Abstract:
The wiring harness provided herein affords adjustability of the relative orientation between the connecting cable and its interface connector in real time, during field applications. The harness rotates to accommodate varying access angles to the desired test point connector. A cable conduit of the harness can be adjusted vertically relative to the axis of its interface connector, as well. Cable wire integrity is maintained during manipulations of the cable conduit relative to the harness electrical connector and stress on the wires is minimized. The harness can be sealed from moisture and environmental factors. The harness can provide shielding from electromagnetic interference for the cabling housed therein. The present harness is well suited for service in high heat environments in, for example, testing of aircraft systems. A cylinder receives the cabling conduit and swivels within a slotted backshell. Slot configuration can limit the translation of the cable conduit.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application claims priority to U.S. Provisional Application No. 61/863,598, filed 8 Aug. 2013, the entire contents of which are incorporated herein by reference. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates to a wiring harness device and method thereof, and more particularly to a rotatable wiring harness and method thereof. 
     BACKGROUND OF THE INVENTION 
     The present invention relates generally to a wiring harness for cabling. More particularly, the present invention relates to a rotatable wiring harness with respect to a fixed connector. 
     Transferring signals via cables or wires remains a preferred and a reliable mode for many applications, despite the advent of wireless means for transferring signals. Generally, cables are made of electrically conducting materials such as copper, aluminum, etc. and are shielded by an insulating material such as rubber or plastic for protection and safe handling. In some applications both an interfacing connector and a test point connector are flexibly tethered. In other field conditions the test point connector may be in a fixed position. In still other field applications the test point connector may be in a fixed position and in a fixed location, wherein the path for the interfacing connector and cable is congested. The test point location may change or the access path to the same may change. The pathway for the cable, any cable conduit, and the interfacing connector may include obstacles. A same testing interfacing connector may need to gain electrical connection, mating, to different test point connectors, each affording only limited pathways for the connecting cable. Conventionally, different cable to connector orientations are provided by different fixed cable to electrical connector assemblies, shown for example, in  FIGS. 1A and 1B . 
     Cables that are used in high-end sophisticated systems such as satellite electronic harness systems or aircraft systems may be desired to have, and may be required to have, capability to be environmentally sealed or to withstand electromagnetic interference. This requirement may be for on craft system harnesses as well as testing harnesses. 
     While, flexible cabling may be able to conform to the walls of a structure or to avoid obstacles, flexible cables may not be compatible with the subject test point connector. Conventionally, flat cables may be flexible and able to bend. One desirable feature of the flexible cable and testing connector assembly is the manipulations that can be made to the cable in real time, repositioning the cable to fit within the available pathway to the test point connector. As an example, the desired test point connector to which mating of an interface connector is desired may be an avionics system&#39;s test point connector on board an aircraft. Such real time adjustments may be desirable due to a change in the open pathway over time or due to the use of the cable and testing connector with different test point connectors and different respective fixed pathways. 
     Not only the physical pathway but electromagnetic interference generated by aircraft or weapons configurations may also vary across aircraft or within a given aircraft across different plans for use. In addition, in some field application cables may be subjected to high heat conditions. 
     SUMMARY OF THE INVENTION 
     The present invention provides a cable harness that affords real time adjustment of the connecting cable orientation to an interfacing connector. The adjustment is multi-functional and may replace the need for multiple cables for testing of a given aircraft or for testing of multiple aircraft. Further, the cable harness can provide environmental and electromagnetic interference shielding. Embodiments of the present invention may have any of the aspects below. 
     One aspect of the present invention is its capability of re-positioning its connecting cable relative to its interface connector. 
     Another aspect of the present invention is its application in obstructed pathways. 
     Another aspect of the present invention is its application in connection cabling pathways that change from one test period to another test period for a given fixed testing point connector. 
     Another aspect of the present invention is the adjustability of the relative orientation between the connecting cable and its interface connector in real time, during field application. 
     Another aspect of the present invention is that it accommodates varying access angles. 
     Yet another aspect of the present invention that it can be adjusted vertically as well as rotationally. 
     Yet another aspect of the present invention is that it may provide environmental shielding. 
     Still another aspect of the present invention is that it may provide electromagnetic interference shielding. 
     A test kit comprising a cable in accordance with an exemplary embodiment of the present invention may require fewer test cables, lessening the cost and weight of the test kit. 
     Still another aspect of the present invention is that it is readily adjusted to accommodate different physical pathways across different aircraft or across a same aircraft. 
     Yet another aspect of the present invention is that the integrity of the cabling is preserved throughout repeated adjustments. 
     Another aspect of the present invention may be reduced time and labor for electrical testing afforded by the harness adjustability during field applications, or otherwise desired, reconfigurations. 
     Another aspect of the present invention is adjustability in a helical path of the connecting cable to the interface connector. 
     Another aspect of the present invention is adjustability in a direction perpendicular to the face of the interfacing connector. 
    
    
     
       BRIEF DESCRIPTION OF THE FIGURES 
       The detailed description is presented with reference to the accompanying figures. Like numbers across drawings may reference like features and components, but may vary across embodiments. For more complete understanding of the features and advantages of the present invention, reference is now made to the detailed description of the invention along with the accompanying figures, wherein: 
         FIGS. 1A-1B  illustrate a conventional wiring conduit that affords a fixed ninety degree cable to interface connector orientation; 
         FIG. 2A  illustrates a left front perspective view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 2B  illustrates a right back perspective view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 2C  illustrates a side view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 2D  illustrates a top view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 3A  illustrates a right front perspective view of a conduit with conduit connector in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 3B  illustrates a partial top view of a wiring harness showing cross sectional line  3 C- 3 C, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 3C  illustrates a cross sectional view along line  3 C- 3 C in  FIG. 3B  of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 3D  shows an exploded view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 3E  shows a portion of  FIG. 3C  in greater detail, in accordance with a conduit connector to cylinder attachment in an exemplary embodiment of the present invention; 
         FIG. 3F  shows greater detail of a rotational adapter cylinder a cross sectional view, in accordance with an exemplary embodiment of the present invention in greater detail; 
         FIG. 4A  illustrates a left front perspective rotational view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 4B  illustrates an inverted front rotational view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 4C  illustrates a top rotational view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention; 
         FIG. 5A  illustrates a left front perspective view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 5B  illustrates a right front perspective view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 5C  illustrates a side view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 5D  illustrates a top view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 6A  illustrates a right front perspective view of a conduit with conduit connector in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 6B  illustrates a partial top view of a wiring harness showing cross sectional line  6 C- 6 C, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 6C  illustrates a cross sectional view along line  6 C- 6 C in  FIG. 6B  of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 6D  shows an exploded view of a of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 7A  illustrates a left front perspective rotational view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 7B  illustrates an inverted front rotational view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 7C  illustrates a top rotational view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 8A  illustrates a left front perspective view of a wiring harness, in accordance with an exemplary window height embodiment of the present invention; 
         FIG. 8B  illustrates a right front perspective view of a wiring harness, in accordance with an exemplary window height embodiment of the present invention; 
         FIG. 8C  illustrates a side view of a wiring harness, in accordance with an exemplary window height embodiment of the present invention; 
         FIG. 8D  illustrates a top view of a wiring harness, in accordance with an exemplary window height embodiment of the present invention; 
         FIG. 9A  illustrates a right front perspective view of a conduit with conduit connector in accordance with an exemplary window embodiment of the present invention; 
         FIG. 9B  illustrates a partial top view of a wiring harness showing cross sectional line  9 C- 9 C, in accordance with an exemplary window embodiment of the present invention; 
         FIG. 9C  illustrates a cross sectional view along line  9 C- 9 C in  FIG. 9B  of a wiring harness, in accordance with an exemplary window embodiment of the present invention; 
         FIG. 9D  shows an exploded view of a of a wiring harness, in accordance with an exemplary window embodiment of the present invention; 
         FIG. 9E  shows a portion of  FIG. 9C  in greater detail, in accordance with an exemplary embodiment of the present invention; 
         FIG. 10A  illustrates a left front perspective rotational view of a wiring harness, in accordance with an exemplary window height embodiment of the present invention; 
         FIG. 10B  illustrates an inverted front rotational view of a wiring harness, in accordance with an exemplary window height embodiment of the present invention; 
         FIG. 10C  illustrates a top rotational view of a wiring harness, in accordance with an exemplary window height embodiment of the present invention; 
         FIG. 11  illustrates an exemplary method for swiveling an electrical harness in accordance with an exemplary rotatable adapter embodiment of the present invention; 
         FIG. 12  illustrates an exemplary method for swiveling an electrical harness in accordance with an exemplary window height helical embodiment of the present invention; 
         FIG. 13  illustrates an exemplary method for swiveling an electrical harness in accordance with an exemplary helical embodiment of the present invention; 
         FIG. 14  illustrates an exemplary method of manufacturing a rotatable adapter embodiment of an electrical harness in accordance with an exemplary embodiment of the present invention; 
         FIG. 15  illustrates an exemplary method of manufacturing a helical embodiment of an electrical harness in accordance with an exemplary embodiment of the present invention; 
         FIG. 16  illustrates an exemplary method of manufacturing a window height embodiment of an electrical harness in accordance with an exemplary embodiment of the present invention; and 
         FIG. 17  shows a front perspective view of an electrical connector and backshell, in accordance with an exemplary embodiment of the present invention. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The invention, as defined by the claims, may be better understood by reference to the following detailed description. The description is meant to be read with reference to the figures contained herein. This detailed description relates to examples of the claimed subject matter for illustrative purposes, and is in no way meant to limit the scope of the invention. The specific aspects and embodiments discussed herein are merely illustrative of ways to make and use the invention, and do not limit the scope of the invention. 
