| DE9408883U1 | 1994-07-28 | |||
| GB2198605A | 1988-06-15 | |||
| DE29515545U1 | 1995-11-23 | |||
| US5373277A | 1994-12-13 |
Gill, David Alan (W.P. Thompson & Co. Celcon House 289-293 High Holborn London WC1V 7HU, GB)
| 1. | A filter apparatus, which filters signals transmitted through a pair of electrically conducting signal carriers, comprising: a pair of filter elements, each of said filter elements positioned to filter electrical signals transmitted through a corresponding one or said signal carriers without electrically contacting said signal carrier; and a pair of guides, each of said guides positioned to maintain position of a corresponding one of said signal carriers in a predetermined positional relationship to said pair of filter elements, said guides positioning and securing said signal carriers in said predetermined positional relationship in response to manual positioning of said signal carriers upon a preformed structure of said guides. |
| 2. | A filter apparatus as set forth in Claim 1 further comprising a second pair of guides each of said guides positioned to maintain a corresponding one of said signal carriers in said predetermined positional relationship to a corresponding one of said filter elements. |
| 3. | A filter apparatus as set forth in Claim 1 wherein said filter elements comprise ferrite elements. |
| 4. | A filter apparatus as set forth in Claim 1 further comprising a housing comprising an interior portion accessible by opening a first body portion of the housing and wherein said pair of filter elements and said pair of guides are disposed within said housing. |
| 5. | A filter apparatus as set forth in Claim 4 wherein said housing further comprises a first opening, through which said signal carriers pass to enter said interior portion. |
| 6. | A filter apparatus as set forth in Claim 5 wherein said housing further comprises a second opening, through which said signal carriers pass to exit said interior portion. |
| 7. | A filter apparatus as set forth in Claim 6 wherein said housing further comprises a second body portion and wherein said first body portion is moveably attached to said second body portion. |
| 8. | A filter apparatus as set forth in Claim 6 wherein said housing further comprises a second body portion and wherein said first body portion is separable from said second body portion. |
| 9. | A filter apparatus as set forth in Claim 1 further comprising: a pair of c {m ttcts, each of said contacts positioned to make electrical contact with a corresponding one of said signal carriers; and a second filter element electrically coupled between said contacts. |
| 10. | A filter apparatus as set forth in Claim 9 wherein said second filter element comprises a capacitor. |
| 11. | A filter apparatus as set forth in Claim 10 further comprising a third filter element electrically coupled to said contacts. |
| 12. | A filter apparatus as set forth in Claim 11 wherein said third filter element comprises a surge protection element. |
| 13. | A filter apparatus as set forth in Claim 9 wherein each signal carrier of said pair of signal carriers is surrounded bv an electrical insulating material and wherein each contact of said pair of contacts contact corresponding one of said pair of signal carriers on a contact surface of said contact which pierces said electrical insulating material when said corresponding signal carrier is manually pressed against said contact surface. |
| 14. | A filter apparatus as set forth in Claim 9 further comprising: a second pair of contacts each of said second pair of contacts positioned to make electrical contact with a corresponding one of said signal carriers; a fourth filter element electrically coupled to said contacts; and a fifth pair of filter elements, each of said fifth pair of filter elements electrically disposed between a corresponding of said first pair of contacts and a corresponding one of said second pair of contacts, said first and said second pair of contacts jointly maintaining position of said pair of signal carriers in a predetermined positional relationship to said fifth pair of filter elements. |
| 15. | A filter apparatus as set forth in Claim 14 wherein said fifth pair of filter elements are not in electrical contact with said pair of signal carriers. |
| 16. | A filter apparatus as set forth in Claim 14 wherein said fourth filter element comprises a capacitor coupled between said pair of said signal carriers. |
| 17. | A filter apparatus as set forth in Claim 16 further comprising a sixth filter element electrically coupled to said contacts. |
| 18. | A filter apparatus as set forth in Claim 17 wherein said sixth filter element comprises a surge protection element. |
| 19. | A filter apparatus as set forth in Claim 18 wherein said fifth pair of filter elements comprise ferrite elements. |
