Prior Art Electrical signal lines are known, for example, from European Patent Application EP-A-0 735 544 (Cartier et al.) assigned to Hewlett-Packard Company. This patent application describes an ultrasound system with a transducer cable for providing an electrical connection between a transducer and a display processor. The first embodiment of the transducer cable in this application has a plurality of stripline or sub-cable assemblies, which are surrounded by single metal braid as an outer overall shield. The third embodiment of the transducer cable in this application uses three layers of extruded ribbon assemblies separated from each other by shield conductors comprising thin strips of bare copper. Each sub-cable assembly contains an integral electrical shielding which separates some of the electrical conductors within one sub-cable assembly from other electrical conductors within the same sub-cable assembly respectively.

There is, however, no shielding on the outside of each sub-cable assembly provided for separating two sub-cable assemblies from each other. The stack of sub-cable assemblies are extruded with a jacket to form a desired length of the transducer cable.

US-A-4 847 443 (Basconi) assigned to the Amphenol Corporation teaches another example of an electrical signal line cable formed from a plurality of generally flat electrical signal line segments stacked together in an interlocking relationship. Each electrical signal line segment of this prior art cable contains at least one signal conductor surrounded on either side by ground conductors. The plurality of ground conductors effectively form a ground plane which inhibit the cross-talk between the adjacent signal conductors. The insulating materials in which the conductors are disposed is extruded over the individual signal conductors.

European Patent EP-B-0 605 600 (Springer et al.) assigned to the Minnesota Mining and Manufacturing Company teaches a ribbon cable and a lamination method for manufacturing the same. The ribbon cable manufactured comprises a plurality of evenly spaced flexible

conductors surrounded by an insulator which is a microporous polypropylene.

US Patent US-A-4 847 443 (Crawley et al.) assigned to W. L. Gore & Associates teaches a multi-conductor flat ribbon cable having a plurality of electrical conductors disposed within an insulator consisting of expanded polytetrafluoroethylene (ePTFE).

PCT patent application WO-A-91/09406 (Ritchie et al) teaches an electrical wiring composed of elongated electrically conductive metal foil strips laminated between opposing layers of insulating films by means of adhesive securing the foil strips between the laminating films.

German patent application DE-A-24 24 442 assigned to Siemens teaches a cable assembly which comprises a plurality of flat cables laminated between insulating films.

PCT patent application WO-A-80/00389 (Clarke) assigned to Square D company of Palatine, Illinois, teaches an input/output data cable for use with programmable controllers. The cable has a ground conductor, a logic level voltage conductor and a number of signal tracks. The conductors are disposed on two or three layers of flexible plastics material in specified ways to give high immunity to interference and low inductive losses. The layers are glued together to form a laminate structure.

W. L. Gore & Associates, Inc., in Phoenix, Arizona, sell a round cable under the part number 02- 07605 which comprises 132 miniature co-axial cables enclosed within a braided shield of tin- plated copper and a jacket tube of PVC.

Summary of the Invention It is an object of the invention to provide an improved electrical signal cable assembly.

It is a further object of the invention to provide an electrical signal cable assembly which is easily terminated.

It is a further object of the invention to reduce the weight of an electrical signal cable assembly so that it can be attached to a hand-held sensor device, such as an ultrasound probe, for easy

handling.

It is a further object of the invention to provide an electrical signal cable assembly which has a high flexlife, as well as low weight.

It is a further object of the invention to minimise the cross talk between the individual signal conductors within an electrical signal cable assembly so that it is suitable in highly sensitive applications such as for ultrasound probes.

These and other objects of the invention are solved by providing an electrical signal cable for transmission of electromagnetic waves comprising at least two electrical conductors, wherein at least one electrical conductor is a signal conductor and at least one other electrical conductor is a ground conductor, wherein a ratio of a weight per length of said signal cable to the impedance of said signal cable is less than g/m/Q, in particular less than 0.002 g/m/M mm Q This has the advantage of achieving extremely low weight cables per unit length especially with a large number of electrical conductors and even with a need for high impedance, resulting in easy handling and longer lifetime. Additionally such a signal cable shows very positive properties concerning flexibility and bending.

Depending on actual applications of the electrical signal cable a package density of the electrical conductors is in the range of 1 to 100 conductor per mm2.

In a preferred embodiment the electrical signal cable is build up as a flat cable with coplanar arranged electrical conductors, wherein for example every second or third electrical conductor is a ground conductor. The electrical conductors are arranged e. g. parallel to each other.

It is especially preferred that each ground conductor is arranged together with a corresponding signal conductor as twisted pair, that two electrical conductors are arranged as ribbon pair or that two electrical conductors are arranged coaxial to each other.

A most simple architecture is achieved by that at least one signal conductor comprises an isolating coating. Since all ground conductor have the same electrical potential it is not necessary to distinguish them. The isolating coating allows with e. g. different colours the

identification of equal signal conductors on opposed ends of the electrical signal cable.

In a preferred embodiment at least the electrical signal conductor is of the type AWG 30 or smaller diameter Depending on the actual application of the electrical signal cable the number of electrical conductors, especially signal conductors and ground conductorsis between 64 and 512.

Good and stable electrical properties of the electrical signal cable are achieved by that the signal conductors are arranged in at least one layer and the at least one ground conductor is arranged in at least one other layer of the Electrical signal cable. In a preferred embodiment the signal conductor layer and/or the ground conductor layer is braided or surfed around a central axis. In another preferred embodiment at least one signal conductor layer and at least one ground conductor layer are stacked on each other.

In a preferred embodiment at least one signal conductor layer is cylindrically arranged around a central axis, said at least one signal conductor layer comprises a plurality of flat cables, each of said flat cables having a plurality of coplanar electrical signal conductors encased within and separated at a pitch distance (a) from each other by a flat cable insulator. The cylindrical arrangement of the flat cables around the central axis of the assembly allows the assembly to bend easily in multiple directions and thus any sensor device, such as an ultrasound probe, can be easily put into a position by an operator. The cylindrical arrangement of the flat cables furthermore ensures a high flex life since any stresses within the electrical signal cable are distributed over the whole of the electrical signal cable rather than being concentrated in certain longitudinal planes.

In one preferred development of the invention, the flat cables are cylindrically braided about the central axis and in a further embodiment of the invention the flat cables are cylindrically surfed or wrapped about the central axis. In order to ensure that the signal conductors within the electrical signal cable are shielded from interfering magnetic fields, an outer shield is disposed about said at least one signal conductor layer.

A plurality of said at least one signal conductor layers can be cylindrically arranged around a

central axis and in such a case are preferably separated from each other by the at least one ground conductor in the type of a separating cylindrical shield. The use of a plurality of flat cables within the electrical signal cable, each of which contains a limited number of signal conductors, has the advantage that flexlife and handling of the electrical signal cable is improved since each of the flat cables has a degree of freedom to move within the assembly.

The separating cylindrical shield is used to shield the signal conductor layers from one another such that the stray electromagnetic fields created by signals in the individual signal conductors of one signal conductor layer do not interfere with the signals in the individual signal conductors of a further signal conductor layer. Furthermore the separating cylindrical shield as the at least one ground conductor serves as a reference impedance potential.