       FIGS. 1A-1B  illustrate a conventional wiring conduit that affords a fixed ninety degree cable to interface connector orientation. The wiring conduit  100  in  FIG. 1A  has an interfacing connector end  130 -C, a fixed ninety degree bend  110 -C, and a cable exit end  120 -C. Similarly, the wiring conduit  101  in  FIG. 1B  has an interfacing connector end  130 , a fixed ninety degree bend  110 , and a cable exit end  120 . In contrast embodiments of the present invention afford a rotatable angle between the interfacing connector and the exiting cable conduit.  FIG. 2A  illustrates a left front perspective view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention. Referring to the foreground, a cable exit end  47 -A connects to a conduit  44 -A. The conduit extends into a backshell slot  37 -A. The top  32 -A of the backshell  30 -A is above slot  37 -A and a front edge  33 A of slot  37 -A is also shown. Beneath the slot  37 -A is a coupling nut  20 -A. And still below the coupling nut  20 -A, an electrical interfacing connector  60 -A is shown. The type of interfacing electrical connector may vary across embodiments of the present invention as required or desired for a given application. Connector types in accordance with rotational adapter embodiments of the present invention include, but are not limited to, series III plug connectors. In accordance with another exemplary embodiment, the cable exit end  47 -A houses a cable which extends to a testing equipment connector, not shown. 
       FIG. 2B  illustrates a right front perspective view of the wiring harness shown in  FIG. 2A , in accordance with an exemplary rotational adapter embodiment of the present invention. The coupling nut  20 -A is now in the foreground and secures electrical interfacing connector  60 -A, below, to the backshell  30 -A, above. A front edge  33 -A of a backshell slot  37 -A is shown beneath a top wall  32 -A of the backshell and above the coupling nut  20 -A. The conduit  44 -A of the conduit assembly  40 -A is shown extending from its conduit connector  42 -A to its exit end  47 -A. In accordance with an exemplary embodiment, the conduit itself may be made of a combination of rubber, plastic, and stainless steel. 
       FIG. 2C  illustrates a side view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention. From the left, exit end  47 -A of the cable conduit connects to the conduit  44 -A which extends into an outer fitting  43 -A, which connects to a threaded conduit connector  42 -A, threads not shown. Conduit connector  42 -A is shown fitted through the backshell slot  37 -A. A front edge  33 -A of the backshell slot  37 -A is spaced from the conduit connector  42 -A in the side view. The coupling nut  20 -A secures a bottom end of a backshell  30 -A to the electrical interfacing connector  60 -A. In accordance with the exemplary embodiment shown in  FIG. 2C , the top  32 -A of the backshell  30 -A is relatively close to a top edge of a slot  37 -A, affording a low profile for the rotatable adapter wiring harness. The mechanical connection between the backshell  30 -A and the interface connector  60 -A is provided by coupling nut  20 -A. 
       FIG. 2D  illustrates a top view of the wiring harness shown in  FIGS. 2A-2C , in accordance with an exemplary rotational adapter embodiment of the present invention. The length of the conduit  44 -A is shown with the exit end  47 -A on the left and the conduit connector  42 -A on the right. The conduit connector is shown passing through the slot  37 -A to attach to the cylinder, not shown. The top  32 -A of the backshell can be seen as well as an outer edge of the electrical interface connector  60 -A. 
       FIG. 3A  illustrates a right front perspective view of a conduit assembly  40 -A. Conduit  44 -A has an exit end  47 -A and a conduit connector  42 -A on its opposite end. Flanking each end of conduit  44 -A are outer fittings  43 -A. In accordance with an exemplary embodiment of the present invention, conduit connector  42 -A is threaded, threads not shown, at its insertion end; the threaded embodiment is described below with reference to  FIG. 3E . A circumferential indent  42 - 1 -A is shown at an insertion end of connector  42 -A. In accordance with an exemplary embodiment, the conduit connector&#39;s  42 -A external threads mate with internal threads in the cylinder, not shown; the indent  42 - 1 -A versus threads are shown for drawing simplification. The referenced threading is particularly shown in  FIG. 3E , and further described below with reference to the same. 
       FIG. 3B  illustrates a partial view of the top view of  FIG. 2D  showing cross sectional line  3 C- 3 C, in accordance with an exemplary rotational adapter embodiment of the present invention. The partial top view shows a portion of the conduit assembly  40 -A with the conduit connector  42 -A inserted into the backshell and cylinder assembly, where the cylinder is not shown but the top wall of the backshell  32 -A and the outer edge of the electrical interface connector  60 -A are identified. A cross section is taken along line  3 C- 3 C  95 -A and the resulting cross sectional view is shown in  FIG. 3C . 
       FIG. 3C  illustrates a cross sectional view along line  3 C- 3 C in  FIG. 3B  of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention. An outer side of top side  52 -A of the cylinder  50 -A rests against an inside  39 -A top wall  32 -A of the backshell  30 -A. Conduit connector  42 -A is inserted into cylinder  50 -A. An enlargement of a portion  99 -A of  FIG. 3C  is shown in FIG.  3 E. The indent  42 - 1 -A of the connector is shown fitted into edge  55 -A of the cylinder. In accordance with exemplary embodiments of the present invention, the mechanical coupling or method of securing the conduit connector  42 -A to the cylinder  50 -A may be the mating of threads, threads not shown. This threaded coupling is shown and more particularly described in and with reference to  FIG. 3E , below. In alternate embodiments a different connector  42 -A and receptacle in the cylinder  50 -A may be used. O-ring  10 -A provides a seal between an outer circumference of the cylinder  50 -A and an inner circumference of the backshell  30 -A. The coupling nut  20 -A joins the interface connector  60 -A to the backshell  30 -A. Retaining ring  80 -A secures the cylinder  50 -A relative to the backshell  30 -A in the vertical direction. The cylinder  50 -A acts as a swivel bushing in accordance with embodiments of the present invention. O-ring  70 -A provides a seal between the backshell  30 -A and the coupling nut  20 -A. The electrical contacts of the interfacing connector  60 -A are not shown. In  FIG. 3C , the connecting face  61 -A of the electrical interfacing connector  60 -A is identified. The interconnections between the conduit connector, backshell, and cylinder of portion  99 -A are shown in greater detail in  FIG. 3E . 
       FIG. 3D  shows an exploded view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention. The attachment end  41 -A of the conduit connector  42 -A connects to cylinder  50 -A at receptacle point  51 -A, as indicated by line  53 -A. Conductor conduit  44 -A is shown connected to conduit connector  42 -A. An outer surface of a top side  52 -A of the cylinder  50 -A is shown beneath a bottom edge  31 -A of the backshell  30 -A. Just above the bottom edge  31 -A of the backshell  30 -A is a lower edge  35 -A of the backshell  30 -A. The open slot  37 -A of the backshell  30 -A will align with the receptacle point  51 -A of the cylinder  50 -A when the wiring harness is assembled. The coupling nut  20 -A is shown above an outer surface of a top side  32 -A of backshell  30 -A. In accordance with the exemplary rotatable adapter shown in  FIG. 3D , an o-ring  70 -A is seated inside the coupling nut  20 -A. 