| 20. | Apparatus comprising: a housing having a first body portion and a second body portion which mate together to enclose an accessible inner portion of said housing; means, disposed within said inner portion, for filtering signals transmitted through at least a first pair of electrical conductors which pass through said inner portion; and guide means, disposed within said inner portion, responsive to placing of each of said electrical conductors against a predetermined portion of said guide means and application of manual pressure bv an individual, for positioning said electrical conductors into a predetermined positional relationship to said means for filtering and for maintaining said electrical conductors in said predetermined positioned relationship. |
| 21. | Apparatus as set forth in Claim 20 wherein said means for filtering comprises: a first ferrite element electromagnetically coupled to a first of said electrical conductors, said electromagnetic coupling being functionally related to said predetermined positional relationship; and a second ferrite element electromagnetically coupled to a second of said electrical conductors, said electromagnetic coupling being functionally related to said predetermined positional relationship. |
| 22. | Apparatus as set forth in Claim 21 further comprising: a first and second electrical contact, each of said contacts electrically coupled to a corresponding one of said electrical conductors; and a first capacitive element electrically coupled between said contacts. |
| 23. | Apparatus as set forth in Claim 22 wherein said first and said second electrical contents each have a contact surface which makes electrical contact with said corresponding electrical conductor when said electrical conductor is manually pressed against said contact surface. |
| 24. | Apparatus as set forth in Claim 23 wherein at least one of said electrical conductors is surrounded by electrical insulating material and wherein manually pressing said electrical conductor against said contact surface causes said contact surface to pierce said insulating material 1 to make electrical contact with said electrical conductor. |
| 25. | Apparatus set forth in Claim 24 further comprising a surge protection element coupled between said first and said second electrical contacts. |
| 26. | Apparatus as set forth in Claim 25 further comprising: third and fourth electrical contacts, each of said contacts electrically coupled to a corresponding one of said electrical conductors; said means for filtering further comprising a third inductive element electrically coupled to said first of said electrical conductors and a fourth inductive element electrically coupled to said second of said electrical conductors, said third and fourth inductive elements coupled between said corresponding one of said first and second contacts and said third and fourth contacts. |
| 27. | Apparatus as set forth in Claim 26 wherein said means for filtering further comprises a second capacitive element electrically coupled between said third and fourth electrical contacts. |
| 28. | Apparatus as set forth in Claim 27 wherein said guide means comprises: first and second guide pushposts which maintain said first of said electrical conductors in said predetermined positional relationship; and third and fourth guide pushposts which maintain said second of said electrical conductors in said predetermined positional relationship. |
| 29. | Apparatus as set forth in Claim 20 further comprising: means, disposed within said inner portion, for severing each of said electrical conductors, said means for severing being resposire to application of manual pressure by said individual; wherein said electrical conductors are each surrounded by electrical insulating material and wherein manually pressing one of said electrical conductors against a corresponding cutting surface of said guide means causes said cutting portion to pierce said insulating material to make electrical contact with said corresponding electrical conductor; said guide means being electrically coupled to said means for filtering. |
| 30. | Apparatus as set forth in Claim 29 wherein said means for filtering comprises an LC ladder clampon filter. |
| 31. | A manually actuated filter comprising: a substrate; a plurality of filter elements disposed upon said substrate; a first guide and a second guide each disposed upon said substrate and each comprising a signal carrier holding portion for holding a signal carrier in a predetermined positional relationship with at least a first of said plurality of filter elements, said holding portion being actuated by manual pressure of said signal carrier against said holding portion. |
| 32. | A manually actuated filter as set forth in Claim 31 wherein said second guide is electrically coupled to at least a second of said plurality of filter elements, and wherein said holding portion of at least said second guide comprises a cutting surface which pierces an insulating layer of said signal carrier to electrically couple said signal carrier to said second of said plurality of filter elements. |
| 33. | A manually actuated filter as set forth in Claim 32 wherein said first of said filter elements comprises a ferrite element. |
| 34. | A manually actuated filter as set forth in Claim 32 wherein said second of said filter elements comprises a capacitive element. |
