US2727213A - Time-delay network - Google Patents
Time-delay network Download PDFInfo
- Publication number
- US2727213A US2727213A US331848A US33184853A US2727213A US 2727213 A US2727213 A US 2727213A US 331848 A US331848 A US 331848A US 33184853 A US33184853 A US 33184853A US 2727213 A US2727213 A US 2727213A
- Authority
- US
- United States
- Prior art keywords
- coil form
- winding
- core
- sections
- network
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Images
Classifications
-
- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03H—IMPEDANCE NETWORKS, e.g. RESONANT CIRCUITS; RESONATORS
- H03H7/00—Multiple-port networks comprising only passive electrical elements as network components
- H03H7/30—Time-delay networks
- H03H7/32—Time-delay networks with lumped inductance and capacitance
Definitions
- This invention is directed to the structure and method of making time-delay networks of the lumped-parameter type for translating signal components included within a predetermined range of frequencies.
- Time-delay networks have long been known in the art and have taken the form of distributedor lumped-parameter circuits.
- a well-known distributed-parameter delay network in accordance with the prior art comprises at least one distributed winding wound around a supporting, grounded core structure and an associated ground-return path.
- the capacitance between the winding and its core structure supplies the distributed capacitance of the network which, together with the inductance of the winding, determines the total time delay exhibited by the network.
- a time delay of any particular amount may be obtained by appropriately selecting the physical characteristics of the winding and its core structure.
- a lumped-parameter type time-delay network due to its electrical and physical dimensions relatively small as far as volume is concerned and exhibits excellent electrical characteristics in that it is capable of translating signal components included within a relatively wide range of frequencies (for example, -4.5 megacycles) with negligible attenuation at the higher frequencies while imparting an approximately equal time delay to all frequency components. It is also relatively easy to shape the response characteristic of such a network due to the fact that it has many dimensions that may be varied.
- an object of the present invention to provide an improved time-delay network of the lumpedparnmeter type for translating signal components included within a predetermined range of frequencies that is simple and economical in construction.
- t is another object of the invention to provide such an improved network that lends itself to mass production.
- the network includes a distributed winding having a multiplicity of series-connected winding sections individually wound around and supported by an assigned one of the sections of the coil form.
- An elongated core member of dielectric material is positioned within the coil form and has one set of surface portions exposed by the apertures thereof.
- the network further comprises at least one conductive surface on the core in spaced, opposed relation to the exposed portions; and conductive elements disposed in the apertures of the coil form, electrically connected to the winding intermediate successive sections thereof and mechanically connected to the exposed portions of the core to constitute, in conjunction with the conductive surface of the core, shunt-connected condensers for the network.
- the network has input and output connections extending from opposite ends of the winding.
- Figure 1 is a schematic representation, partially cutaway, of a lumped-parameter time-delay network constnicted in accordance with the present invention
- Figure 2 is another view of the embodiment shown in Figure 1;
- Figure 3 is an equivalent circuit diagram of the network of Figures 1 and 2;
- Figure 4 discloses another embodiment of the core member of a delay line constructed in accordance with the invention.
- the time-delay network there represented is of the lumped-i parameter type for translating signal components included within a predetermined range of frequencies. While the illustrated arrangement is of the three-terminal or unbalanced type, the invention is equally applicable to balanced networks.
- the network shown is in the form of a simulated transmission line and comprises an elongated hollow coil form 10, which may be cylindrically shaped or have any desired configuration and preferably is constructed of insulating material, such as Bakelite.
- Coil form 10 has a series of apertures 11 disposed transversely of and equally spaced from one another along the length of the form, thereby dividing coil form 10 into an axially extending multiplicity of coil-supporting sections.
- the network also includes a distributed winding 12 which has a multiplicity of series-connected winding sections individually wound around and supported by a section of form 10.
- a conductive surface 14 within core 13 which may conveniently be formed by spraying the internal surface of the core with a silver firing mixture.
- This conductive surface is made discontinuous, as represented by the discontinuity 19 which may be a non-conductive strip; otherwise conductive surface 14 would have the effect of a shorted-turn secondary for winding 12.
- a series of silver patches 15 are fired on the externai periphery of the core to provide conductive elements which are spaced along the core was to'be exposed through apertures 11 of coil form 10.
- Conductive elements 15 are electrically connected, by means of soldered connections 2%, to turns of winding 12 which extend diagonally across slots 11 of coil form and which may be considered as inter-section winding turns inasmuch as they constitute the conductive connections extending between contiguous sections or" the winding. .