A tubular spacer is disposed within said at least one signal conductor layer and serves as a filler or stabiliser about which the flat cables are cylindrically arranged. The tubular spacer is constructed from a solid material, from a stranded material or is in the form of a hollow tube. In the latter case the interior of the tubular spacer can carry fluids or further electric leads, for example for control signals or power. Preferably an inner cylindrical shield is disposed between the tubular spacer and the at least one signal conductor layer to provide further protection against interfering electromagnetic fields when the interior of the tubular spacer carries further electric leads and also acts as a reference ground potential.

In another improvement of the invention an outer cylindrical shield is disposed between an outer one of said at least one signal conductor layer and the outer ground shield and is separated from the outer ground shield by a first insulation layer. A second insulation layer is further disposed between said outer ground shield and a jacket. These shields, insulation layers and outer jacket protect the interior of the electrical signal cable from mechanical damage and also from external interfering magnetic fields.

The flat cables in the electrical signal cable are constructed from an upper insulator attached to a lower insulator which are, in the preferred embodiment of the invention, laminated to each other. In another embodiment of the invention, the upper insulator is adhered to the lower insulator by an adhesive which is selected from the group of thermoplastic adhesives comprising polyester or polyurethane. Furthermore a coating of adhesion promoters made from fluorinated copolymers, such as fluorinated ethylene/propylene and perfluoroalkoxy, from

epoxy resin adhesives, from amino resin adhesives, from phenolic resin adhesives or from silicone adhesives can be used to bond the layers together.

The insulator is formed from the group of insulating materials consisting of polyester, perfluoralkoxy, fluoroethylene-propylene, polyolefins including polyethylene and polypropylene, polymethylpentene, polytetrafluoroethylene or expanded polytetrafluorethylene.

Preferably a fluoropolymer is used and most preferably the upper insulator and the lower insulator are formed from expanded polytetrafluorethylene (ePTFE). Expanded PTFE has a very low dielectric constant and is light in weight. This ensures that the electrical properties of the assembly are extremely good and also that the electrical signal cable constructed using an ePTFE dielectric material is light in weight which allows for easy handling of the cable.

Furthermore the flexlife properties of cables made from ePTFE are known to be good and thus the assembly constructed using this dielectric material also has good flexlife properties. The assembly could also be constructed using an extruded polymer or a foamed polymer.

In another preferred embodiment if the invention a plurality of signal conductor layers are stacked on each other, each signal conductor layer comprising a plurality of coplanar electrical signal conductors encased within an insulator and being separated from each other by a first pitch distance (a), whereby the first pitch distance (a) is between 0,1 mm and 10 mm and the characteristic impedance of the electrical signal cable is in the range of 50 Q to 200 Q.

In one improvement of the invention, the electrical signal cable is constructed with the insulator comprising an upper insulator attached to a lower insulator by means of a lamination bonding.

This method of manufacture is comparatively simple and allows the manufacture of a long lengths of cable assembly in a comparatively short period of time.

Preferably the upper insulator and the lower insulator are formed from the group of insulating materials consisting of polyethylene, perfluoralkoxy, fluoroethylene-propylene, polypropylene, polymethylpentene, polytetrafluoroethylene or expanded polytetrafluorethylene and more preferably they are formed from expanded polytetrafluorethylene (ePTFE). Expanded PTFE has a very low dielectric constant and dissipation and accordingly provides electrical signal cables with very good electrical performance.

In a further development of the invention, a shielding strip is situated between at least two of said signal conductor layers to electromagnetically shield the signal conductors in one signal conductor layer from the signals being carried on the signal conductors in another one of the signal conductor layers. Using the shielding strip, the cross-talk between the signal conductors in two adjacent signal conductor layers is reduced to more than acceptable levels. The shielding strip can be attached to the insulators by lamination bonding.

In a further improvement of the invention, first shielding means surrounding said signal conductor layers are provided in electrical contact with at least one end of the said shielding strips. The ends of the shielding strips are thus mechanically protected from damage and can also not act as antennas. Furthermore, an insulating layer can be provided which surrounds said first shielding means and then second shielding means are provided surrounding said insulating layer. The second shielding means shield the signal conductors within the signal conductor layers from stray electromagnetic fields outside the electrical signal cable. A cable jacket is then placed over the second shielding means surrounding said signal conductor layers to protect the complete electrical signal cable assembly from mechanical damage.

In one embodiment of the invention, at least one spacer is disposed within the cable jacket for shaping the electrical signal line, i. e. for holding the signal conductor layers in place within the cable jacket. The signal conductor layers can be arranged substantially in parallel planes to each other in which case two crescent-shaped spacers are provided. The signal conductor layers can also be arranged helically around the spacer in which case the spacer is cylindrical in shape.

Description of the Drawings Fig. 1 shows a preferred embodiment of an electrical signal cable of the invention in cross section with different embodiments of signal conductors and ground conductors.

Fig. 2 shows another preferred embodiment of an electrical signal cable in cross section.

Fig. 3 shows an electrical signal cable of the invention in perspective view.

Fig. 4 shows another embodiment of the electrical signal cable assembly of the invention.

Fig. 5 shows a cross section of a flat cable used in the inventive electrical signal cable.

Fig. 6 shows a method of manufacturing the plurality of signal conductor layers for the inventive electrical signal cable.

Fig. 7 shows a sintering device used in the manufacture of the signal conductor layers.

Fig. 8 shows a diagram of an apparatus for testing the flexlife of the electrical signal cable.

Fig. 9 shows a further embodiment of the invention.

Fig. 10 shows a further embodiment of the invention.

Fig. 11 shows a further embodiment of the invention.

Fig. 12 shows the electrical signal cable according to a another preferred embodiment of the invention.

Fig. 13 shows a method for the manufacture of the electrical signal cable of Fig. 12.

Fig. 14 shows the electrical signal cable according to another embodiment of the invention.

Fig. 15 shows the electrical signal cable according to another embodiment of the invention.

Fig. 17 shows a further example of a signal conductor layers suitable for use in the invention.

Fig. 18 shows a further embodiment of the electrical signal cable of the invention.

Detailed Description of the Invention The first preferred embodiment of an electrical signal cable 10 of the invention shown in Fig. I includes several electrical conductors of type I to 4 which are arranged on respective circles and which are surrounded by a jacket 5 which is for example made from expanded PTFE (GORE-TEX@). Each electrical conductor 1 to 4 is a signal conductor or a ground conductor or an assembly of at least one signal conductor and at lest one ground conductor. It is important to note that the term"conductor"used herein is not limited to round wires but should also include any geometric type of wire, such as for example plain conductors, flat conductors, shield conductors, net shaped conductors, braided shield conductors, foil type conductors,

hollow conductors or braided conductors in different cross section geometry's, such as for example edged, triangle, quarter type and so forth.

The electrical conductors designated with 1 to 4 show different examples for assemblies including one signal conductor and one ground conductor. Electrical signal conductor I includes one signal conductor and one ground conductor arranged as twisted pair. Electrical signal conductor 2 includes one signal conductor and one ground conductor arranged as ribbon pair. Electrical signal conductor 3 includes one signal conductor and one ground conductor in a coaxial arrangement without an outer jacket. Electrical signal conductor 4 includes one signal conductor and one ground conductor, wherein the signal conductor 4a includes an insulating jacket whereas the ground conductor 4b is a plain wire, also called drainwire.