| 35. | A manually actuated filter as set forth in Claim 34 further comprising a third guide and a fourth guide disposed upon said substrate, said third guide and said fourth guide each comprising a signal carrier holding portion for holding a second signal carrier in a predetermined positional relationship with at least a third of said plurality of filter elements, said holding portion being actuated by manual pressure of said second signal carrier against said holding portion, and wherein said holding portion of said fourth guide comprises a cutting surface which pierces an insulating layer of said second signal carrier to electrically, couple said second signal carrier to said second of said plurality of filter elements. |
| 36. | A manually actuated filter as set forth in Claim 35 further comprising a manually actuated cutting element disposed upon said substrate, said cutting element comprising a cutting portion which severs said signal carrier in response to manually applied pressure to said cutting portion. |
| 37. | A manually actuated filter as set forth in Claim 36 wherein said substrate comprises a housing which comprises a first portion and a second portion which mate together to form an inner portion and wherein said plurality of filter elements and said first, second, third and fourth guides are each disposed within: said inner portion. |
| 38. | A manually actuated filter as set forth in Claim 31 wherein said substrate comprises a housing which comprises a first portion and a second portion which mate together to form an inner portion and wherein said plurality of filter elements and said first and second guides are each disposed within said inner portion. |
BACKGROUND OF THE INVENTION Sophisticated electronic devices such as computers, facsimile machines and copiers are commonly used in the business environment, and increasingly in the home environment. In the business environment, installation of electronic devices is frequently performed by trained personnel equipped with any necessary tools. In the home environment, cost considerations often require that electronic devices be installable by the average consumer to reduce the costs associated with professional installation. As a result, electronic devices used in the home require simplicity of installation for widespread consumer acceptance.
In general, many electronic devices are self-contained and thus do not require professional installation in either the home or the business environment.
(computer networks are one notable exception. Typically, such networks require installation of appropriate wiring, together with specialized electronic devices to ensure proper network operation. Pending U. S. Patent application entitled"HOME AREA NETWORK SYSTEM AND METHOD" (Ser. No.: 08/924,449),-filed on August 28.1997, which is assigned to the assignee of the present application describes a local area network which may be used within a home using existing Plain Old Telephone Service (POTS) Unshielded Twisted Pair (UTP) wiring at a customer premises. As described in the aforesaid patent application, such a system advantageously allows conventional POTS wiring, which is already installed in the home, to be used for both conventional call sending and receiving and at the same time to be used for computer networking. As further described in the aforesaid
patent application, a passive low pass filter may be located at the Telephone Network Interface (TNI) at the demarcation between the subscriber loop and the customer premises to improve network performance.
Installation of a local area network in the home such as described in the aforesaid patent application would be greatly simplified and therefore far more desirable for potential users and customers if the aforesaid filter could easily be installed without the use of tools or specialized knowledge. Other types of filters or electrical devices would also benefit from such features.
SUMMARY OF THE INVENTION In a principal aspect, the present invention provides simplified installation of a filter or similar type of electronic device. In accordance with the principal aspect of the invention, a signal carrier is electrically coupled to a filter by manual coupling of the signal carrier to appropriate components of the filter apparatus.
Advantageously, no tools are required to sever the signal carrier or to position the signal carrier into an appropriate position to enable operation of the filter upon signals transmitted on the signal carrier.
In certain embodiments, the filter max, contain filtering elements which modify the signals in the signal carrier in a desired way without electrically contacting the signal carrier. Alternatively, or in addition, the filter may also include filter elements which electrically contact the signal carrier. In the former embodiment, filters employing the principles of the present invention may contain guides which are actuated bv manual force to hold the signal carriers in a predetermined positional relationship to the filter elements. In the latter embodiment, the guides contain a cutting surface which pierces an insulated layer of the signal carriers when the signal carriers are manually pressed against an appropriate portion of the guides. The filter elements may include ferrite elements, capacitive elements, clamping devices and other elements which modify electrical signals.