- An input connection 18 extends from one end of winding 12 and an output connection 16 extends from the other end.
- a common connection17 which may be grounded, is soldered .to the internal conductive surface 14 of core member 13 to complete both the input and output circuits of the delay network.
- each condenser 21 is determined by the physical dimensions of each conductive element 15, and the thickness and .dielectric constant of core 13.
- the self .andmutual inductance of winding 12 is determined by the diameter of coil formlfi, the size and type of conductornsed in fabricating the winding, the number of turns per winding section and the distance between successive sections.
- the shunt capacitance, in conjunction withthe-inductance, determines the total time delay of the network which is so selected that a signal applied to input .terminals 17, 18 is delayed for the desired duration before it appears at output terminals 16, 17.
- The-selec- ,tion of these parameters is also governed by the frequencyresponse-cl aracteristic desiredrthat is, the desired frequency range over which signal components must not be attenuatedappreciaoly nor subjected to phase distortion.
- afurtherseries of, elongatedconductive elements 22 areprinted, fired or in-anyway mechanicallygaflixed to coil; form 10, on. the obverse side to that which-is slotted, before winding 12 is wound thereon.
- Each such element extends longitudinally of the form to spanat least'two successive winding-support sections of the coil form and, consequently, twocontinuoussections-of winding 12.
- the insulation of the winding conductor serves asthe dielectric, while the turns of the winding overlyingclements 22 andithe elements themselves serve as :the condenser.electrodeswith the result thatthe winding sections spanned by elements :22 are .capacitively intercoupled, asshown by. condensers ZSin Figure 3.
- Sectionalized winding .12 is subsequently wound around the core and coil form assembly witheach section thereof supported by a section of the .coil form and with inter-section winding turnsextending diagonally across slots 11 and, therefore, across conductive elements 15.
- the inter-section turns are soldered to such surfaces 15 and a ground strap 17 is then soldered to the internal surface 14.
- a common electrode is employedfor the shunt-connected condensers 21, being provided by one common conductive surface 14 as shown in Figure 1.
- the modified core member 24 of Figure 3 may also be utilized in the described network.
- a series of conductive surfaces 26 are mechanically afiixed to the internal periphery of the core individually opposite a corresponding external conductive element 15.
- Internal conductive surfaces 26 are electrically joined together by means of a common connection 27 which serves the same function as conductor 17 of Figure 1.
- Type of material of coil form '10 *Bakelite Outside diameter of coil form 10 .368 inch Inside diameter of coilform 10- .250 inch Width of apertures 11 .125 inch Arcof apertures 11 Distance between centers of apertures 11 .377 inch Type of conductor for winding 12 Celenamel No.
- Alumpedparameter timeedelay network for translating-signal componentsiinclude'dawithin a predetermined range of frequenciescomprising: an elongated coil form of insulating -material'having a series of apertures spaced from one another along the length of said coil form dividing said coil :for-m into an axially extending multiplicity of coil-supporting sections; a--distributed winding having a multiplicity of series-connected winding sections individually wound around'and'supportedbyan assigned one of said sections ofsa'idcoil form; an elongated core memberof dielectric material concentrically positioned within said coil'form and exposed "by said apertures of said coil form; at least one conductive surface within said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shunt-connected condensers for said network; and input and output connections
- a lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an ax ally extending multiplicity of coilsupporting sections; a distributed Winding having a multiplicity of series-connected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated hollow core member of dielectric material concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface within said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shunt-connected condensers for said network; and input and output connections extending from opposite ends of said Winding.