     Turning to the cylinder,  50 -A, an o-ring  10 -A seats between a lower edge  54 -A and a bottom edge  56 -A. A cross sectional view taken along line  92 -A of the cylinder portion  92 - 1 -A of  FIG. 3D  is shown in  FIG. 3F . The cylinder and its bottom portion are shown in greater detail in  FIG. 3F . A top side  52 -A of the cylinder is shown beneath the bottom edge  31 -A of backshell  30 -A. The electrical connecting end, connecting face,  61 -A of the electrical interfacing connector  60 -A is shown beneath the retaining ring  80 -A. The top  62 -A of the electrical interface connector  60 -A fits into the bottom  31 -A of the backshell and is secured to the backshell by coupling nut  20 -A. Also shown are anti-rotational teeth  31 -A-a, which are further described below in reference to  FIG. 17  and their position on the harness is discussed below relative to  FIG. 9E . Anti-rotational teeth  31 -A-a, along the bottom edge  31 -A of the backshell  30 -A mate with the anti-rotational teeth  60 - 2 -A-b of the connector  60 -A. 
       FIG. 3E  shows portion  99 -A of  FIG. 3C  in greater detail, in accordance with an exemplary rotational adapter embodiment of the present invention. The external threads  42 - 2 -A of the conduit connector  42 -A are mated with internal threads  55 - 1 -A of the cylinder  50 -A. The slot height  30 -A-sh is just slightly larger than an external conduit connector diameter  42 -A-d. An outside diameter  42 -A-d of the conduit connector  42 -A extends to a close proximity to an inside of bottom  33 - 2 -A edge and a top  33 - 1 -A edge of the slot  37 -A in the backshell  30 -A. In accordance with an exemplary embodiment the slot height can limit the vertical displacement of the conduit connector from the electrical connector. Also shown in this enlarged view is the juxtaposition of the outer side  52 - 1 -A of the top side  52 -A of the cylinder  50 -A to the inside surface  39 -A of a top wall  32 -A of the backshell  30 -A. Similarly, the outer surface of the cylinder  50 -A side wall  50 - 3 -A mates up against the inner surface of a side wall  30 - 3 -A of the backshell  30 -A. In alternate embodiments of the present invention, the outside surface of the top of the cylinder may be separated from the inside of the top wall of the backshell during operation of the wiring harness. In still other embodiments the cylinder and backshell may be configured such that the top surfaces of the cylinder and backshell, respectively, do not make contact regardless of the operational status of the wiring harness. 
       FIG. 3F  shows a cross sectional view of a rotational adapter cylinder,  92 - 1 -A in  FIG. 3D , in greater detail, in accordance with an exemplary embodiment of the present invention. The cross sectional reference view line  92 -A is shown in  FIG. 3D . Referring again to  FIG. 3F , the cylinder has a closed top side, top wall,  52 -A and an open bottom edge  56 -A. Between lower edge  54 -A and bottom edge  56 -A is a channel into which an o-ring  10 -A may be housed. The inside of bottom edge of  56 -A of the cylinder  50 -A is chamfered  57 -A. The insertion point or receptacle  51 -A for the conduit connector is shown. 
       FIG. 4A  illustrates a rotational view in a left front perspective of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention. The conductor conduit  44 -A is in the foreground midway in the rotational range  36 -A. The conduit connector  42 -A fits through slot  37 -A of the backshell  30 -A. The conduit connector  42 -A is shown in the middle range of the slot  37 -A, where a front edge  33 -A provides a rotational stop for a counter clockwise  36 - 3 -A direction. Similarly a back edge, not shown, of slot  37 -A provides a stop for maximum clockwise rotation position  36 - 2 -A. In accordance with the exemplary embodiment of  FIGS. 4A-4C  and  FIG. 3C , the diameter of the insertion portion of the conduit connector  42 -A nearly spans the vertical  77 -A open distance of the slot  37 -A. Also shown in this subject embodiment is the relatively low profile of the wiring harness; for example, a top side  32 -A of the backshell  30 -A is relatively close to a top edge of the slot  37 -A. Coupling nut  20 -A is shown below the backshell  30 -A and secures the same to the interface connector  60 -A. The embodiment of  FIGS. 4A-4C  affords a rotation span  36 -A near 130 degrees. 
       FIG. 4B  illustrates an inverted front rotational view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention. A top side  32 -A of the backshell  30 -A is now shown below conduit connector  42 -A. In accordance with an exemplary embodiment of the present invention the cable conduit has a diameter  36 - 1 -A of 0.69 inches. Coupling nut  20 -A is shown, here, above the backshell  30 -A and secures the backshell  30 -A to the interface connector  60 -A. 
       FIG. 4C  illustrates a top rotational view of a wiring harness, in accordance with an exemplary rotational adapter embodiment of the present invention. A top surface  32 -A of the backshell is shown above conduit connector  42 -A. A rotation span  36 -A of about 130 degrees is provided by the subject exemplary embodiment. The rotational span of any embodiments of the present invention can range from a minute rotation of single digit degrees to an angle of greater than 180 degrees. Conduit connector  42 -A is shown inserted through slot  37 -A of the backshell. The entire conduit assembly  40 -A swings through the rotation angle about the cylinder, which acts as a swivel bushing. Conduit  44 -A fits into outer fitting  43 -A which is secured to an end conduit connector  42 -A. 
       FIG. 5A  illustrates a left front perspective view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention. From the top of the figure, the top  32 -H of the backshell  30 -H is above slot  37 -H and a front edge  33 -H of the slot is also shown. From the foreground, a cable exit end  47 -H connects to a conduit  44 -H which connects to conduit connector  42 -H, which extends through the backshell slot  37 -H and into the cylinder at the receptacle point  51 -H. In accordance with an exemplary embodiment the conduit connector  42 -H mates with the receptacle point  51 -H by mating external threads on connector  42 -H and tapped threads at the receptacle  51 -H. Beneath the slot  37 -H at the lower end of the backshell  30 -H is coupling nut  20 -H, which couples the backshell to the electrical interfacing connector  60 -H. The type of electrical interface connector may vary across embodiments of the present invention as required or desired for a given application. Connector types in accordance with helical embodiments of the present invention include, but are not limited to, MIL-DTL-38999. In accordance with exemplary embodiments, the cable exit end  47 -H houses a cable which extends out of the conduit to a testing equipment connector, not shown. 
       FIG. 5B  illustrates a right front perspective view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention. The coupling nut  20 -H is in the background and secures electrical interfacing connector  60 -H, below, to the backshell  30 -H, above. A back edge  33 - 3 -H of the helical backshell slot  37 -H is shown left of conduit connector  42 -H. Conduit connector  42 -H fits through the backshell slot  37 -H and affixes into receptacle point  51 -H of the cylinder  50 -H, where the cylinder  50 -H is housed within the backshell  30 -H and is not shown. A top side  32 -H of the backshell  30 -H is also visible in this view. The conduit  44 -H of the conduit assembly is shown extending from its conduit connector  42 -H to its exit end  47 -H. 
       FIG. 5C  illustrates a side view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention; From the left, exit end  47 -H of the cable conduit connects to the conduit  44 -H which extends into an outer fitting  43 -H, which connects to a threaded conduit connector  42 -H, threads not shown. Conduit connector  42 -H is shown fitted into the backshell slot  37 -H. A front edge  33 -H of the backshell slot  37 -H is spaced from the conduit connector  42 -H in the side view. The coupling nut  20 -H secures a bottom end of a backshell  30 -H to the electrical interfacing connector  60 -H. In accordance with the exemplary embodiment shown in  FIG. 5C , the top  32 -H of the backshell  30 -H is relatively close to a top edge of a slot  37 -H, but the harness has a higher profile than the rotatable adapter embodiment shown in  FIGS. 2A-2C . The mechanical connection between the backshell  30 -H and the interface connector  60 -H is provided by coupling nut  20 -H. 
       FIG. 5D  illustrates a top view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention. The length of the conduit  44 -H is shown with the exit end  47 -H on the left and the conduit connector  42 -H on the right. The conduit connector is shown passing through the slot  37 -H to attach to the cylinder  50 -H, not shown in the top view  5 D, shown in  FIG. 5C . Referring again to  FIG. 5D , the top  32 -H of the backshell is shown; the outer edge of the electrical interface connector  60 -H is also visible in this view.  FIG. 6A  illustrates a right front perspective view of a conduit assembly  40 -H. Conduit  44 -H has an exit end  47 -H and a conduit connector  42 -H on its opposite end with outer fitting  43 -H at either end of conduit  44 -H. The attachment end  41 -H of the conduit connector  42 -A connects to cylinder  50 -A, not shown. Referring again to  FIG. 6A , in accordance with an exemplary embodiment of the present invention  42 -H is threaded at its insertion end, as described above with reference to  FIG. 3E . 