In another embodiment shown in Fig. 2 all round electrical conductors 7 are signal conductors with an isolating jacket similar to signal conductors 4a of the embodiment according to Fig. 1.

Instead of ground conductors 4b there is provided at least one shield conductor 8 circular shaped in cross section. This circular ground conductor 8 shield inner signal conductors from outer signal conductors. As far as necessary further circular ground conductors can be provided for building further compartments including respective signal conductors 7.

In the following with reference to Figs. 3 to 11 there are described several preferred embodiments of an electrical signal cable of the invention, wherein at least one signal conductor layer is cylindrically arranged around a central axis, said at least one signal conductor layer comprises a plurality of flat cables, each of said flat cables having a plurality of coplanar electrical signal conductors encased within and separated at a pitch distance (a) from each other by a flat cable insulator. The signal conductors and at least one ground conductor are arranged in different layers, wherein the signal conductors are arranged in several flat cables. The signal conductor layer is also called subcable assembly.

Figs. 3 and 4 show a cylindrical electrical signal cable assembly 10 according to the invention having a central axis 15. The term cylindrical used in this context does not imply that the assembly be geometrically cylindrical. Rather an assembly 10 whose dimensions are substantially cylindrical is also covered. Such an assembly 10 could be formed when outside forces exert pressure on the surface of the assembly 10 and"squash"one side of the assembly

10 to form an assembly 10 with an oval cross-section. In all figures, like numerals are used to denote like elements.

The assembly 10 comprises an optional tubular spacer 20 forming the central core of the assembly 10. The tubular spacer 20, if present, is surrounded by a cylindrically arranged inner cylindrical shield 30 onto which is disposed a first signal conductor layer 40. The structure of the signal conductor layer 40 will be described later. The tubular spacer 20 is made from permeable ePTFE, PTFE, polyamide, polyurethane, persion or any other suitable material. The tubular spacer 20 may be solid or have a hollow interior to carry cooling fluids, electrical control lines, electrical power lines, gases etc. The tubular spacer 20 may further be made from a braided or stranded material.

In the embodiment of the invention depicted in Figs. 3 and 4, the first signal conductor layer 40 is disposed within a second signal conductor layer 60 and is separated from the second signal conductor layer 60 by a separating ground conductor in the form of a cylindrical shield 50. The second signal conductor layer 60 has the same structure as the first signal conductor layer 40. It is possible to conceive of an embodiment of the invention in which no further signal conductor layer are present. It is also possible to conceive of an embodiment in which further signal conductor layer are disposed about the second signal conductor layer 60 and separated from the second signal conductor layer 60 by further separating cylindrical shields.

An outer cylindrical shield 70 is disposed about the outermost one of the signal conductor layers 40,60. In the embodiment of Figs. 3 and 4 the outer cylindrical shield 70 is disposed about the second signal conductor layer 60. A first insulating layer 80 is arranged about the outer cylindrical shield 70 and on this is disposed an outer shield 90. The outer shield 90 is grounded and shields the signal conductor layers 40,60 within the assembly 10 from interfering electromagnetic fields. A second insulating layer 100 is disposed about the outer ground shield 90 and the electrical signal cable 10 is then placed within a jacket 110.

The first insulating layer 80 and the second insulating layer 100 are made, for example, from PTFE, ePTFE, FEP or polyester. Preferably the first insulating layer 80 and the second insulting layer 100 are made from sintered GORE-TEX tape which is obtainable from W. L. Gore & Associates and is wrapped about the electrical signal cable 10 using known wire-wrapping

techniques.

The inner cylindrical shield 30 and the separating cylindrical shield 50 are braid, foil, surfed, woven or wire shields made from a metal or a metallised polymer, such as copper, aluminium, tin-plated copper, silver-plated copper, nickel-plated copper, alloys or a metallised fabric such as an aluminised polyester. Later embodiments of the invention will be described in which no inner cylindrical shield 30 or separating cylindrical shield 50 are present.

The outer ground shield 90 is a braid, foil or wire shield made from a metal or a metallised polymer, such as copper, aluminium, tin-plated copper, silver-plated copper, nickel-plated copper, alloys or aluminised polyester. In one embodiment of the invention, the outer ground shield 90 is made from a copper braid with a braiding angel of about 35°. In some applications, the outer ground shield 90 can be omitted.

The jacket 110 is made from silicone or polyolefins such as polyethylene, polypropylene or polyethylpentene; fluorinated polymers such as fluorinated ethylene/propylene (FEP); fluorinated alkoxypolymer such as perfluoro (alkoxy) alkylanes, e. g. a co-polymer of TFE and perfluorproplyvinyl ether (PFA); polyurethane (PU), polyvinylchloride (PVC), silicone, polytetralfluoroethylene (PTFE) or expanded PTFE. In one embodiment of the invention the jacket 110 was made from PVC. In a further embodiment of the invention the jacket is made from ePTFE reinforced with silicone.

As can be seen by close inspection of Fig. 3 the first signal conductor layer 40 and the second signal conductor layer 60 are made from a plurality of flat cables 45 which are braided together in a first embodiment of the invention. Braiding techniques are known in the art and suitable machines are available from Ratera in Manresa, Spain, SPIRKA Maschinenbau GmbH in Alfeld (Leine), Germany, Magnatech International, Inc., in Sinking Spring, USA, and Steeger GmbH & Co., Wuppertal, Germany.

In the second embodiment of the invention depicted in Fig. 4, the first signal conductor layer 40 and the second signal conductor layer 60 are formed respectively from two layers 42a and 42b and 62a and 62b respectively. Each of the two layers 42a, 42b, 62a, 62b is formed of one or a plurality of flat cables 45 which are wrapped or surfed in opposite directions around the

electrical signal cable 10. Surfing the flat cables 45 in opposite directions has the advantage that cross-talk between the individual signal conductors 130 in the different flat cables 45 is reduced. A first one of the layers 42a, 62a is wrapped in a first direction. A second one of the layers 42b, 62b is wrapped in a second direction as shown in the Fig. Wrapping techniques are known in the art and suitable machines are available from Ridgeway & Co., Leicester, UK, Roblon, Denmark, Innocable, France or Stolberger, Germany.

Fig. 5 shows a cross-sectional view of the flat cable 45. The flat cable 45 is made up of a plurality of individual signal conductors 130 arranged in a parallel plane and surrounded by an upper insulating layer 120a and a lower insulting layer 120b. In this example sixteen individual signal conductors 130 are shown spaced at a pitch distance a of 0. 35 mm. However, this is not limiting of the invention and different pitch distances a of number of individual signal conductors 130 could be used. The upper insulating layer 120a and the lower insulating layer 120b are laminated together as will be explained later. Whilst the flat cable 45 is shown in this embodiment as being laminated, it would be possible to use extrusion techniques to extrude the individual signal conductors 130 for example within a polyurethane, an FEP-based or a polyester layer. Alternatively foamed or solid polyethylene could be used. Furthermore the upper insulating layer 120a and the lower insulating layer 120b could be adhered together using a thermoplastic adhesive such as a polyester adhesive or a polyurethane adhesive.