- a three-terminal lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of series-connected Winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated holl w core member of dielectric material concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shunt-connected condensers for said network; input and output connections extending
- a three-terminal lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated, cylindrically shaped coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of seriesconnected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated, cylindrically shaped hollow core member of dielectric material having an outside diameter less than the inside diameter of said coil form concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core,
- a three-terminal lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated, cylindrically shaped coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of seriesconnected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated, cylindrically shaped hollow core member of dielectric material having an outside diameter less than the inside diameter of said coil form concentrically positioned within said coil form and exposed by said apertures of said coil form; a first series of conductive surfaces on the internal periphery of said core; a second series of conductive surfaces on the external periphery of said core disposed in said apertures of said coil form and individually disposed opposite an assigned one of said first series of conductive surfaces, electrically connected to said Winding intermediate
- a three-terminal lumpedparameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of series-connected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated hol ow core member of dielectric material concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shunt-connected condensers for said network; additional conductive elements mechanically
- a three-terminal lumped-parameter time-delay network for translatin signal components included within a predetermined range of frequencies comprising: an elongated, cylindrically shaped coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along flte length of'saidt-coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having multiplicity of series-connected winding sections individually wound around and supported bynan assigned'one of said sections of said coil form; an elongated, cylindrically shaped hollow core member of dielectric'material having an outside diameter less than the inside diameter of said coil form concentrically positioned within said coil form and exposed by said apertures of said-coilform; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to
- a three-terminal lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated, cylindrically shaped hollow coil form of insulating material having a series of rectangularly shaped apertures disposed transversely of said coil form and equally spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of series-connected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated, cylindrically shaped hollow core member of dielectric material having an outside diameter less than the inside diameter of said coil form concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface mechanically aflixed to the internal periphery of said core; a series of rectangularly shaped conductive elements disposed in said apertures of said coil form having substantially the same physical dimensions as said rectangularly shaped apertures, electrical
- a lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of. winding. sections individually wound aroundandzsupportcd by -an assigned-one of said sections of saidi coil form, said winding further having. intersectionwindingturnsextending across said apertures of said coil-formuand'connecting said winding sections in,
- Alum ed-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising; an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the'length of said coil form dividing said coil form into.
- an axially extending multiplicity of coilsupportingsections a distributed winding having a multiplicity of winding sections individually wound around and supported by an'assigned one of said sections of said coil form, said'winding further having inter-section winding turns extending across said apertures of said coil form and connecting said winding sections in series relation; an elongated hollow core member of dielectric material concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, a multiplicity of condensers for said network; conductive bonding connections connecting said inter-section turns to said conductive elements for connecting said condensers in shunt relation with said winding sections; input and output connections extending from opposite ends of said winding; and/a common connection extending from said internal conductive surface of said core.
- a lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures spaced from one another along the length of said coil form dividing said coilform into an axially extending multiplicity.
- a distributed winding having a multiplicity of series-connected Winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated core member of dielectric material positioned within said coil form and having one set of surface portions exposed by said apertures of said coil form; at least one conductive surface on said core in spaced, opposed relation to said exposed portions; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to said exposed portions of said core to constitute, in conjunction with said conductive surface of said core, shunt-connected condensers for said network; and input and output connections extending from opposite ends of said winding.
Description
Dec. 13, 1955 J. J. LUCAS TIME-DELAY NETWORK Filed Jan. 19, 1953 JACK J. LUCAS IN V EN TOR.
HIS ATTORNEY.
TIME-DELAY NETWORK Jack J. Lucas, Chicago, 11]., assignor to Zenith Radio Corporation, a corporation of Iliinois Application January 19, 1953, Serial No. 331,848
11 Claims. (Cl. 333-29) This invention is directed to the structure and method of making time-delay networks of the lumped-parameter type for translating signal components included within a predetermined range of frequencies.
Time-delay networks, as such, have long been known in the art and have taken the form of distributedor lumped-parameter circuits. A well-known distributed-parameter delay network in accordance with the prior art comprises at least one distributed winding wound around a supporting, grounded core structure and an associated ground-return path. The capacitance between the winding and its core structure supplies the distributed capacitance of the network which, together with the inductance of the winding, determines the total time delay exhibited by the network. A time delay of any particular amount may be obtained by appropriately selecting the physical characteristics of the winding and its core structure. However, in order to provide such a prior art time-delay network which exhibits desirable electrical characteristics over an appreciable passband while still imparting a considerable time delay to an applied signal, it has been necessary to make the network relatively long and bulky. Moreover, it is difficult to compensate such a network in an attempt to improve or modify its electrical characteristics.
A lumped-parameter type time-delay network, on the other hand, due to its electrical and physical dimensions relatively small as far as volume is concerned and exhibits excellent electrical characteristics in that it is capable of translating signal components included within a relatively wide range of frequencies (for example, -4.5 megacycles) with negligible attenuation at the higher frequencies while imparting an approximately equal time delay to all frequency components. It is also relatively easy to shape the response characteristic of such a network due to the fact that it has many dimensions that may be varied. However, in the construction of lumped-parameter delay networks in the past, it has been customary to employ a multiplicity of separate external condensers individually connected to an assigned junction of a corresponding multiplicity of series-connected winding sections. It will be appreciated that such a construction is relatively expensive and cumbersome and does not readily lend itself to economical mass production.