Embodiments employing the principles of the present invention, advantageously allow coupling of signal carriers to the filter without use of tools and, consequently, are easy to use and present fewer risks of misoinstallation or breakage due to improper use of tools or use of improper tools.
These and other features and advantages of the invention will be understood by considering the following detailed description of certain preferred embodiments. In the course of this description, reference will be made to the attached drawings.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 shows a top view of a first embodiment of an apparatus which employs the principles of the present invention.
Figure l (a) is an electrical schematic diagram implemented by the apparatus of Figure 1.
Figure l (b) shows a side view of element 26 of Figure 1.
Figure l (c) shows a side view of element 12 of Figure 1 in a closed position.
Figures l (d) and l (e) show alternative embodiments of a side view of element 1 of Figure 1 in an open position.
Figure 1 (f) shows a side view of elements 22 together with a cross-sectional view of element 16 of Figure 1.
Figures l (g) and 1 (h) show side views of alternative embodiments of element 22 of Figure 1.
Figures 1 (i) and 1 (j) show alternative embodiments of element 23 of Figures l (g) and 1 (h).
Figure 2 shows a top view of a second embodiment of an apparatus which employs the principles of the present invention.
Figure 2 (a) shows an electrical schematic diagram of a filter implemented by the apparatus of Figure 2.
Figure 2 (b) shows a side view of element 50 of Figure 2 (a).
Figure 2 (c) shows a top view of a layout of electrical and mechanical components of the apparatus of Figure 2.
Figure 3 shows a top view of a third embodiment of an apparatus which employs the principles of the present invention.
Figure 3 (a) shows an electrical schematic diagram of a filter implemented by the apparatus of Figure 3.
Figure 3 (b) shows a top view of a layout of electrical and mechanical components of the apparatus of Figure 3.
Figure 4 shows a top view of a fourth embodiment of an apparatus which employs the principles of the present invention.
Figure 4 (a) shows an electrical schematic diagram of a filter implemented by the apparatus of Figure 4.
Figure 4 (b) shows a top view of a layout of electrical and mechanical components of the apparatus of Figure 4.
Figure 4 (c) shows a side view of element 70 of Figure 4 in an open position.
Figure 4 (d) shows a side view of element 70 of Figure 4 in a closed position.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS For ease of reference, like elements in the following description are labeled with the same reference numbers, and multiple instances of the same element are labeled with the same reference number together with a suffix to individually designate the specific instance of the element. For example, in the following description, element 26, which is shown in numerous places, is labeled and referred to individually as 2, etc. Reference to each instance of an element is made without use of the suffix. For example a reference to element 26 refers to all instances (26.1,26.2, etc.) of element 26.
The embodiments shown in the drawings and described herein are particularly well adapted for use in a home based local area network such as
described in aforementioned patent application, Ser. No. 08/924,449, entitled "HOME AREA NETWORK SYSTEM AND METHOD"filed on August 28, 1997, which is hereby incorporated by reference. Such embodiments however may find use-in a number of other contexts. Moreover, as will become apparent to those skilled in the art in view of the following description, numerous modifications may be made to the embodiments disclosed herein.
Turning to Figure 1, filter apparatus 10 includes a housing 12 which includes an interior portion 14. Interior portion 14 receives a pair of signal carriers 16 (shown individually as 16.1 and 16.2) through an opening 18 in the housing 12.
Signal carriers 16 take the form of conventional POTS UTP wiring used in a customer premises. Such wiring typically takes the form of several twisted pairs of individually insulated copper wires. In each pair of wires, one wire is typically designated a"tip"wire and the other wire is typically designated as a"ring"wire.
Ferrite elements 22 (shown individually as 22.1 and 22.2) filter signals transmitted by signal carriers 16. The signal carriers exit through a second opening 20 of the housing 12. Signal carriers 16.1 and 16.2 are designated upon exiting filter 10 as 16.1 and 16.2'to indicate the filtered signal carried bv the signal carriers.