The individual signal conductors 130 can be made from any conducting material such as copper, nickel-plated copper, tin-plated copper, silver-plated copper, tin-plated alloys, silver- plated alloys or copper alloys. The individual signal conductors 130 may be lacquered.

Preferably the individual signal conductors used in the invention are made from round alloy wire. It would also be possible to use flat conductors. The number of individual signal conductors 130 depicted in Fig. 5 is not intended to limiting of the invention. The axes of the individual signal conductors 130 are separated by a first pitch distance a which is in the range of 0,1 to 10 mm. The upper insulating layer 120a and the lower insulating layer 120b can be made of any insulating dielectric material such as polyethylene, polyester, perfluoralkoxy, fluoroethylene-propylene, polypropylene, polymethylpentene, polytetrafluoroethylene or expanded polytetrafluorethylene. Preferably expanded polytetrafluoroethylene such as that described in US-A-3 953 556, US-A-4 187 390 or US-A-4 443 657 is used.

Manufacture of the flat cable 45 is illustrated in Fig. 6 for the embodiment in which the upper insulating layer 120a and the lower insulating layer 120b are made from expanded PTFE. This method is essentially the same as that taught in US-A-3082292 (Gore). A plurality of individual signal conductors 130, an upper insulator 120a located above the plurality of individual signal conductors 130, and a lower insulator 120b located below the plurality of individual signal conductors 130 were communally passed between two heated contra-rotating pressure rollers 400a and 400b at a lamination temperature sufficient to achieve bonding between the lower insulator 120b and the upper insulator 120a, e. g. between 327°C and 410 °C. The flat cable 45 was thereby formed. For this purpose, the upper pressure roller 400a is provided with a number of upper peripheral grooves 410a each separated by an upper peripheral rib 420a which are lined up at a distance from one another along the circumference of the pressure rollers 400a. Similarly, the lower pressure rollers 400b is provided with a number of lower peripheral grooves 410b each separated by a lower peripheral rib 420b which are lined up at a distance from one another along the circumference of the pressure roller 400b. Each upper peripheral groove 41 Oa of the upper pressure roller 400a together with the adjacent upper peripheral ribs 420a lines up with one of the lower peripheral grooves 41 Ob with the adjacent lower peripheral ribs 420b of the lower pressure roller 400b to form a passageway channel for one of the electrical signal conductors 130. The distances (a) between the two pressure rollers 400a, 400b and the peripheral grooves 410a, 41 Ob are designed in terms of their dimensions in such a way that a single conductor 410 and the upper insulator 420a and the lower insulator 420b pass continuously between a pair consisting of one of the upper peripheral grooves 41 Oa and one of the lower peripheral grooves 41 Ob. The upper peripheral ribs 420a and the lower peripheral ribs 420b have such a small separation from one other that the upper insulator 420a and the lower insulator 420b are firmly pressed together at these positions to form an intermediate zone 440 in the flat cable 45.

In order to improve their adhesion of the upper insulator 120a to the lower insulator 120b to the individual signal conductors 130 and with each other within the flat cable 45, the flat cable 45 was led through a sintering device in which the flat cable 45 is heated such that one achieves intimate joining in the intermediate zones 140 of the flat cable 45. If using an upper insulator 120a and a lower insulator 120b made of PTFE, use is made of a sintering temperature in the range from 327° to 410°C.

An example of an embodiment of a sintering device in the form of a sintering oven 150

comprising a salt bath is illustrated in a schematic and simplified form in Figure 7. In this example flat cable 45 is continually passed through the sintering oven 150.

Flex-life measurements are made using an apparatus as shown in Fig. 8. A one meter long sample of the electrical signal cable 10 to be tested is attached to a movable attachment 520 and hung with a weight 540 of 500g. The movable attachment 520 could swing a 30 cm long first end 525 of the electrical signal cable assembly 10 through an angle of 90° as shown by the arrow in Fig. 8. The bending radius was 50 mm. A cycle counter 530 is used to count the number of cycles through which the first end 525 of the electrical signal cable 10 was swung, i. e. from the zero, upright position to +90°, back to the zero position, to the-90° position and then back to the zero position. Stops 510a, 51 Ob prevent the other end of the electrical signal cable 10 from being swung. A measurement of the ohmic resistance of the individual signal conductors 130 within the electrical signal cable 10 was carried out by connecting sixteen individual signal conductors 130 in one flat cable 45 in parallel with each other. Eight flat cables 45 were connected in series with each other. The total ohmic resistance of the electrical signal cable assembly 10 comprising eight flat cables 45 each with sixteen individual signal conductors 130 was measured at the beginning of the measurement cycles and then the number of measurement cycle carried out until the ohmic resistance had increased by 10%. A maximum of 180 000 cycles was, however, carried out and then by plotting the results obtained to the end of the measurement, the number of cycles required to increase the ohmic resistance by 10% was calculated by plotting a curve on the graph. The measurements are carried out at a temperature of 222°C. Further details of the test are found in German National Standard DIN 0472 603 test F.

In the forgoing the layers 40 and 60 and the flat cable 45 are described as including only electrical signal conductors. However, in other not shown embodiments it is also possible, that such a layer 40,60 or such a flat cable 45 also includes electrical ground conductors which separate one ore more electrical signal conductors from each other. This is for example possible by just connecting some of the electrical signal conductors of one layer or one flat cable to ground potential. Such an arrangement of electrical signal and ground conductors in one layer or one flat cable includes for example alternating electrical signal conductors (S) and electrical ground conductors (G) shortly named as GS-arrangement. In other embodiments there are arrangement such as GSGGSGGSG.... or GSSGGSSG.... or... GSGSGS... realised. In this

context it is important to note, that such a flat cable with different alternating arrangements of G and S alone already builds up an electrical signal cable of the invention.

In the following with reference to Figs. 12 to 19 there are explained other preferred embodiments of an electrical signal cable of the invention wherein a plurality of signal conductor layers 1020,1120,1220,1320,1620,1720 are stacked on each other, each signal conductor layer 1020,1120,1220,1320,1620,1720 comprising a plurality of coplanar electrical signal conductors 1330,1630,1730 encased within an insulator 1040a, 1040b and being separated from each other by a first pitch distance a. Again each stack can additionally include ground conductors, whereby ground conductors in the form of layers 1050,1150,1250,1650,1750 between each stack can be partly or completely omitted.

Fig. 12 shows another embodiment of the invention. It shows an electrical signal cable 1 O 10 comprising a plurality of subcable assemblies or signal conductor layers 1020. In Fig. 12 eight signal conductor layers 1020 are shown. However, this is merely illustrative of the invention and not intended to be limiting.

Each signal conductor layers 1020 comprises a plurality of individual signal conductors 1030 arranged in a parallel plane and surrounded by an upper insulating layer 1040a and a lower insulating layer 1040b. The upper insulating layer 1040a and the lower insulating layer 1040b are laminated together as will be explained later. The individual signal conductors 1030 can be made from any conducting material such as copper, nickel-plated copper, tin-plated copper, silver-plated copper, tin-plated alloys, silver-plated alloys or copper alloys. Preferably the individual signal conductors 1030 are made of round copper wire. It would also be possible to use flat conductors.