It is, accordingly, an object of the present invention to provide an improved time-delay network of the lumpedparnmeter type for translating signal components included within a predetermined range of frequencies that is simple and economical in construction.
t is another object of the invention to provide such an improved network that lends itself to mass production.
it is a further object of the invention to provide a novel method of constructing a lumped-parameter type of timedelay network.
In accordance with the invention, a lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprises an elongated coil form ofinsulating material which United States Patent 0 has a series of apertures spaced from one another along the length of the coil form, dividing the form into an axially extending multiplicity of coil-supporting sections. The network includes a distributed winding having a multiplicity of series-connected winding sections individually wound around and supported by an assigned one of the sections of the coil form. An elongated core member of dielectric material is positioned within the coil form and has one set of surface portions exposed by the apertures thereof. The network further comprises at least one conductive surface on the core in spaced, opposed relation to the exposed portions; and conductive elements disposed in the apertures of the coil form, electrically connected to the winding intermediate successive sections thereof and mechanically connected to the exposed portions of the core to constitute, in conjunction with the conductive surface of the core, shunt-connected condensers for the network. Finally, the network has input and output connections extending from opposite ends of the winding.
The features of this invention which are believed to be new are set forth with particularity in the appended claims. The invention, however, together with further objects and advantages thereof, may best be understood by reference to the following description in conjunction with the accompanying drawings, in which:
Figure 1 is a schematic representation, partially cutaway, of a lumped-parameter time-delay network constnicted in accordance with the present invention;
Figure 2 is another view of the embodiment shown in Figure 1;
Figure 3 is an equivalent circuit diagram of the network of Figures 1 and 2; and
Figure 4 discloses another embodiment of the core member of a delay line constructed in accordance with the invention.
Referring now more particularly to Figures 1-3, the time-delay network there represented is of the lumped-i parameter type for translating signal components included within a predetermined range of frequencies. While the illustrated arrangement is of the three-terminal or unbalanced type, the invention is equally applicable to balanced networks. The network shown is in the form of a simulated transmission line and comprises an elongated hollow coil form 10, which may be cylindrically shaped or have any desired configuration and preferably is constructed of insulating material, such as Bakelite. Coil form 10 has a series of apertures 11 disposed transversely of and equally spaced from one another along the length of the form, thereby dividing coil form 10 into an axially extending multiplicity of coil-supporting sections. The network also includes a distributed winding 12 which has a multiplicity of series-connected winding sections individually wound around and supported by a section of form 10.
Au elongated hollow core member 13 of a suitable dielectric material, such as ceramic, preferably having the same cross-sectional configuration as coil form 10 but having an external dimension less than the internal dimension of the coil form is concentrically positioned within the form. There is at least one conductive surface 14 within core 13 which may conveniently be formed by spraying the internal surface of the core with a silver firing mixture. This conductive surface is made discontinuous, as represented by the discontinuity 19 which may be a non-conductive strip; otherwise conductive surface 14 would have the effect of a shorted-turn secondary for winding 12. Also, a series of silver patches 15 are fired on the externai periphery of the core to provide conductive elements which are spaced along the core was to'be exposed through apertures 11 of coil form 10.
The capacitance of each condenser 21 is determined by the physical dimensions of each conductive element 15, and the thickness and .dielectric constant of core 13. The self .andmutual inductance of winding 12 is determined by the diameter of coil formlfi, the size and type of conductornsed in fabricating the winding, the number of turns per winding section and the distance between successive sections. The shunt capacitance, in conjunction withthe-inductance, determines the total time delay of the network which is so selected that a signal applied to input .terminals 17, 18 is delayed for the desired duration before it appears at output terminals 16, 17. The-selec- ,tion of these parameters is also governed by the frequencyresponse-cl aracteristic desiredrthat is, the desired frequency range over which signal components must not be attenuatedappreciaoly nor subjected to phase distortion.
While a lumped-parameter time-delay network constructed in the manner described may exhibit a linear phase shift characteristic over a limited frequency range, it-has been found that by providing a capacitive coupling bri ge :across successive winding sections, the linear response may be extended further into the frequency spectrum. To this'end, afurtherseries of, elongatedconductive elements 22 areprinted, fired or in-anyway mechanicallygaflixed to coil; form 10, on. the obverse side to that which-is slotted, before winding 12 is wound thereon. Each such element extends longitudinally of the form to spanat least'two successive winding-support sections of the coil form and, consequently, twocontinuoussections-of winding 12. The insulation of the winding conductor serves asthe dielectric, while the turns of the winding overlyingclements 22 andithe elements themselves serve as :the condenser.electrodeswith the result thatthe winding sections spanned by elements :22 are .capacitively intercoupled, asshown by. condensers ZSinFigure 3.