Figure l (a) shows a schematic diagram of the filter implemented by the filter apparatus 10 of Figure 1. Ferrite elements 22.1 and 22.2 are shown in Figure l (a) as inductive elements 22.1 and 22.2 coupled in series with signal carriers 16.1 and 16.2 respectively Figure I shows a lower portion of ferrite elements 22.1 and 22.2.
As explained in further detail below, housing 12, in certain embodiments, includes an upper portion which contains a corresponding upper portion to the ferrite elements 22.1 and 22.2. Those skilled in the art will appreciate that ferrite materials may only loosely be described as providing the function of the "inductors,"shown schematically in Figure l (a). Typical ferrite materials, such as ferrite elements 22, are composed of ferromagnetic materials that can be magnetized to produce large magnetic flux densities in response to small applied magnetization forces (such as from signals on signal carriers 16). Ferrite materials exhibit magnetic properties which are dependent on the frequency at which they
are excited. At high frequencies, typical ferrite materials are best viewed as frequency dependent resistors that attenuate the higher frequency components of signals which pass through the ferrite material. The ferrite elements 22 can be used to a low pass filter, such as described in the aforesaid patent application (Ser. No.), to attenuate signals above approximately 1.1 MHz.
Ferrite elements 22.1 and 22.2 are each shown in Figure 1 as taking the form of a rectangular shaped block containing a groove (23.1 and 23.2 respectively) to accept, and to guide, the corresponding signal carrier 16.1 or 16.2.
As shown in side view m Figure l (g), ferrite elements 22.1 and 22.2 are physically Separate and are therefore unconnected electrically. Figure l (g) shows the top portion of the ferrite elements together with the lower portion shown in top view in Figure 1. In Figure l (g), the lower portion of the ferrite elements 22.1 and 22.2 are designated respectively as 22. la and 22.2b and the upper portions are designated respectively and 22.1 b and 22.2b. The upper portion of each of the ferrite elements is preferably affixed to upper portion 15 of the housing 12, and is preferably aligned with the corresponding lower portion, as shown in Figure l (g), to form a conducting pathway between the upper portion and the lower portion when the housing is in a closed position such as shown in Figure l (c).
Figure 1 (h) shows an alternative embodiment where the ferrite elements 22.1 and 22.2 are formed out of a single block of ferrite material with two grooves, 23.1 and 23.2, formed therein to accept and to guide signal carriers 16.1 and 16.2 respectively. If the ferrite elements 22.1 and 22.2 are separate, then the elements will introduce differential mode attenuation into signals transmitted by signal carriers 16. If the ferrite elements 22.1 and 22.2 are joined bv virtue of being formed from a single block, then the elements will advantageously introduce both differential mode and common mode attenuation into signals transmitted by signal carriers 16.
Ferrite elements 22.1 and 22.2 are each positioned to allow a corresponding signal carrier 16 to-ass through groove 23.1 or 23.2 in the ferrite element 22.1 or 22.2 so as to inductively couple signals within signal carriers 16.1 and 16.2. The
exact manner in which the groove is formed in the ferrite is not critical. Figures l (g) and 1 (h) show an embodiment in which the grooves 23.1 and 23.2 are formed entirely in the lower portion of the ferrite element. Alternatively, as shown in Figures l (i) and l (j), the grooves 23.1 and 23.2 may be formed partially in the upper and the lower portions of the ferrite element. The predetermined positional relationship of the signal carriers to the corresponding ferrite element determined primarily by the corresponding groove 23 and is facilitated bv guide push posts 26.
Guide push posts 26.13 and 26.1 b maintain signal carrier 16.1 in predetermined positional relationship with ferrite element 22.1. Guide push posts 26.23 and 26.2b maintain signal carrier 16.2 in predetermined positional relationship with ferrite element 22.2. The positional relationships shown in the drawings are merely one example of the positional relationships which may be achieved. Other positional relationships may be achieved by varying the size of the grooves 23. The precise positional relationship of the ferrite elements to the signal carriers varies depending upon the filtering effect desired. Maximum filtering effect is typically achieved bv having a tight fit of the signal carrier 16 in a corresponding groove 23.