       FIG. 6B  illustrates a partial view of the top view of  FIG. 5D  showing cross sectional line  6 C- 6 C, in accordance with an exemplary helical embodiment of the present invention. The partial top view shows a portion of the conduit assembly  40 -H with the cable conduit  44 -H and with conduit connector  42 -H inserted into the backshell and cylinder assembly, where the cylinder is not shown but the top of the backshell  32 -H and the outer edge of the electrical interface connector  60 -H are identified. A cross section is taken along line  6 C- 6 C  95 -H and the resulting cross sectional view is shown in  FIG. 6C . 
       FIG. 6C  illustrates a cross sectional view along line  6 C- 6 C in  FIG. 6B  of a wiring harness, in accordance with an exemplary helical embodiment of the present invention. An outside surface of a top  52 -H of the cylinder  50 -H is displaced from an inside surface  39 -H of top wall  32 -H of the backshell  30 -H. Similar to the rotatable adapter, as shown in  FIG. 3E  and described above, the helical embodiment has a helical slot height near the diameter of the conduit connector, this height is constant along the helical slot path. Opposite the top  32 -H of the backshell  30 -H is the face  61 -H of the interface connector  60 -H. 
     The interfacing and securing mechanism between connector  42 -H and cylinder  50 -H are shown as an indent  42 - 1 -H of the conduit connector  42 -H, which fits into notch  55 -H of cylinder  50 -H. In accordance with exemplary embodiments of the present invention, the mechanical connection or method of securing the conduit connector  42 -H to the cylinder  50 -H is by the mating of threads, where such threads are shown in  FIG. 3E  and described above. O-ring  10 -H provides a seal between an outer circumference of the cylinder  50 -H and an inner circumference of the backshell  30 -H. Coupling nut  20 -H joins the interface connector  60 -H to the backshell  30 -H. 
     Retaining ring  80 -H acts as stop for the cylinder  50 -H, relative to the backshell  30 -H, in the vertical direction. The cylinder  50 -H acts as a swivel bushing in accordance with embodiments of the present invention. O-ring  70 -H provides a seal between the backshell  30 -H and the coupling nut  20 -H. A chamfered  57 -H bottom edge of the cylinder  50 -H is displaced above retaining ring  80 -H. The inner diameter of the backshell  30 -H decreases from a first inner diameter  30 - 2 -H from its electrical connector  60 -H end to a second diameter  30 - 1 -H just below the retaining ring  80 -H. The top of the connector is where the section lines end on  60 -H. The connector  60 -H is shown fully inserted in the backshell  30 -H. A bottom edge  31 -H of the backshell is shown displaced from a ledge on the connector  60 -H, described in further detail with reference to  FIG. 9E , below. Referring again to  FIG. 6C , also shown are anti-rotational teeth  31 -H-a, which are further described below in reference to  FIG. 17  and their position on the harness is discussed below relative to  FIG. 9E . Anti-rotational teeth  31 -H-a mate with the anti-rotational teeth  60 - 2 -H-b of the connector  60 -H. 
     A pair of slack wires  81 -H and  82 -H are shown extending into  81 - 2 -H,  82 - 2 -H from the top  62 -H of the electrical connector  60 -H and into  81 - 1 -H,  82 - 1 -H the conduit connector  42 -H. The slack in the wires or cable affords the rotation or other displacement of the conduit  44 -H relative to the connector  60 -H with minimal strain on the cable wires, in accordance with exemplary embodiments of the present invention. 
       FIG. 6D  shows an exploded view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention. The attachment end  41 -H of the conduit connector  42 -H connects to cylinder  50 -H at receptacle point  51 -H, as indicated by line  53 -H. Conductor conduit  44 -H is shown connected to conduit connector  42 -H via outer fitting  43 -H. Open slot  37 -H of the backshell  30 -H aligns with the receptacle point  51 -H of the cylinder  50 -H when the wiring harness is assembled. A front edge  33 -H is visible. The backshell steps out to a larger outer diameter near a bottom edge  31 -H forming a ledge  35 -H. 
     An outer surface of a top side  52 -H of the cylinder  50 -H is shown beneath a bottom edge  31 -H of the backshell  30 -H. The coupling nut  20 -H is shown above an outer surface of a top side  32 -H of backshell  30 -H. In accordance with the exemplary helical embodiment shown in  FIG. 6D , an o-ring  70 -H is seated inside the coupling nut  20 -H. A channel between  54 -H and  56 -H is formed at the bottom of cylinder  50 -H, where in accordance with the embodiment of  FIG. 6D , an o-ring  10 -H seats between  54 -H and  56 -H in the channel. This channel is more particularly shown in  FIG. 3F . The electrical contact end  61 -H of the electrical interfacing connector  60 -H is shown beneath the retaining ring  80 -H. The top  62 -H of the interface connector  60 -H fits into the bottom  31 -H of the backshell and is secured to the backshell by coupling nut  20 -H. 
     In accordance with the present invention, embodiments may enable repositioning of the conduit connector via rotation in the X-Y plane, where the face or electrical contact points of the interface connector are also in the X-Y plane, as in the rotational adapter described above and shown in  FIGS. 2A-4C . In accordance with a rotational adapter embodiment, this repositioning can be made in real time during field applications and may even be performed when the interfacing connector is electrically connected to a test point connector. 
     In an alternate embodiment of the present invention, a helical repositioning of the conduit cable relative to the connecting face of the interface connector is enabled. The adjustability feature of the rotational adapter is augmented to include movement of the conductor conduit normal to the face of the interfacing connector, or in the Z direction. With respect to the helical embodiment, rotation is afforded through the X-Z and Y-Z planes, however rotation about the swiveling bushing remains in the X-Y plane and the cylinder translates in the Z direction. Similar to the slot in a rotational adapter embodiment, the helical embodiment has a constant height. In contrast to the planar slot of the rotational adapter, the helical slot harness moves in a helical form to enable simultaneous rotation in the X-Y plane and translation in the Z direction. In a helical embodiment the perpendicular distance of the conduit to the interfacing connector can be adjusted, increasing or decreasing as needed. 
       FIG. 7A  illustrates a left front perspective rotational view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention. The conduit adapter  42 -H fits through slot  37 -H of the backshell  30 -H. The conduit connector  42 -H is shown in the middle range of the slot  37 -H, where a front edge  33 -H provides a rotational stop for a counter clockwise  36 - 3 -H direction. Similarly a back edge, not shown, of slot  37 -H provides a stop for maximum clockwise rotation position  36 - 2 -H. In accordance with the exemplary embodiment of  FIGS. 4A-4C  and  FIG. 3C , the diameter of the insertion portion of the conduit connector  42 -H nearly spans the vertical open distance, Z direction, of the slot  37 -H. Also shown in the subject embodiment is a relatively low profile of the wiring harness; for example, a top wall  32 -H of the backshell  30 -H is relatively close to a top edge of the slot  37 -H. Coupling nut  20 -H is shown below the backshell  30 -H and secures the same to the interface connector  60 -H. Cable conduit  44 -H extends into the foreground in this view. 
       FIG. 7B  illustrates an inverted front rotational view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention. A top wall  32 -H of the backshell  30 -H is now shown below conduit connector  42 -H. In accordance with an exemplary embodiment of the present invention, the conduit connector can travel of 0.82 inches  42 -H-z in the Z direction. Coupling nut  20 -H is shown, here, above the backshell  30 -H and secures the backshell  30 -H to the interface connector  60 -H. 
       FIG. 7C  illustrates a top rotational view of a wiring harness, in accordance with an exemplary helical embodiment of the present invention. A top surface  32 -H of the backshell is shown above conduit connector  42 -H. A rotation span  36 -H of about 130 degrees is provided by the subject exemplary embodiment. The rotational span of any embodiments of the present invention can range from a minute rotation of single digit degrees to an angle of greater than 180 degrees. Conduit connector  42 -H is shown inserted through slot  37 -H of the backshell. The entire conduit assembly  40 -H swings through the rotation angle upon swiveling of the wiring harness. Conduit  44 -H fits into outer fitting  43 -H which is secured to an end conduit connector  42 -H. 
     In accordance with the embodiment of  FIGS. 7A-7C , if the conduit connector  42 -H is in the front portion of the slot, towards front edge  33 -H, it is farther away in the Z direction from the face  61 -H of the interface connector  60 -H. If conduit connector  42 -H is against a back edge  33 - 3 -H of the helical slot, then the conduit connector  42 -H is closer in the Z direction to the face of the interface connector. In the embodiment of  FIGS. 7A-7C  the conduit moves away from the interface connector with a counter clockwise rotation  97 -H. In alternate embodiments, the helical slot may increase the distance of the conduit from the interface connector with a clockwise rotation. The helical shaped slot allows the cable to avoid obstructions side to side as well as front to rear, relative to the interfacing connector. 