,In. constructing the described network the severalcomponentpartsthereof are individually fabricated. For examp1e,,coil form ,10 is provided with cut-away portions or-apertures 11 and printed conductive strips .22 .while core-member '13 is providedwith silver-fired surfaces 14 and 15. The core is then inserted into the coil formand properly oriented so that the surfaces =15 thereof are aligned with and exposed throughapertures 11. The core is then inserted into the coil form and properly oriented so that the surfaces 15 thereof are aligned with and exposed through apertures 11. The core is then securely fixed in position by any suitable binding technique such as cementing. Sectionalized winding .12 is subsequently wound around the core and coil form assembly witheach section thereof supported by a section of the .coil form and with inter-section winding turnsextending diagonally across slots 11 and, therefore, across conductive elements 15. The inter-section turns are soldered to such surfaces 15 and a ground strap 17 is then soldered to the internal surface 14.
Preferably, a common electrode is employedfor the shunt-connected condensers 21, being provided by one common conductive surface 14 as shown in Figure 1. However, the modified core member 24 of Figure 3 may also be utilized in the described network. In this modification a series of conductive surfaces 26 are mechanically afiixed to the internal periphery of the core individually opposite a corresponding external conductive element 15. Internal conductive surfaces 26 are electrically joined together by means of a common connection 27 which serves the same function as conductor 17 of Figure 1.
While the invention isnot limited 'to any specific circuit constant or physical dimensions, the following electrical and physical dimensions of the embodiment of Figure 1 are given as illustrative of a proven network having a linear phase 'shift-characteristicand having only a 3 decibel attenuation over a pass-band from 0 to 4.5 megacycles while at the same time exhibiting a total time delay of 2.70 micro-seconds.
Type of material of coil form '10 *Bakelite Outside diameter of coil form 10 .368 inch Inside diameter of coilform 10- .250 inch Width of apertures 11 .125 inch Arcof apertures 11 Distance between centers of apertures 11 .377 inch Type of conductor for winding 12 Celenamel No. 41 AWG Number of turns per winding section '57 Total number of winding 'sec- 'tions 78 Type of material of dielectric core -member13 :Bariumtitanate ceramic of dielectric constant 'Silver fired surface .125 inch Type of conductive surface 14-- Width of strip 19 Width of conductive element H p .022 inch Length of conductive e ement 22 .635 inch The invention 'provides,'rtherefore,ianimproved lumpedparameter .timesdelay network that ,is extremely simple andcconomical in constructionand yet is effective to translate signal .components included within a predetermined rangc. of frequencies.
While :particularembodiments have been shown and described, modificationsmaybe made, and it isintcndcd in :the .appendedwlaims to.:cover all such modifications as may fallwithin the true spirit and scope of the invention.
I claim:
1. Alumpedparameter timeedelay network for translating-signal componentsiinclude'dawithin a predetermined range of frequenciescomprising: an elongated coil form of insulating -material'having a series of apertures spaced from one another along the length of said coil form dividing said coil :for-m into an axially extending multiplicity of coil-supporting sections; a--distributed winding having a multiplicity of series-connected winding sections individually wound around'and'supportedbyan assigned one of said sections ofsa'idcoil form; an elongated core memberof dielectric material concentrically positioned within said coil'form and exposed "by said apertures of said coil form; at least one conductive surface within said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shunt-connected condensers for said network; and input and output connections extending from opposite ends of said winding.
2. A lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an ax ally extending multiplicity of coilsupporting sections; a distributed Winding having a multiplicity of series-connected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated hollow core member of dielectric material concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface within said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shunt-connected condensers for said network; and input and output connections extending from opposite ends of said Winding.
3. A three-terminal lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of series-connected Winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated holl w core member of dielectric material concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shunt-connected condensers for said network; input and output connections extending from opposite ends of said winding; and a common connection extending from said internal conductive surface of said core.
4. A three-terminal lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated, cylindrically shaped coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of seriesconnected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated, cylindrically shaped hollow core member of dielectric material having an outside diameter less than the inside diameter of said coil form concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shuntconnected condensers for said network; input and output connections extending from opposite ends of said winding; and a common connection extending from said internal conductive surface of said core.