The number of individual signal conductors 1030 depicted in Fig. 12 is not intended to limiting of the invention. The axes of the individual signal conductors 1030 are separated by a first pitch distance a which is in the range of 0,1 to I mm. The upper insulating layer 1040a and the lower insulating layer 1040b can be made of any insulating dielectric material such as polyethylene, polyester, perfluoralkoxy, fluoroethylene-propylene, polypropylene, polymethylpentene, polytetrafluoroethylene or expanded polytetrafluorethylene. Preferably expanded polytetrafluoroethylene such as that described in US-A-3 953 556, US-A-4 187 390 or US-A-4

443 657 is used.

The signal conductor layers 1020 are separated from each other by a shielding strip 1050. The shielding strip 1050 is made for example from a metal foil, metal braid, conductive tape or a metallised textile. The following metals can be used: copper, tin, silver, aluminium or alloys thereof. In one embodiment of the invention the shielding strip 1050 was made from copper- coated polyamide fabric of the Kassel-type type supplied by the Statex company in Hamburg, Germany, and had a thickness of approximately 0,1 mm and a width of around 9 mm.

The signal conductor layers 1020 were arranged in a planar manner, one above another, to form a bundle of signal conductor layers 1020 using the apparatus 1100 shown diagramtically in Fig.

13.

Fig. 13 shows a plurality of first spools 1102 onto which is rolled a first strip 1103 forming the signal conductor layers 1020 and a plurality of second spools 1104 onto which is rolled a second strip 1105 forming the shielding strip 1050. A plurality of first (subcable assembly or signal conductor layer) strips 1103, separated from each other by a second (shielding) strip 1105 is rolled respectively off the plurality of first spools 1102 and the plurality of second spools 1104 and joined together at position 1106 to form a bundle 1107.

The thus created bundle 1107 of signal conductor layers 1020 was slid into a tube which forms a first shielding means 1060. The first shielding means 1060 may be made of a metal foil, such as a foil made from copper, aluminium or silver, or from metallised textile. In one embodiment of the invention the first shielding means was made from Kassel copper-coated polyamide fabric supplied by the Statex company in Hamburg, Germany, and had a thickness of approximately 0,1 mm and a width of around 9 mm. Crescent-shaped Spacers 1090 were positioned between the plurality of subcable assemblies 1020 and the first shielding means 1060 in order to maintain a substantially tubular shape. The spacers 1090 are made from permeable ePTFE, PTFE, polyamide, perlon or any other insulating material.

Shielding strip ends 1055 project beyond an edge 1025 of the subcable assemblies 1020 and are bent downwardly or upwardly such that each shielding strip end 1055 touches another one of the shielding strip ends 1055. At least one of the shielding strip ends 1055 is in electrical

contact with the first shielding means 1060. In Fig. 12, the shielding strip ends 1057 of the outermost ones of the plurality of signal conductor layers 1020 and the signal conductor layers 1020 immediately adjacent to the outermost ones of the signal conductor layers 1020 is shown as being in electrical contact with the first shielding means 1060. Each of the shielding strips 1050 and the first shielding means 1060 are therefore held at the same potential. It would, of course, be possible to hold the shielding strips 1050 and the first shielding means 1060 at a different potential. In this latter case the shielding strip ends 1055 would not electrically contact with the shielding means 1060.

An insulating layer 1065 was then wrapped around the first shielding means 1060 using known wire wrapping techniques. The insulating layer 1065 may be made, for example, from PTFE, FEP, ePTFE or polyester. Preferably the insulating layer 1065 is made from sintered GORE- TEX) tape which is obtainable from W. L. Gore & Associates.

A second shielding means 1070 surrounds the first shielding means 1060. The second shielded means 1070 is a braid, foil or wire shield made from a metal or a metallised polymer, such as copper, aluminium, tin-plated copper, silver-plated copper, nickel-plated copper or aluminised polyester. In one embodiment of the invention the second shielding means 1070 is made from a copper braid with a braiding angle of about 35°.

A jacket 1080 is placed over the second shielding means 1070. The jacket 1080 is made from silicone or polyolefins such as polyethylene, polypropylene or polyethylpentene; fluorinated polymers such as fluorinated ethylene/propylene (FEP); fluorinated alkoxypolymer such as perfluoro (alkoxy) alkylanes, eg. a co-polymer of TFE and perfluorproplyvinyl ether (PFA); polyurethane, polyvinylchloride (PVC) or polytetralfluoroethylene (PTFE) or expanded PTFE.

In one embodiment of the invention the jacket 1080 was made from PVC.

Another embodiment of the invention is shown in Fig. 14. In this figure, the same reference numerals are used to denote components of the electrical signal cable 1110 having the same function as the components of the electrical signal cable 1010 of Fig. 12 except that the numerals are increased by 100. In this embodiment of the invention a tubular spacer 1190 is used in the core of the electrical signal cable 1110 and the signal conductor layers 1120 are wrapped in a helical manner with an axis through the core 1200 of the electrical signal line

1110. The materials used for the construction of this embodiment of the electrical signal cable 1110 are the same as those used above.

This embodiment of the electrical signal cable 1110 has the advantage that it is substantially more flexible than the foregoing embodiment 1010.

A further embodiment of the electrical signal cable 1210 is shown in Fig. 15. Again the same reference numerals are used to denote components of the electrical signal cable 1210 having the same function as the components of the electrical signal line 10 of Fig. 12 or the electrical signal cable 1110 of Fig. 13 except that the numerals are increased by a further 100. In this embodiment of the electrical signal line, the plurality of signal conductor layers 1220 are twisted before being placed within the first shielding means 1270 thus obtaining a substantially more flexible electrical signal cable 1210. Again the same materials are used for the construction of this electrical signal cable 1210 as are described in the embodiment of Fig. 12.

Fig. 18 shows a further example of a signal conductor layer 1620 which comprises a plurality of individual signal electrical signal conductors 1630 arranged in a parallel plane and surrounded by an upper insulating layer 1640a and a lower insulating layer 1640b. The signal conductor layer 1620 further included an upper shielding means 1650a and a lower shielding means 1650b attached to the outer surfaces of the upper insulting layer 1640a and the lower insulating layer 1640b, respectively. The upper shielding means 1650a and the lower shielding means 1650b can be made, for example, from copper or aluminium foil, perforated copper foil or metallised polyamide. In the preferred embodiment they are made from copper foil. The upper shielding means 1650a and the lower shielding means 1650b are joined to each other at ends 1660a and 1660b as show in Fig. 18. A jacket 1680 made from ePTFE was attached to the upper shielding means 1650a and the lower shielding means 1650b. The jacket 1680 could also be made from PFA, FEP or PTFE.

Manufacture of the embodiment of the signal conductor layer 1620 depicted in Fig. 18 is carried out in a similar manner as the signal conductor layer 1320 described above and depicted in Fig. 7.