     In helical embodiments of the present invention and in rotational adapter embodiments of the present invention, the front edge and the back edge of the respective slots can provide positive lateral stops for the swivel. In accordance with embodiments of the present invention, a positive stop from the inside surface of the top wall of the backshell contacting an outer side of a top side of a cylinder may be employed in the positive Z direction away from the interface connector. In alternate embodiments, a top edge and a bottom edge of the slot itself may also provide the positive stops for movement in the Z direction. A stop in the negative Z direction can be provided by a retaining ring, such as  80 -H in  FIG. 6D  or an additional retaining ring for the purpose of limiting vertical displacement can be employed. 
     In accordance with an exemplary embodiment, when the conduit fitting is moving through the helical slot toward the rear of the backshell, the rear end of the cylinder will make contact against the inside rear end of the backshell and stop. When the conduit fitting is moving forward through the helical slot the front end of the cylinder will make contact, for example against a snap ring or some other device that creates a reduction in the inside diameter of the backshell for the cylinder to stop against. Stopping against the inside of the backshell provides more surface area contact than the ends of the slot and therefore would create less wear when swiveling the backshell or conduit. Conventional swivel joints for cable harnesses may utilize bent tubing to make a 90 degree turn, as shown for example in  FIGS. 1A and 1B . This conventional device can limit the sharpness of the turn that can be achieved. In turn, the length of the backshell is affected by the fixed elbow. The present invention provides a swivel joint with a relatively shallow Z directional clearance from the interface connector. This feature may be desirable in multiple applications, to include testing of aircraft systems. 
     A rotatable adapter wiring harness embodiment of the present invention permits rotation of the cable leg on a cable harness to swivel to any degree of rotation that is within the limits of the slot in the backshell. Positive stops prevent the cable from being over rotated. This rotation restriction may reduce wear and prevent damage to the electrical wires housed within the rotatable adapter wiring harness assembly. In accordance with an exemplary embodiment, a front edge of a backshell slot provides a forward or clockwise rotation stop and a back edge of the backshell slot provides a backward or counter-clockwise rotation stop. The length, distance from front edge to back edge, of the slot in the backshell can be made specific to a given field condition and a given apparatus to be tested. 
       FIG. 8A  illustrates a left front perspective view of a wiring harness, in accordance with an exemplary window height embodiment of the present invention. Referring to the foreground, a cable exit end  47 -W connects to a conduit  44 -W of the conduit assembly  40 -W. The conduit connector  42 -W extends into a backshell slot  37 -W. The top wall  32 -W of the backshell  30 -W is above slot  37 -W and a front edge  33 -W of the slot is shown. A top edge  33 - 1 -W of the slot  37 -W is displaced from the conduit connector  42 -W while the bottom edge  33 - 2 -W is readily seen in the foreground. Beneath the slot  37 -W is a coupling nut  20 -W. And still below the coupling nut  20 -W, an electrical interfacing connector  60 -W is shown. The type of interfacing electrical connector may vary across embodiments of the present invention as required or desired for a given application. As with the rotation adapter and helical embodiments, Connector types in accordance with embodiments, to include window height embodiments, include, but are not limited to, MIL-DTL-38999 series III plug connectors. In accordance with another exemplary embodiment, the cable exit end  47 -W houses a cable which extends to a testing equipment connector, not shown. 
       FIG. 8B  illustrates a right front perspective view of the wiring harness shown in  FIG. 8A , in accordance with an exemplary window height embodiment of the present invention. The coupling nut  20 -W is in the back ground and secures electrical interfacing connector  60 -W, below, to the backshell  30 -W, above. A back edge  33 - 3 -W of the window backshell slot  37 -W is shown left of the conduit connector  42 -W. Conduit connector  42 -W fits through the backshell slot  37 -W and affixes into receptacle point  51 -W of the cylinder, housed within the backshell  30 -W. A top edge  33 - 1 -W and a bottom edge  33 - 2 -W of window slot  37 -W are also shown above and below, respectively, the conduit connector  42 -W. A top wall  32 -W of the backshell  30 -W is above the top edge  33 - 1 -W of the slot  37 -W. The conduit  44 -W of the conduit assembly  40 -W is shown extending from its conduit connector  42 -W to its exit end  47 -W. Flanking each end of conduit  44 -W are outer fittings  43 -W. 
       FIG. 8C  illustrates a side view of a wiring harness, in accordance with an exemplary window height embodiment of the present invention. From the left, exit end  47 -W of the cable conduit connects to the conduit  44 -W which extends into an outer fitting  43 -W, which connects to a threaded conduit connector  42 -W. Conduit connector  42 -W is shown passing through the backshell slot  37 -W. A front edge  33 -W of the backshell slot  37 -W is spaced from the conduit connector  42 -W in this side view. Here, in a window embodiment the conduit connector is spaced from a top slot edge  33 - 1 -W and a bottom slot edge  33 - 2 -W. The coupling nut  20 -W secures a bottom end of a backshell  30 -W to the electrical interfacing connector  60 -W. In accordance with the exemplary embodiment shown in  FIG. 8C , the top  32 -W of the backshell  30 -W is relatively close to a top edge of a slot  37 -W, affording a low profile for the rotatable adapter wiring harness. Coupling nut  20 -W provides the mechanical connection between the backshell  30 -W and the interface connector  60 -W. In accordance with a window embodiment of the present invention, the cable conduit can swivel about a center axis  73 -W of the backshell-cylinder assembly as well as move in a direction parallel to the center axis  73 -W. 
       FIG. 8D  illustrates a top view of the wiring harness shown in  FIGS. 8A-8C , in accordance with an exemplary window height embodiment of the present invention. The length of the conduit  44 -W is shown with the exit end  47 -W on the left and the conduit connector  42 -W on the right. The conduit connector is shown passing through the slot  37 -W to attach to the cylinder, not shown. The top wall  32 -W of the backshell can be seen as well as an outer edge of the electrical interface connector  60 -W. 
       FIG. 9A  illustrates a right front perspective view of a conduit assembly  40 -W in accordance with an exemplary window height embodiment of the present invention. Conduit  44 -W has an exit end  47 -W and a conduit connector  42 -W on its opposite end. Flanking each end of conduit  44 -W are outer fittings  43 -W. The attachment end  41 -W of the conduit connector  42 -W connects to cylinder  50 -W, not shown. In accordance with an exemplary embodiment of the present invention  42 -W is threaded at its insertion end, as described below with reference to  FIG. 9C . 
       FIG. 9B  illustrates a partial top view of a wiring harness showing cross sectional line  9 C- 9 C, in accordance with an exemplary window embodiment of the present invention. The partial top view shows a portion of the conduit assembly  40 -W cable conduit  44 -W which extends into an outer fitting  43 -W, which connects to a threaded conduit connector  42 -W. The conduit connector  42 -W is inserted through the backshell; the cylinder, housed within the backshell, is not shown but the top of the backshell  32 -W and the outer edge of the electrical interface connector  60 -W are identified. A cross section is taken along line  9 C- 9 C  95 -W and the resulting cross sectional view is shown in  FIG. 9C   
       FIG. 9C  illustrates a cross sectional view along line  9 C- 9 C in  FIG. 9B  of a wiring harness, in accordance with an exemplary window embodiment of the present invention. This view shows a portion of the conduit assembly  40 -W with the conduit connector  42 -W inserted through the backshell  30 -W and into the cylinder  50 -W. As in  FIGS. 3C and 6C , the mechanical connection between the conduit connector  42 -W and the cylinder  50 -W is shown simplified as an indent  42 - 1 -W into edge  55 -W of cylinder  50 -W. In accordance with an exemplary embodiment, the mechanical connection of the conduit connector  42 -W to the cylinder insertion point, receptacle, is external threads on the conduit connector mated to internal threads in the cylinder, not shown in  FIG. 9C  but shown in  FIG. 3E . An outside surface of a top side  52 -W of the cylinder  50 -W is displaced from an inside surface  39 -W of top wall  32 -W of the backshell  30 -W. 