A side view of guide push posts 26 is shown in Figure 1 (b). Guide push posts 26 as shown in Figure l (b) take the form of a slot 30 into which a signal carrier 16 is pressed. Advantageously, slot. 30 of the guide push post 26 has a width which allows the signal carrier 16 to be manually pressed into the slot while constraining the signal carrier to maintain a predetermined positional relationship between the signal carrier and the associated ferrite element. The guide push post 26 shown in Figure l (b) is merely one example of the form which the guide push post may take. The exact structure used to hold the signal carriers 16.1 and 16.2 in positional relationship to the associated ferrite element is not critical. As a consequence, the guide push posts may be replaced with any number of structures which allow the signal carriers to be manually positioned into the predetermined positional relationships and which maintain the signal carriers in such position.
Figure l (f) shows a side view of the ferrite element with the corresponding signal carrier. As shown in Figure l (f), signal carrier 16.1 includes a conductor 32
surrounded by a insulating material 34. Ferrite element 22.1 is positioned in predetermined positional relationships 36 and 38 respectively with respect to signal carrier 16.1. Signal carrier 16.2 takes the same form as signal carrier 16.1 and is similarly positioned with respect to ferrite element 22.2 The ferrite elements 22 are merely one example of an inductive type filter element which can be used in accordance with the principles of the present invention. Advantageously, the ferrite elements 22 provide filtering of the signals contained in signal carriers 16.1 and 16.2 without requiring the use of tools or complex installation procedures to couple the filtering element to the signal carrier.
All that is required is the signal carrier be inserted into guide push posts 26 and 28 and groove 23 to place and secure the signal carriers in the predetermined positional relationship with the ferrite element. The exact type of the ferrite element 22 however, is not critical.
The housing 12 provides structural integrity and physical protection for the devices contained within the housing. Preferably, the housing is formed of plastic or other non-conducting material to minimize any parasitic capacitive and inductive coupling which may occur between the signals on the signal carrier and the filter apparatus. additionally"such a housing allows physical placement of the filter apparatus in areas with exposed live electrical elements.
Although providing the foregoing advantages, a housing is not necessary and is not required. In embodiments which have no housing, and thus have the advantage of lower cost, the lower portion 13 of the housing 12 takes the form of a rigid or substantially rigid material upon which the various components of the filter apparatus are mounted. In such embodiments, the ferrite element may be modified to a structure which allows surrounding, either completely or substantially, of the signal carriers with the ferrite element to achieve a desired filtering effect.
Alternatively, a filter such as shown in Figure 4 may be used to eliminate use of ferrite materials.
Figures l (c), l (d) and l (e) show side views of the housing 12. In Figure l (c), housing 12 is shown as having lower portion 13 and an upper portion 15. Lower
portion 13 is shown from a top view in Figure 1. The housing 12 is shown in Figure l (c) in a closed position. Figures l (d) and l (e) show alternative embodiments of the housing 12. In Figure l (d), upper portion 15 is mounted to lower portion 13 bv way of a hinge type mechanism 37 which allows upper portion 15 to rotate into an open position as shown in Figure l (d) to allow access to inner portion 14. In Figure l (e), upper portion 13 is held in closed position to lower portion 15 by way of prongs 39.1 and 39.2 which secure upper portion 15 to lower portion 13. Figures l (d) and l (e) merely show two examples of ways of which the upper portion 15 may be attached to the lower portion 13. The exact manner of attachment is unimportant so long as the filter apparatus can easily be opened manually to allow access to the inner portion 14. In addition, the exact shape of the housing is unimportant and may take any one of a number of shapes.
Moreover, the housing may include other apparatus and other electrical and mechanical devices and need not be limited to only the filter apparatus 10.