In addition to the upper insulator 1340a and the lower insulator 1340b being passed through the contra-rotating pressure rollwer 1400a and 1400b at a lamination temperature, the material to form the upper shielding means 1650a, the lower shielding means 1650b and the jacket 1680 are

additionally passed through contra-rotating pressure rollers at a temperature sufficient to ensure that the upper shielding means 1650a and the lower shielding means 1650b are laminated to the upper insulating 1640a and the lower insulator 1640b and to each other at the ends 1660a, 1660b.

Use of the laminated upper shielding means 1650a and the lower shielding means 1650b allows the construction of an electrical signal cable 1010 with a plurality of subcable assemblies orsignal conductor layer 1620 without a shielding strip 1050 placed between the signal conductor layer 1620.

Examples Example 1 This was constructed as shown in Fig. 3. The tubular spacer 20 was made of a polyurethane tube and had an outer diameter of 4.0 mm. The inner cylindrical shield 30 (outer diameter 4.4 mm), the separating cylindrical shield 50 (outer diameter 6.0 mm) and the outer cylindrical shield 70 (outer diameter 7.6 mm) were made of a copper-plated polyamide fabric supplied by the Statex company of Bremen, Germany under the trade name KASSEL. The first signal conductor layer 40 (outer diameter 5.6 mm) and the second signal conductor layer 60 (outer diameter 7.2 mm) were both made from four flat cables 45 each containing sixteen individual signal conductors 130 of AWG 4007 made from PD 135 alloy obtainable from Fhelps Dodge in Irvine, California, at a pitch distance of 0. 35 mm laminated between ePTFE with a dielectric constant of 1.3. These were braided at a braiding angle of 20-22°. The first insulation 80 (outer diameter 7.7 mm) and the second insulation 100 (outer diameter 8.2 mm) were made of an ePTFE GORGE-TEX binder available from W. L. Gore & Associates. The outer shield 90 was made from braided bare alloy wire constructed with a braiding angle of approx. 40° using 36 bobbins with eight ends at 10 picks/inch (2.54 cm). The jacket 110 was made from PVC and had an outer diameter of 10.0 mm.

Flexlife tests carried out on the electrical signal cable array showed that the ohmic resistance increased by 10% between only 6000 and 60 000 cycles. This was thought to be due to the extremely sharp braiding angle of the subcable assemblies 40 and 60.

Example 2 This was constructed as shown in Fig. 4. The tubular spacer 20 was made of a ePTFE joint sealant filler (JSF 50) obtainable from W. L. Gore & Associates, Putzbrunn, Germany, having an outer diameter of 4.0 mm. The inner cylindrical shield 30 (outer diameter 4.4 mm), the separating cylindrical shield 50 (outer diameter 6.0 mm) and the outer cylindrical shield 70 (outer diameter 7.6 mm) were made of a copper-plated polyamide fabric supplied under the trade name KASSEL by the Statex company of Bremen, Germany. The first signal conductor layer 40 (outer diameter 5.6 mm) and the second signal conductor layer 60 (outer diameter 7.2 mm) were both made from two flat cables 45 each containing 32 individual signal conductors 130 of AWG 4207 made from PD135 alloy at a pitch distance of 0. 35 mm laminated between ePTFE with a dielectric constant of 1.3. The first layers 42a, 62a of the first and second signal conductor layer 40,60 were formed from one of the flat cables 45. The second layers 42b, 62b of the first and second signal conductor layer 40,60 were formed from the other one of the flat cables 45. These were wrapped at a wrapping angle of 40°. The first insulation 80 (outer diameter 7.7 mm) and the second insulation 100 (outer diameter 8.2 mm) were made of an ePTFE GORE-TEX binder available from W. L. Gore & Associates. The outer shield 90 (outer diameter 8.1 mm) was made from braided bare alloy wire with a braiding angle of 40°.

The jacket 110 was made from silicone-reinforced ePTFE obtainable from W. L. Gore & Associates, Phoenix, Arizona, under the name SILKORE and had an outer diameter of 10.5 mm.

Flexlife tests carried out on the electrical signal cable array showed that the ohmic resistance increased by 10% after between 25 000 and 110 000 cycles. The capacitance between one of the individual signal conductors 130 and the outer shield 90 was 57 pF/m.

Example 3 This is constructed as shown in Fig. 9. This example has a first signal conductor layer 40 which is identical to the first signal conductor layer of Example 2 and having an outer diameter of 5.6 mm. The example has, however, two second signal conductor layer 60'and 60"each containing flat cables 45 with forty-eight individual signal conductors 130 of AWG 4207 laminated in the same manner as the flat cables 45 of example 2 and separated by a further cylindrical separating

shield 50'. The outer diameter of the first one of the second signal conductor layer 60'has an outer diameter of 7.4 mm and the second one of the second signal conductor layer 60"has an outer diameter of 9.0 mm. The further cylindrical separating shield 50'has an outer diameter of 7.8 mm.

As a result of the incorporation of the two second signal conductor layer 60'and 60", the outer diameter of some of the outer layers of the electrical signal cable 10 changes as follows. The outer cylindrical shield 70 has an outer diameter of 9.4 mm, the first insulation 80 had an outer diameter of 9.5 mm and the second insulation 100 had outer diameter of 9.9 mm whilst the outer shield's 90 outer diameter was 9.8. Finally the jacket 110 had an outer diameter of 11.4 mm.

In this example an electrical signal cable 10 with 256 individual signal conductors 130 is formed.

Example 4 This was constructed as shown in Fig. 10. The tubular spacer 20 was made of an ePTFE joint sealant filler (JSF50) obtainable from W. L. Gore & Associates with an outer diameter of 4.0 mm. In contradistinction to Example 1, there was no inner cylindrical shield 30, separating cylindrical shield 50 and outer cylindrical shield 70. A first signal conductor layer 40'and two second signal conductor layer 60'and 60"were both made from four flat cables 45 each containing sixteen individual signal conductors 130 made from PD 135 alloy of AWG 4207 at a pitch distance of 0.35 mm laminated between ePTFE with a dielectric constant of 1. 3. These were braided at a braiding angle of approx. 40°. The signal conductor layer 40', 60'and 60"had outer diameter of 5.2 mm, 6.4 mm and 7.6 mm respectively. The outer shield 90 had an outer diameter of 8.0 mm and was made from braided PD 135 alloy wire of AWG 4001 obtainable from Fhelps Dodge in Irvine, California, and was braided using 36 bobbins with eight ends at 10 picks per inch (2.54 cm) with a braiding angle of approx. 35°. The jacket 110 was made from reinforced ePTFE sold under the name SILKORE by W. L. Gore & Associates in Phoenix, Arizona, with a wall thickness of approx. lmm and had an outer diameter of 10.5 mm. The subcable assemblies 40', 60'and 60"together with the outer shield formed a core which was pulled into the jacket 110.

Grounding between individual signal conductors 130 in this example is achieved by using every second individual signal conductor 130 as a ground conductor 130.

Flexlife tests carried out on the electrical signal cable array showed that the ohmic resistance increased by substantially less than 10% after 180 000 cycles at which point the flexlife test was stopped Example 5 This example is identical with that of Example I except that the flat cables 45 made from individual signal conductors of AWG 4207 (0.07 mm diameter) made from PD135 alloy were braided at an angle of 20° and the tubular spacer 20 was made of polyurethane.