     In contrast to the rotatable adapter and the helical embodiments the slot height of the window embodiment affords movement of the conduit perpendicular to a connection face  61 -W of the interface connector  60 -W in the Z direction. O-ring  10 -W provides a seal between an outer circumference of the cylinder  50 -W and an inner circumference of the backshell  30 -W. The backshell coupling nut  20 -W joins the interface connector  60 -W to the backshell  30 -W. Retaining ring  80 -W acts as a vertical stop for the cylinder relative to the backshell in the negative Z direction. The cylinder  50 -W acts as a swivel bushing in accordance with embodiments of the present invention. O-ring  70 -W provides a seal between the backshell  30 -W and the coupling nut  20 -W. The lower portion of the wiring harness  93 -W is shown in greater detail in  FIG. 9E  and described in more detail with reference to the same. The coupling of the backshell  30 -W to the electrical connector  60 -W is shown in greater detail in  FIG. 9E . Referring again to  FIG. 9C , also shown are anti-rotational teeth  31 -W-a, which are further described below in reference to  FIG. 17  and their position on the harness is discussed below with reference to  FIG. 9E . 
       FIG. 9D  shows an exploded view of a window wiring harness, in accordance with an exemplary window embodiment of the present invention. An outer surface of a top side  52 -W of the cylinder  50 -W is shown beneath bottom edge  31 -W of the backshell  30 -W. The coupling nut  20 -W is shown above an outer surface of a top side  32 -W of backshell  30 -W. In accordance with the exemplary window embodiment shown in  FIG. 9D , an o-ring  70 -W is seated inside the coupling nut  20 -W. Bottom edge  56 -W of cylinder  50 -W and o-ring  10 -W are shown in greater detail in  FIG. 9E . Referring again to  FIG. 9D , the electrical contact end  61 -W of the electrical interfacing connector  60 -W is shown beneath the retaining ring  80 -W. The top  62 -W of the interface connector  60 -W fits into the bottom  31 -W of the backshell and is secured to the backshell by coupling nut  20 -W. Above bottom edge  31 -W is a lower edge  35 -W of the backshell, described in greater detail with reference to  FIG. 9E . Along the bottom edge  31 -W of the backshell  30 -W are anti-rotational teeth  31 -W-a, shown in  FIG. 9C , which mate with the anti-rotational teeth  60 - 2 -W-b, shown in  FIG. 9C , of the connector  60 -W. 
     The attachment end  41 -W of the conduit connector  42 -W connects to cylinder  50 -W at receptacle point  51 -W, as indicated by line  53 -W. Conductor conduit  44 -W is shown connected to conduit connector  42 -W via outer fitting  43 -W. Open slot  37 -W of the backshell  30 -W aligns with the receptacle point  51 -W of the cylinder  50 -W when the wiring harness is assembled. A top edge  33 - 1 -W and a bottom edge  33 - 2 -W of slot  37 -W are shown and may be used as vertical stops, in accordance with exemplary embodiments of the present invention. 
     The mechanical coupling between the cylinder and backshell are further described with reference to  FIG. 9E , which shows portion  93 -W of  FIG. 9C  in greater detail, in accordance with an exemplary embodiment of the present invention. Cylinder  50 -W has a chamfered  57 -W bottom end  56 -W along its inner circumference. The cylinder  50 -W is housed in the backshell  30 -W. In this view, wires  81 -W and  82 -W are shown in the center of the cylinder and backshell, where said wires extend to make electrical contact with the connector  60 -W. Electrical connector  60 -W is shown as a solid cross section block to simplify the drawing. The connector  60 -W may be of a conventional configuration. O ring  10 -W provides a seal between an outer circumference of the cylinder  50 -W and an inner circumference of the backshell  30 -W, while O-ring  70 -W provides a seal between the backshell  30 -W and the coupling nut  20 -W. 
     The connector  60 -W, in accordance with an exemplary embodiment has external threads  67 -W at the end opposite the connection face  61 -W. These external threads  67 -W mate with internal threads  23 -W of the coupling nut  20 -W. Coupling nut  20 -W has a collar  22 -W at its top end which catches on ledge  35 -W of the backshell  30 -W. The bottom edge  31 -W of the backshell is shown spaced above ledge  60 - 2 -W of the connector  60 -W before full mating of threads for mechanical coupling of the backshell to the connector  60 -W. Similarly, ledge  60 - 1 -W of the connector  60 -W is shown spaced above bottom edge  28 -W of the coupling nut  20 -W. Along ledge  60 - 2 -W of the connector  60 -W are anti-rotational teeth, not shown, which mate with the anti-rotational teeth on the bottom edge  31 -W of the back shell  30 -W, not shown. A top  62 -W of the electrical connector is shown displaced from retaining ring  80 -W and fully inserted into the backshell  30 -W. 
       FIGS. 10A-10C  show rotational views of a window height embodiment of the present invention.  FIG. 10A  illustrates a left front perspective rotational view of a wiring harness, in accordance with an exemplary window embodiment of the present invention. The cable conduit  44 -W extends into the foreground. The conduit adapter  42 -W fits through slot  37 -W of the backshell  30 -W. The conduit connector  42 -W is shown in the middle range of the slot  37 -W, where a front edge  33 -W provides a rotational stop for a counter clockwise  36 - 3 -W direction. Similarly a back edge, not shown, of slot  37 -W provides a stop for maximum clockwise rotation position  36 - 2 -W. The conduit connector  42 -W is also shown displaced from a top edge  33 - 1 -W and a bottom edge  33 - 2 -W of slot  37 -W, which may be used as vertical stops, in accordance with exemplary embodiments of the present invention. Also shown in the subject embodiment is a relatively low profile of the wiring harness; for example, a top side  32 -W of the backshell  30 -W is relatively close to a top edge of the slot  37 -W. Coupling nut  20 -W is shown below the backshell  30 -W and secures the same to the interface connector  60 -W. The embodiment of  FIGS. 10A-10C  affords a rotation span  36 -W near 130 degrees. 
       FIG. 10B  illustrates an inverted front rotational view of a wiring harness, in accordance with an exemplary window embodiment of the present invention. A top side  32 -W of the backshell  30 -W is now shown below conduit connector  42 -W. In accordance with the exemplary embodiment of  FIGS. 10A-10C , the external diameter of the insertion portion of the conduit connector  42 -W is smaller than vertical  77 -W open distance of the slot  37 -W. In accordance with an exemplary embodiment, the vertical  77 -W distance of the window slot is 1.50 inches. Also in accordance with an exemplary embodiment of the present invention, a vertical excursion  36 - 1 -W for the cable conduit of 0.68 inches is afforded with a cable conduit diameter  42 -A-d, shown for example in  FIG. 3E , of 0.82 inches. Referring again to  FIG. 10B , coupling nut  20 -W is shown, here, above the backshell  30 -W and secures the backshell  30 -W to the interface connector  60 -W. The connection face  61 -W of the connector  60 -W is at the top in this view. 
       FIG. 10C  illustrates a top rotational view of a wiring harness, in accordance with an exemplary window embodiment of the present invention. A top surface  32 -W of the backshell is shown above conduit connector  42 -W. A rotation span  36 -W of about 130 degrees is provided by the subject exemplary embodiment. The rotational span of any embodiments of the present invention can range from a minute rotation of single digit degrees to an angle of greater than 180 degrees. Conduit connector  42 -W is shown inserted through slot  37 -W of the backshell. The entire conduit assembly  40 -W swings through the rotation angle upon swiveling of the wiring harness. Conduit  44 -W fits into outer fitting  43 -W which is secured to an end conduit connector  42 -W. 
     In accordance with the embodiment of  FIGS. 7A-7C , if the conduit connector  42 -H is in the front portion of the slot, towards front edge  33 -H, it is farther away in the Z direction from the face  61 -H of the interface connector  60 -H. If conduit connector  42 -H is against a back edge  33 - 3 -H of the helical slot, then the conduit connector  42 -H is closer in the Z direction to the face of the interface connector. In the embodiment of  FIGS. 7A-7C  the conduit moves away from the interface connector with a counter clockwise rotation  97 -H. In alternate embodiments, the helical slot may increase the distance of the conduit from the interface connector with a clockwise rotation. The helical shaped slot allows the cable to avoid obstructions side to side as well as front to rear, relative to the interfacing connector. 
     In helical embodiments of the present invention and in rotational adapter embodiments of the present invention, the front edge and the back edge of the respective slots can provide positive lateral rotation stops for the swivel. The slot front and back edges of a window slot may also provide positive lateral rotation stops for the swivel. In the helical and window embodiments, since the cylinder is moving upwards and downwards in the Z direction,  FIGS. 7A-C  and  10 A-C, the outer side of the top surface of the cylinder can make contact with the inside of the top wall of the backshell, in accordance with exemplary embodiments of the present invention. The slot itself may also provide the positive stops for movement in the Z direction. Alternatively a retaining ring, for example  80 -W, shown in  FIG. 9E , may serve as a lower vertical displacement stop. 