The apparatus 10 of Figure 1 may be termed a"zero-terminal"type filter because there are no direct electrical connections between the filter and the signal carriers 16. The filter therefore has no"terminals"to which the signal carriers are coupled. The embodiment of Figure 2 shows a"two-terminal"type filter apparatus (40) which embodies the principles of the present invention. Filter apparatus 40 takes the form of a two-terminal filter by use of contact push posts 50.1 and 50.2 which make electrical contact with signal carriers 16.1 and 16.2 respectively.
Filter apparatus 40 is similar to filter apparatus 10 described in connection with Figure 1 except that guide push posts 26.1 b and 26.2b of apparatus 10 are replaced in apparatus 40 with contact push posts 50.1 and 50.2. Contact push posts which are shown in side view in Figure 2 (b) maintain the predetermined positional relationship of each signal carrier 16 with respect to ferrite elements 22 and also contain cutting surfaces 52 to pierce insulating material 34 of the signal carrier 16 to form an electrical contact between contact push post 50 and the corresponding signal carrier 16. This advantageously allows a direct electrical connection between the signal carrier 16 and filter elements such as shown in Figure 2 (a)
which shows an electrical schematic of a filter implemented by filter apparatus 40.
The exact structure of the contact push post 30 is not critical and may take any form which allows the insulating layer of the wire to be pierced to make positive electrical contact with the signal carrier with the conductor 32 of the signal carrier 16 by use oi manually applied pressure and without the use of tools.
In Figure 2 (a), the apparatus 40 includes ferrite elements 22.1 and 22.2, a capacitor 54.1 coupled between contact push posts 50.1 and 50.2 and a surge protection device 56.1 which may take the iorm of a conventional Metal Oxide Varistor (MOV) which is included to protect the capacitor 54. Preferably, the contact push posts 50.1 and 50.2 form a gas tight contact with the corresponding signal carriers 16.1 and 16.2. The filter apparatus shown in Figures 2 and 2 (a) may be simplified by eliminating the ferrite elements 22, leaving shunt capacitor 54 as the filtering element between the tip and ring conductors 16.2 and 16.1 respectively.
Figure 2 (c) shows a layout of the electrical and mechanical components of the filter apparatus 40 of Figure 2 As shown in Figure 2 (c), capacitor 54.1 and surge protector 56.1 are coupled between contact push posts 50.1 and 50.2. Guide push posts 26 and contact push posts 50 together maintain signal carriers 16 (not shown in Figure 2 (c)) in predetermined positional relationship with ferrite elements 22. The layout of components shown in Figure 2 (c), as with the corresponding figure of the other embodiments disclosed herein, is merely one example of how the components the filter apparatus may be placed. The exact layout of components is not critical and numerous layouts may be used, depending upon manufacturing requirements, limitations of the housing 12 or other considerations.
The filtering characteristics of the filter apparatus 40 of Figure 2 may be improved bv the addition of another pair of contact push posts 50 to allow use of additional ferrite filtering elements in a ladder filter structure. Such an embodiment is shown in Figure 3. In Figure 3, an additional pair of contact push posts 50.3 and 50.4 together with an additional pair of ferrite elements 22.3 and 22.4 are added to implement the filter as shown in Figure 3 (a). As shown in Figure
3 (a), the filter apparatus 60 includes ferrite elements 22.1,22.2,22.3 and 22.4.
Capacitive elements 54.1 and 54.2 are coupled by way of contact pushposts 50 to signal carriers 16. Surge protector 56.1 is coupled in parallel between contact push posts 50.3 and 50.4. Capacitor 54.1 is coupled between contact. push posts 50.1 and 50.2. Guide push post 26.1 and contact push post 50.1 maintain signal carrier 16.1 in predetermined positional relationship with ferrite element 22.1 and contact push posts 50.1 and 50.3 maintain signal carrier 16.1 in predetermined positional relationship with ferrite element 22.3. Guide push post 26.2 and contact push post 50.2 maintain signal carrier 16.2 in predetermined positional relationship with ferrite element 22.2 and contact push posts 50.2 and 50.4 maintain signal carrier 16.2 in predetermined positional relationship with ferrite element 22.4.
