterkontakt- side contact member (5; 5 ^{'; 5'';} 5 i, 5 ₂₎ to the zugehö ^¬ ring inner conductor (8; 8 _1, 8 ₂₎ of the high-frequency cable (7) folic constricting process steps includes :

axially leading out the at least one inner conductor (8, 8 ₁ , 8 ₂ ) of the high-frequency cable (7) from an associated insulator (11, Iii, H ₂ ) of the high-frequency cable (7) at a front end of the high-frequency cable (7),

Connecting the at least one inner conductor contact side contact element (5, 5 ^' , 5 ^" , 5i, 5 ₂ ) to the associated inner conductor (8; 8 ₁ , 8 ₂ ) of the high frequency cable (7) and

Heating the front end of the high-frequency cable (7) over a certain period of time and axial Hineinver- push the at least one inner conductor (8; 8 _1, 8 ₂₎ of the high-frequency cable (7) to the respectively associated inside ^¬ conductor contact-side contact member (5; 5 ^'; 5 ^" , 5i, 5 ₂ ) into the high frequency cable (7). 31. The method according to claim 29,

characterized ,

that the connecting of the at least one innenleiterkontakt- side contact member (5; 5 ^{'; 5'';} 5 i, 5 ₂₎ to the zugehö ^¬ ring inner conductor (8; 8 _1, 8 ₂₎ of the high-frequency cable (7) folic constricting process steps includes : axially leading out the at least one inner conductor (8; 8i, 8 ₂ ) of the high-frequency cable (7) from an associated insulator (11; Iii, H ₂ ) of the high-frequency cable (7) at a front end of the high-frequency cable (7) and

Connecting the at least one inner conductor contact side contact element (5, 5 ^' , 5 ^" , 5i, 5 ₂ ) to the associated inner conductor (8; 8 ₁ , 8 ₂ ) of the high frequency cable (7).