     In accordance with the present invention, embodiments may enable repositioning of the conduit connector via rotation in the X-Y plane, where the face or electrical contact points of the interface connector are also in the X-Y plane, as in the rotational adapter described above and shown in  FIGS. 2A-4C . In accordance with a rotational adapter embodiment this repositioning can be made in real time during field applications and may even be performed when the interfacing connector is electrically connected to a test point connector. 
     Embodiments of the present rotatable wiring harness may be sealed from environmental factors using, for example, o-rings, as illustrated in  FIG. 3C , and thread sealant. Exemplary embodiments of the present invention may also provide shielding the testing cable from electromagnetic interference. For example, plating of the cylinder, backshell, and conduit assembly with a conductive metal and using a conductive o-ring between the cylinder and backshell may provide effective electromagnetic interference shielding. 
     In accordance with an exemplary embodiment of the present invention, a given conduit assembly  40 -A,  40 -H, or  40 -W is interchangeable and can be combined with different sets of cylinder-backshells, each backshell providing a different slot configuration and respective cylinders accommodating the slot excursions. 
       FIG. 11  illustrates an exemplary method for swiveling an electrical harness in accordance with an exemplary rotatable adapter embodiment of the present invention. A method of swiveling a rotatable adapter wiring harness includes acquiring a wiring harness with: a slotted backshell; a cylinder housed in the backshell; a cable conduit housing a cable and joined perpendicular to the cylinder and extending through the slot; and an electrical connector connected to the cable and fixed to a bottom of the backshell  1100 . Further, the method continues by using the cylinder as a swivel bushing  1105  and rotating the conduit secured to the cylinder within the slot opening  1110  to swivel a rotatable adapter wiring harness. An exemplary method may further include limiting vertical displacement of the conduit connector via a slot height which is near a conduit connector diameter  1115 . Limitation of lateral rotation is also desirable; hence the exemplary method provides using a front edge of the slot as a first lateral rotational stop  1120  and using a back edge of the slot as a second lateral rotational stop  1125 . An exemplary method further includes a minimum rotation, using a slot width which affords a lateral rotational displacement of the conduit connector within the slot of at least 90 degrees  1130 . In alternate embodiments a maximum lateral rotation can be as little as single digit degrees or in still alternate embodiments  180  degrees rotation maybe enabled. By providing a slack in that portion of the cable housed within the cylinder and backshell  1135 , torsional and or tensile stress on the conducting wires is minimal and the integrity of the cable is preserved across repeated manipulations of the wiring harness  1140 , such as the rotating of the conduit connector within the slot relative to the electrical connector. 
       FIG. 12  illustrates an exemplary method for swiveling an electrical harness in accordance with an exemplary window embodiment of the present invention. A method of rotating a wiring harness includes acquiring a wiring harness with: a window slotted backshell; a cylinder housed in the backshell; a cable conduit housing a cable and joined perpendicular to the cylinder and extending through the window slot; and an electrical connector connected to the cable and fixed to a bottom of the backshell  1200 . By using the cylinder as a swivel bushing  1205 , the user can turn the cable conduit within the window slot  1210  relative to the electrical connector. The exemplary method further includes using a slot height which affords vertical displacement of the conduit connector within the window slot  1215 . Positive stops for displacement of the conduit connector, in accordance with the exemplary embodiment of  FIG. 12  may be provided as follows: using a top edge of the window slot as an upwards, or first, vertical stop  1220 , using a bottom edge of the window slot as a downwards, or second, vertical stop  1225 ; using a front edge of the window slot as first lateral rotational displacement stop  1230 ; and using a back edge of the window slot as a second lateral rotational displacement stop  1235 . The range of the lateral rotational displacement may be determined by the width of the slot, in accordance with the exemplary method of  FIG. 12 , using a slot width which affords a lateral rotational displacement of at least 90 degrees  1240  is desired. In alternate embodiments, a narrower slot width or a wider slot width may be used. Providing slack in that portion of the cable housed within the cylinder and the backshell  1245  reduces stress on the cable associated with movement of the conduit and cylinder while rotating the conduit connector within the slot relative to the electrical connector  1250 . 
       FIG. 13  illustrates an exemplary method for swiveling an electrical harness in accordance with an exemplary helical embodiment of the present invention. An exemplary method to rotate a wiring harness in a helical pattern, in accordance with an exemplary method of the present invention entails, acquiring a wiring harness having: a helical slotted backshell; a cylinder housed in the backshell; cable conduit housing a cable, attaching perpendicular to the cylinder, and extending through the helical slot; and an electrical connector connected to the cable and fixed to a bottom of the backshell  1300 . Having acquired a harness, the method continues with using the cylinder of the harness as a swivel bushing  1305  and translating the conduit secured to the cylinder within the helical slot opening  1310 . A method of swiveling a harness in accordance with the present invention may further include using a helical slot which affords a vertical displacement of the conduit connector along the helical slot path  1315 , using a top edge of the window slot as a first or upper vertical stop  1320 , and using a bottom edge of the window slot as a second or lower vertical stop  1325 . Lateral translation can be limited by using a front edge of the slot as a first lateral rotational stop  1330  and using a back edge of the slot as a second lateral rotational stop  1335 . The magnitude of the potential lateral rotation within the helical slot can be set by using a slot width which affords a desired lateral rotational displacement, for example, of at least 90 degrees  1340 . The exemplary method further includes providing slack in that portion of the cable housed within the cylinder and backshell  1345 , which reduces stress on the cable wires housed in the harness and electrically connected to the interface connector during displacement of the conduit and rotation of the swivel bushing, the cylinder. Limiting the vertical displacement of the conduit connector to the helical path  1355  can be achieved by using a helical slot height near the external diameter of the conduit connector  1350 . 
       FIG. 14  illustrates an exemplary method of manufacturing a rotatable adapter embodiment of an electrical harness in accordance with an exemplary embodiment of the present invention. The method includes machining a slot in a backshell  1400  and tapping a hole in a cylinder, sized to receive a cable conduit connector  1405 . Manufacturing continues with inserting the cylinder into the backshell  1410 , aligning the tapped hole within the slot in backshell  1415 , and mating the external threads on the conduit connector with the internal threads of the tapped hole in the cylinder  1420 . The backshell, in accordance with embodiments of the present invention has an external step on its lower end; catching this backshell ledge on an upper collar of a coupling nut  1425  is part of the exemplary method as shown in  FIG. 14 . A top of an electrical connector employed in a wiring harness in accordance with embodiments of the present invention has a tapered top  62 -A, as shown, for example, in  FIG. 3D . Referring again to  FIG. 14 , configuring an inside diameter backshell profile at its bottom end to equal an outside diameter profile of an electrical connector at its top end  1430  and inserting the electrical connector top into the bottom of the backshell  1435  seats the electrical connector into the backshell. Then, mating external threads on an electrical connector to internal threads of a lower portion of the coupling nut  1440  and securing the electrical connector to the backshell via the coupling nut  1445  mechanically secures the electrical connector to the backshell of the harness. The manufacturing method may further include chamfering a bottom edge of the cylinder  1450 . 
     Machining a slot height nearly equal to a conduit connector diameter  1455  can provide a limiting of vertical displacement of the conduit connector via the height of the slot  1460 . Limiting the rotation of the harness can be provided by the slot configuration. Machining a slot width which affords a lateral rotational displacement of the conduit connector within the slot of at least 90 degrees  1465  and using a front edge of the slot as a first lateral rotational stop  1470  and a back edge of the slot as a second lateral rotational stop  1475  may be employed in a manufacturing method, in accordance with an exemplary embodiment of the present invention. And finally, though not necessarily last, providing slack in that portion of a cable housed within the cylinder and the backshell  1480  reduces stress in the housed wiring and in turn improves reliability with repeated use. The method of providing slack in the cable housed within the cylinder and backshell may be used in all method embodiments for manufacturing a rotatable adapter, helical or window wiring harness in accordance with the present invention. 