Figure 3 (b) shows a top view of a component layout of the elements of Figure 3. As seen in Figure 3 (b), capacitor 54.1 is connected between contact push posts 50.1 and 50.2 and capacitor 54.2 is connected between contact push posts 50.3 and 50.4, as is surge protector 56.
Figure 4 shows an embodiment of a four-terminal device 80 where general arbitrary order high quality LC ladder filters are constructed using capacitors and wire wound inductors. For a four terminal device such as shown in Figure 4 to be realized, the signal carriers 16.1 and 16.2 must be severed and electrical connections must be made in each of the resulting four signal carriers 16.1 and 16.2 and 16.1' and 16.2'. Electrical contact with each of the resulting four signal carriers is made by contact push posts 50.1,50.2,50.3 and 50.4. The signal carriers may be severed by 0 wave of a cutting element 70 shown in side view in Figures 4 (c) and 4 (d). Cutting element 70 is shown in an open position in Figure 4 (c). Wires 16.1 and 16.2 are shown in cross-section placed upon a lower portion 72 of cutting element 70. Cutting element 70 also includes an upper portion 74 which has on a lower surface a cutting portion 76. Cutting portion 76 rnav be constructed of the same material as 5 upper portion 74 or may be constructed of a different material than upper portion 74. Upper portion 74 is depressed manually onto signal carriers 16 into closed position as shown in Figure 4 (d). Upper portion
74 is rotatably coupled to lower portion 72 by way of a hinge type mechanism 78 and is maintained in closed position by any one of conventional means including a detent mechanism in hinge 78 or a prong or similar type device as shown at 82 to hold upper portion 74 tight against lower portion 72. Once cut, it is not necessary for upper portion 74 to be held in tightly closed position as shown in Figure 4 (d).
However, the severed ends of the signal carrier 16 should not contact one another and holding the cutting element in a closed position physically blocks one end of the signal carrier from the other, thus preventing any electrical contact between the two ends of the severed signal carrier. The portion of the cutting element which contacts the signal carrier in the closed position must be non-conducting in order to prevent the cutting element from serving as a conductor to carry electrical signals from one severed end of a signal carrier to another end of the same or other signal carrier. Thus, if the cutting portion 76 of the upper portion 74 is a conducting material, in a closed position the cutting portion should be buried into the lower portion 72 by way of a groove or the like to prevent electrical contact between the cutting portion 76 and signal carrier 16. It should be noted that the exact structure and operation of the cutting element 70 is not critical. The cutting element can take any one of number of different forms so long as it enables severing of signal carriers 16 without the use of tools.
Figure 4 (a) shows an electrical schematic diagram of a filter realized in accordance with the filter apparatus 80 shown in Figure 4. As shown in Figure 4 (a), a plurality of LC-type ladder structures may be implemented as shown as 72.1, 72.2, and 72.3 using inductive elements 84 and capacitive elements 51. In addition, surge protectors 56.1 and 56.2 may be used at both ends of the filter structure. It should be noted that severing the signal carriers 16 allows the use of inductive elements 84 which take the form of conventional inductors connected in series with signal carrier 16.2 as opposed to the inductive ferrite element 22.
Figure 4 (b) shows a top view of the layout of the components of the filter apparatus 80. Contact push posts 50.1,50.2,50.3 and 30.4 implement four terminals to which the surge protectors 56 and LC-type ladder structures 72 are
connected. Capacitor 54.4 in Figure 4 (b) (which is not shown in Figure 4 (a)) may be used to implement an odd order filter.
The filters shown and described herein all take the form of low pass filters which attenuate signals above a particular frequency range. It will be appreciated by those skilled in the art in view of the present disclosure, that the filter apparatus of Figures 1,2,3 and 4 may be modified with additional and/or different components to achieve a multi-band type filter incorporating high pass and low pass portions to filter electrical signals in two or more frequency ranges. Except as specifically noted herein, the specific mechanisms and techniques which have been described are merely illustrative of exemplary applications of the principles of the present invention. Numerous modifications in addition to those described herein max, be made to the methods and apparatus described herein without departing from the true spirit and scope of the invention.