Example 6 This example is identical with that of Example 4 except that the flat cables 45 were braided at an angle of 20° and individual signal conductors 130 of AWG 4007 (0.08 mm diameter) made from PD135 alloy were used.

Flexlife tests carried out on the electrical signal cable array 10 showed that the ohmic resistance increased by substantially less than 10% after 240 000 cycles at which point the flexlife test was stopped Example 7 This example was identical with that of Example 4 except that the flat cables 45 were surfed or wrapped at an angle of 20° instead of being braided and individual signal conductors 130 of AWG 4007 (0.08 mm diameter) made from PD135 alloy were used. A polyurethane tube was used as the tubular spacer 20.

Flexlife tests carried out on the electrical signal cable array 10 showed that the ohmic resistance increased by substantially less than 10% after 240 000 cycles at which point the flexlife test was stopped

Example 8 This example was identical with that of Example 2 except that individual signal conductors 130 of AWG 4007 (0.08 mm diameter) made from PD135 alloy were used and a polyurethane tube was used as the tubular spacer 20.

Flexlife tests carried out on the electrical signal cable array showed that the ohmic resistance increased by substantially less than 10% after 180 000 cycles at which point the flexlife test was stopped Example 9 This example is illustrated in Fig. 11. The tubular spacer 20 was made of an ePTFE joint sealant filler (JSF 50) obtainable from W. L. Gore & Associates. The first signal conductor layer 40 was constructed from four flat cables 45, denoted LI, L2, L3 and L4, each containing sixteen individual signal conductors 130 of AWG 4007 (0.08 mm diameter) made from PD 135 alloy at a pitch distance of 0. 35 mm laminated between ePTFE with a dielectric constant of 1.3. The outer cylindrical shield 70 was made from the KASSEL foil obtainable from the Statex company of Bremen, Germany. The first insulating layer 80 was made from an ePTFE GORE- TEXO binder obtainable from W. L. Gore & Associates, Putzbrunn, Germany.

Example 10 This example was identical with that of Example 2 except that a polyurethane tube was used as the tubular spacer 20 and the jacket was made of PVC.

Flexlife tests carried out on the electrical signal cable array showed that the ohmic resistance increased by substantially less than 10% after 180 000 cycles at which point the flexlife test was stopped Example 11 This example was identical with that of Example 2 except that the individual signal conductors

were made of wire of AWG 4007 and the jacket was made of PVC.

Flexlife tests carried out on the electrical signal cable array showed that the ohmic resistance increased by substantially less than 10% after 180 000 cycles at which point the flexlife test was stopped.

Example 12 The construction of this example is depicted in Fig. 19 in which the same reference numerals are used to denote the same feature as those in Fig. 12 except that the numerals are increased by 700.

The individual signal conductors 1730 were made from AWG 4001 silver-plated copper wire and embedded within an upper insulating layer 1740a and a lower insulating layer 1740b of GORE- TEXW tapes made in the Pleinfeld, Germany, plant of W. L. Gore & Associates. Each signal conductor layer 1720 contained sixteen of the individual signal conductors 1730. The pitch distance a between the individual signal conductors was 0.35 mm. Four signal conductor layer 1720 were bundled together on top of each other with no shielding strip 1750 between them to form a signal conductor layer bundle 1725. A pair of signal conductor layer bundles 1725 were then placed together with a shielding strip 1750 made of Kassel copper-coated polyamide fabric supplied by the Statex company. The pair of signal conductor layer bundles 1725 were slipped inside a tube forming the first shielding means 1760 and made of Kassel copper-coated polyamide fabric. One of a shielding strip end 1755 was placed in electrical contact with the first shielding means 1765. An insulating layer 1765 of GORE-TEX (g) insulating tape was subsequently wrapped around the first shielding means 1760. The second shielding means 1770 was made of tin-coated copper braid and a jacket 1780 made from polyvinyl chloride was then slipped over the insulating layer 1765. An electrical signal line cable assembly 1710 containing eight signal conductor layer 1720 and 128 individual signal conductors 1730 was thus obtained.

Example 13 This example was constructed according to the embodiment of the invention as depicted in Fig.

12. The individual signal conductors 1030 were made from AWG 4001 silver-plated copper wire and embedded within an upper insulating layer 1040a and a lower insulating layer 1040b of GORGE-TEX tapes made in the Pleinfeld, Germany, plant of W. L. Gore & Associates. Each

signal conductor layer 1020 contained sixteen of the individual signal conductors 1030. The pitch distance a between the individual signal conductors was 0.35 mm. Eight signal conductor layer 1020 were bundled together on top of each other with a shielding strip 1050 strip made of Kassel- type copper-coated polyamide fabric supplied by the Statex company between each of the signal conductor layer 1020. The shielding strip ends 1055 were placed in electrical contact with the first shielding means 1065. The eight signal conductor layers 1020 were slipped inside a tube made of Kassel copper-coated polyamide fabric forming the first shielding means 1060 and an insulating layer 1065 of GORE-TEXX insulating tape was wrapped around the Kassel fabric. The second shielding means 1070 was made of tin-plated copper braid and a jacket 1080 made from polyvinyl chloride was then slipped over the insulating layer. An electrical signal line cable 1010 containing 8 layers and 128 individual signal conductors was thus obtained.

Example 14 This was manufactured in the same manner and using the same materials as example 13 except that AWG 4207 PD135 alloy wire was used.

Comparative Example 15 As a comparison a conventional flat cable comprising a bundle of 132 miniature co-axial cables was used. The conductors were made of AWG 4207 silver-plated alloy wire, the insulator of ePTFE and the outer conductor of silver-plated copper. A jacket of a fluoropolymer was extruded over the outer conductor. A shield of tin-plated copper was then braided over the bundle of 132 miniature co-axial cables and a jacket tube of PVC was extruded over the braided shield. This electrical signal line assembly is commercially available from W. L. Gore & Associates under the part number 02-07605.

Comparative Example 16 A prior art coaxial round cable having an impedance of 50 Ohm was constructed using a signal conductor of AWG 44 (0,054 mm diameter) with an ePTFE insulation having a dielectric contrant of 1. 3.

Comparative Example 17 A prior art coaxial round cable having an impedance of 80 Ohm wasconstructed using a signal conductor of AWG 44 (0,054 mm diameter) with an ePTFE insulation having a dielectric contrant of 1. 3.

Comparative Example 18 A prior art coaxial round cable having an impedance of 80 Ohm was constructed using a signal conductor of AWG 46 (0.0399 mm diameter) with an ePTFE insulation having a dielectric constant of 1.3.

Further Examples using different dielectric materials Further examples are carried out using the structures taught above but using different dielectric materials with different constants. These require different thickness of the upper inulsation layer 120a and the lower insulation layer 120b when the pitch distance is 0.35 mm. Table 1 illustrates the case when an impedance of the electrical signal cable 10 is designed to be 80 Q. Table 2 illustrates the case when an impedance of the electrical signal cable 10 is designed to be 50 Q.