       FIG. 15  illustrates an exemplary method of manufacturing a helical embodiment of an electrical harness in accordance with an exemplary embodiment of the present invention. The method may begin with machining a helical slot in a backshell  1500  and tapping a hole in a cylinder, sized to receive a cable conduit connector  1505 . The method as described and shown in  FIG. 15  need not be performed in numerical order. With a slot present, inserting the cylinder into the backshell  1510  and aligning the tapped hole within the helical slot in backshell  1515  readies the receptacle in the cylinder for the conduit connector such that screwing the conduit connector into the tapped hole in the cylinder will mechanically secure the cable housing conduit to the cylinder  1520 . The backshell in a helical embodiment in accordance with the present invention has an outer step or ledge  35 -H at its lower end, shown for example in  FIG. 6D . Also shown in  FIG. 6D  is a tapered top end  62 -H of the electrical interface connector of the present invention. Referring again to  FIG. 15 , Configuring an inside diameter backshell profile at its bottom end to equal an outside diameter profile of an electrical connector at its top end  1530 , inserting a retaining ring into a bottom inside of the backshell beneath a bottom edge of the cylinder  1535 , inserting the electrical connector top into the bottom of the backshell  1540  seats the electrical connector in the harness. Then, catching a backshell ledge on an upper collar of a coupling nut  1525  and mating external threads on an electrical connector to internal threads of a lower portion of the coupling nut  1550  provide securing of the electrical connector to the backshell via the coupling nut  1555 . In accordance with an exemplary method placing an o-ring into an inside coupling nut surface  1545  may be performed to seal the harness between the coupling nut and the backshell. 
     Still referring to  FIG. 15 , the method of manufacturing a helical wiring harness in accordance with an exemplary method of the present invention may also include chamfering an inside wall bottom edge of the cylinder  1560 , cutting a channel in a bottom portion of the cylinder on its outside  1565 , and/or inserting an o-ring in the cylinder channel  1570 . Limiting the range of motion of the conduit connector may be desired. The present invention includes exemplary methods for limiting and facilitating the range of motion of the conduit connector with the swiveling of the cylinder to which the connector is attached. Machining a slot height near the diameter of the conduit connector  1575  affords limiting vertical displacement of the conduit connector via the length of the helix  1580 . The exemplary method continues with machining a helical slot width which affords a lateral displacement of the conduit connector along the helical slot path  1585 , forming a front edge of the helical slot as a first lateral displacement stop  1590 , and forming a back edge of the slot as a second lateral displacement stop  1595 . By using slack in the cable housed within the cylinder and the backshell, shown for example in  FIG. 14   1480 , motion induced stress on the cable is reduced. Using the stops to limit the range of motion contributes to limiting potential tensile and torsional stress on the cable and serves as a guide for desired cable slack. 
       FIG. 16  illustrates an exemplary method of manufacturing a window height embodiment of an electrical harness in accordance with an exemplary embodiment of the present invention. An exemplary method of manufacturing machining a window height harness includes: machining a window slot in the sidewall of a backshell  1600 ; tapping a hole in a cylinder, sized to receive a cable conduit connector  1605 ; inserting the cylinder into the backshell  1610 ; aligning the tapped hole within the backshell slot  1616 ; and mating the external threads on a conduit connector to the internal threads of the tapped hole  1620 , securing the cable housing conduit into the cylinder. The method may further include any or all of the following: catching a backshell ledge on an upper collar of a coupling nut  1625 ; configuring an inside diameter backshell profile at its bottom end to equal an outside diameter profile of an electrical connector at its top end  1630 ; inserting a retaining ring into a bottom inside of the backshell beneath a bottom edge of the cylinder  1635 ; inserting the electrical connector top into the bottom of the backshell  1640 ; inserting an o-ring in an inside surface of the coupling nut  1645 ; mating external threads on an electrical connector to internal threads of a lower portion of the coupling nut  1650 ; securing the electrical connector to the backshell via the coupling nut  1655 ; chamfering a bottom edge of the cylinder  1660  along its inner circumference; cutting a channel in a bottom portion of the cylinder on its outside surface  1665 ; inserting an o-ring into the cylinder channel  1670 ; machining a slot height in excess of a conduit connector diameter  1675 ; affording vertical displacement of the conduit connector via the height of window slot  1680 ; machining a slot width which affords a lateral rotational displacement of the conduit connector within the slot  1685 ; using a front edge of the window slot as a first lateral rotational stop  1690 ; using a back edge of the slot as a second lateral rotational stop  1692 ; using a top edge of the window slot as a first vertical displacement stop  1694 ; and using a bottom edge of the slot as a second vertical displacement stop  1696 . 
       FIG. 17  shows a front perspective view of an electrical connector and a backshell, in accordance with an exemplary embodiment of the present invention. The anti-rotational teeth  31 -W-a on the backshell  30 -W are seated in the anti-rotational teeth  60 - 2 -W-b on the connector  60 -W. The connector  60 -W is shown fully inserted into the backshell  30 -W. In accordance with the exemplary embodiment shown in  FIG. 17 , the teeth ratio from backshell  30 -W to connector  60 -W is 1:5. Other ratios, to include 1:1, may be desired in alternate embodiments. The connector teeth  60 - 2 -W-b are positioned just above the external threads  67 -W of the connector  60 -W upon ledge  60 - 2 -W, ledge shown in  FIG. 9E . The coupling nut is not shown in  FIG. 17 , permitting a clear view of the anti-rotational teeth. Referring again to  FIG. 17 , also shown is the ledge  35 -W on the backshell  30 -W. The backshell ledge  35 -W which will be caught by collar  22 -W of the coupling nut  20 -W are shown, for example, in  FIG. 9E . In accordance with exemplary embodiments of the present invention, the anti-rotational teeth across the backshell and connector interface keep the backshell from rotating relative to the connector, while swiveling of the cable conduit is afforded via the cylinder bushing. At the same time, the coupling nut keeps the backshell mechanically secured to the connector. Though shown with the window designation, helical and rotational adapter embodiments of the present invention may also incorporate an anti-rotational teeth interface between the electrical connector and the backshell. 
     An exemplary rotatable adapter wiring harness was manufactured and field tested on an F-22 aircraft. The interface connector was attached to the desired test point connector and the conduit was repositioned across the lateral rotational range afforded by the rotatable adapter wiring harness prototype. The wiring harness was made from aluminum. A rotation angle of 150 degrees was utilized in the field. The results of the testing protocol support a reliable performance mechanically and electrically for a wiring harness in accordance with embodiments of the present invention. Embodiments of the present invention may provide a lateral rotational angle of 270 degrees. 
     By providing a slack in that portion of the cable housed within the cylinder and backshell, torsional and or tensile stress on the conducting wires is reduced and the integrity of the cable is preserved across repeated manipulations of the wiring harness. 
     The present invention allows adjustments to be made in real time to the orientation of a cable leg with respect to an interfacing connector. When mating interfacing connectors and corresponding cable assemblies to testing connectors on an aircraft hardware may create physical access constraints and electrical components may cause signal interference issues. The ability to adjust the position of the conduit leg housing the connecting cable or the interfacing connector relative to the same around these obstructions may permit the use of a single cable across multiple weapon stations without damaging the cable assembly. Conventionally, cable assemblies that do not swivel, may be permanently configured for the specific weapon station they will be mated to. This singular application can result in the need for several cables to perform the same field tasks that could be performed with one embodiment of the present invention. A single adjustable and rotatable cable and connector assembly instead of multiple cable and connector assemblies may permit decreased weight to a test kit, such as those used on the flight line. Further, the adjustable cable and connector assembly can decrease testing time in the field for an aircraft maintainer. The reduction in cables afforded by a rotatable assembly in accordance with the present invention may reduce the initial and maintenance costs of test kits which in include the same. 
     Other applications, which could benefit from the present invention, include testing of weapons systems. Cable assemblies that do not have the swivel feature may have to be configured for the specific weapon station they will be mated to. This can result in the need for several cables to perform the same task as one with an adjustment feature. Being able to use one cable instead of multiple cables to serve the same purpose allows for decreased weight to an overall kit. It may also reduce maintainer man hours for performing on aircraft tests. Further, still, a reduction in cabling afforded by a movable harness may reduce the cost of the test kit. The present invention is readily adapted to high heat environments using material such as aluminum or stainless steel. In alternate embodiments, a lighter weight material, such as plastic may be used for the cylinder, the backshell and other components described herein. In still other embodiments, an alternate slot configuration may be desired, in accordance with the present invention. Aircraft as an on craft application is also exemplary and other applications may be desired on, for example, watercraft, land-craft, spacecraft, or missile craft. 
     Although embodiments for a rotatable wiring harness have been described in language specific to structural features and/or methods, it is to be understood that the appended claims are not necessarily limited to the specific features or methods described. Rather, the specific features and methods are disclosed as exemplary implementations. While specific alternatives to steps of the invention have been described herein, additional alternatives not specifically disclosed but known in the art are intended to fall within the scope of the invention. Thus, it is understood that other applications of the present invention will be apparent to those skilled in the art upon reading the described embodiment and after consideration of the appended claims and drawings.