Table 1 Dielectric constant Dielectric Material AWG size of a Thickness of one of the conductor 130 insulation layers 120a, 120b [mm] 1.4 ePTFE, foamed PE, 4207 0.1 foamed FEP/PFA 2.1 FEP, PFA, PE 42 0,16 3.5 Polyester 42 0,3 1.4 ePTFE, foamed PE, 4007 0.122 foamed FEP/PFA 2.1 FEP, PFA, PE 40 0,193 3.5 Polyester 40 0,363 1.4 ePTFE, foamed PE, 3807 0.1255 foamed FEP/PFA 2.1 FEP, PFA, PE 38 0,24 3.5 Polyester 38 0,44 1.4 ePTFE, foamed PE, 4407 0.076 foamed FEP/PFA 2.1 FEP, PFA, PE 44 0,116 3.5 Polyester 44 0,22 Table 2 Dielectric constant Dielectric Material AWG size of a Thickness of one of the conductor 130 insulation layers 120a, 120b [mm] 1.4 ePTFE, foamed PE, 4207 0.05 foamed FEP/PFA 2.1 FEP, PFA, PE 42 0.066 3.5 Polyester 42 0,11 1.4 ePTFE, foamed PE, 4007 0.053 foamed FEP/PFA 2.1 FEP, PFA, PE 40 0.078 3.5 Polyester 40 0,128 1.4 ePTFE, foamed PE, 3807 0.07 foamed FEP/PFA 2.1 FEP, PFA, PE 38 0.1 3.5 Polyester 38 0,165 1.4 ePTFE, foamed PE, 4407 0.033 foamed FEP/PFA 2.1 FEP, PFA, PE 44 0.048 3.5 Polyester 44 0,08

Cross-Talk (dB/m) Cross-talk measurements were also carried out and are illustrated in the following table. In this table S indicated an individual signal conductors 130 carrying a signal, G an individual signal conductor 130 serving as a ground conductor in the same flat cable 45. x indicates an individual signal conductor 130 separating the individual signal conductors 130 on which the measurements are made. The last six entries in the table illustrate the cross-talk measurements made between individual signal conductors 130 in different layers of flat cables 45. The first three of these entries show the cross-talk between individual signal conductors 130 of different flat cable layers (L1-L2; L1-L3; L1-L4) in which separating cylindrical shields were at ground potential. The last three of these entries show the cross-talk between individual conductors 130 of different flat cable layers (L 1-L2; L1-L3; L1-L4) in which some of the individual signal conductors 130 served as ground conductors. In the case of Examples 1,2,5,8 and 9 the separating cylindrical shields were also at ground potential.

Table 3 Measurement Points Example Number 1 2 4 5 8 9 S-S-20.3-20.4-19.9-20.5-16.8 SxS-24.5-19.2 S x x S-26.4-21.6 xxS-26.8-23.1Sx GSSG-16. 9-22.2-19.7 G S G S-38. 6-32-35. 4 SS: L1-L2-51.4-53.5-46.6-51.8-41.2 SS: L1-L3-48.8-45.6-51.1-43.6-36.1 SS: Ll-L4-49.5-52 GS:L1-L2-50.1-42.2-52.7-53.6-48 GS: L1-L3-51.5-42-42.7 GS:LI-L4-43-50.

Table 4 shows a comparison of the electrical and mechanical properties of the electrical signal line manufactured according to this invention in comparison to the cables of the comparative example, an electrical signal line available from W. L. Gore & Associates.

Table 4 Example 12 Example 13 Example 14 Comparative Examp@ (02-07605) Electrical Properties Impedance ~ 100 # ~ 75 # ~ 100 # 78 # Attenuation @ 5 MHz 1,20 dB/Assy.0,73 dB/Assy. 0,7 dB/Assy. 1,09 dB/Assy. Attenuation @ 10 MHz 1,67 dB/Assy. 0,89 dB/Assy. 1,17 dB/Assy. Velocity of Signal Propagation compared to velocity of light. 81,1% 81,0% 81,0% 76,6% X-talk: Signal/Signal 17,4 dB 20,3 dB 36 dB Subcable1/subcable2 30,1 dB 35,4 dB 36 dB ---------- Subcable1/subcable3 39,4 dB 42,3 dB ---------- Subcable1/subcable4 47,6 dB 44,4 dB ---------- Bundle/Bundle(SC4/SC5) 50,5 dB ---------- ---------- ---------- Mechanical Properties Weight 225 g 237 g ca. 300g Length 2,5 m 2,5 m 2,5 m

The signal/signal value is the cross-talk between any two adjacent electrical signal conductors 1030 in the same signal conductor layer 1020. For example 12, the value for subcablel/subcable2 is the cross talk between two corresponding electrical signal conductors 1730 in two adjacent signal conductor layers 1720 in the same signal conductor layer bundle 1725, i. e. with no shielding strip 1750 between the two adjacent signal conductor layers 1720.

The value for subcablel/subcable3 is the cross talk between two corresponding electrical signal conductors 1730 in two signal conductor layer 1720 separated by one signal conductor layer 1730 in the same signal conductor layer bundle 1725. Similarly, the value for subcablel/subcable4 is the cross talk between two corresponding electrical signal conductors 1730 in two signal conductor layer 1720 separated by two signal conductor layer 1720 in the same signal conductor layer bundle 1725, i. e. the first and last signal conductor layer 1720 in one of the signal conductor layer bundles 1725. The value for the bundle/bundle crosstalk of example 12 is obtained by measuring the cross talk between two corresponding electrical signal conductors 1730 in the signal conductor layer 1720 immediately adjacent to the shielding strip 1750, i. e. the first signal conductor layer 1720 in one of the signal conductor layer bundles 1725 and the last signal conductor layer 1720 in the other of the signal conductor layer bundles 1725.

The cross talk values for examples 13 and 14 are measured in the same manner except, of course, that there is always at least one shielding strip 1050 between the two electrical signal conductors 1030 in the different signal conductor layer 1020. There is no value given for the bundle/bundle cross talk since the signal conductor layer 1020 of examples 13 and 14 are not bundled.

The value for the cross talk given for the comparative example is the value measured between any two adjacent electrical signal conductors.

It can be seen from this table that the electrical signal lines manufactured according to this invention have a much better velocity of signal propagation compared to the comparative example. By suitable choice of electrical signal conductors the cross-talk can be reduced to a value which is at least comparable to that in the comparative example. Indeed in practice it is known that any value greater than 20 dB is acceptable. For the same length of line, the inventive electrical signal lines are substantially lighter, i. e. for 132 lines a weight saving of up to 25% is achievable.

Weight Table 6 shows measurements of a weight per length and respective calculations of a number of examples where the value of weight per length is divided by the capacitance of the electrical signal cable. In example 4 the weight per length was measured at a"virtual single coax" comprising one signal conductor and two adjacent ground conductors.

Table 5 Example No. Weight per length (g/m) Impedance (Ohm) Weight per length per impedance (g/m/Ohm) 1 0. 181 97 0.00187 2 0. 144 57 0.00158 4 0. 2142 125 0.0017 5 0. 144 100 0.00144 930.0019580.181 0. 179 50 0.00358 17 0. 348 80 0. 0044 800,00389180.311

It can be seen from Table 6 thatthe electrical signal cable of the invention has a very low weight per unit length compared to its impedance.