5. A three-terminal lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated, cylindrically shaped coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of seriesconnected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated, cylindrically shaped hollow core member of dielectric material having an outside diameter less than the inside diameter of said coil form concentrically positioned within said coil form and exposed by said apertures of said coil form; a first series of conductive surfaces on the internal periphery of said core; a second series of conductive surfaces on the external periphery of said core disposed in said apertures of said coil form and individually disposed opposite an assigned one of said first series of conductive surfaces, electrically connected to said Winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with said first series of conductive surfaces, a series of shunt-connected condensers for said network; input and output connections extending from opposite ends of said winding; and a common connection joining, and extending from, said first series of conductive surfaces of said core.
6. A three-terminal lumpedparameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of series-connected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated hol ow core member of dielectric material concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shunt-connected condensers for said network; additional conductive elements mechanically afiixed to said coil form and longitudinally extending along the length of said coil form to span at least two successive winding sections, insulated from but capacitively coupled to said winding sections, to provide in said network a capacitive coupling between such spanned sections for shaping the frequency-phase characteristic of said network; input and output connections extending from opposite ends of said winding; and a common connection extending from said internal conductive surface of said core.
7. A three-terminal lumped-parameter time-delay network for translatin signal components included within a predetermined range of frequencies comprising: an elongated, cylindrically shaped coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along flte length of'saidt-coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having multiplicity of series-connected winding sections individually wound around and supported bynan assigned'one of said sections of said coil form; an elongated, cylindrically shaped hollow core member of dielectric'material having an outside diameter less than the inside diameter of said coil form concentrically positioned within said coil form and exposed by said apertures of said-coilform; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shunt-connected condensers for said network; elongated conductive strips mechanically afiixed to the external periphery of said coil form and longitudina ly extending along the length of said coil form to span at le-ast.two successive winding sections, insulated from but capacitively coupled to said winding sections, to provide in said network a capacitive coupling between such spanned sections for shaping the frequency-phase characteristic of said network; input and output connections extending from opposite ends of said winding; and a common connection extending from said internal conductive surface of said core.
8. A three-terminal lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated, cylindrically shaped hollow coil form of insulating material having a series of rectangularly shaped apertures disposed transversely of said coil form and equally spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of series-connected winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated, cylindrically shaped hollow core member of dielectric material having an outside diameter less than the inside diameter of said coil form concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface mechanically aflixed to the internal periphery of said core; a series of rectangularly shaped conductive elements disposed in said apertures of said coil form having substantially the same physical dimensions as said rectangularly shaped apertures, electrically connected to said winding intermediate successive sections thereof and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conduc'tive surface of said core, a series of shunt-connected condensers for said network; an elongated conductive strip mechanically affixed to the external periphery of said coil form and longitudinally extending along the length of said coil form to span at least two successive winding sections, insulated from but capacitively coupled to said winding sections, to provide in said network a capacitive coupling between such spanned sections for shaping the frequency-phase characteristic of said network; input and output connections extending from opposite ends of said winding; and a common connection extending from said internal conductive surface of said core.
9. A lumped-parameter time-delay network for translating signal components included Within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the length of said coil form dividing said coil form into an axially extending multiplicity of coil-supporting sections; a distributed winding having a multiplicity of. winding. sections individually wound aroundandzsupportcd by -an assigned-one of said sections of saidi coil form, said winding further having. intersectionwindingturnsextending across said apertures of said coil-formuand'connecting said winding sections in,
series'relatioman elongated hollow core member of dielectric material concentrically positioned within said coilform'and exposed by .said apertures of said coil form; at least one elongated conductive surface within said core; conductive elements disposed'in said apertures of said coil form, electrically connected to said inter-section turns and mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, shuntconnected condensersfor said network; and input and output connections extending from opposite ends of said winding.
10. Alum ed-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising; an elongated coil form of insulating material having a series of apertures disposed transversely of said coil form and spaced from one another along the'length of said coil form dividing said coil form into. an axially extending multiplicity of coilsupportingsections; a distributed winding having a multiplicity of winding sections individually wound around and supported by an'assigned one of said sections of said coil form, said'winding further having inter-section winding turns extending across said apertures of said coil form and connecting said winding sections in series relation; an elongated hollow core member of dielectric material concentrically positioned within said coil form and exposed by said apertures of said coil form; at least one elongated conductive surface on the internal periphery of said core; conductive elements disposed in said apertures of said coil form, mechanically connected to the exposed portions of said core to constitute, in conjunction with the internal conductive surface of said core, a multiplicity of condensers for said network; conductive bonding connections connecting said inter-section turns to said conductive elements for connecting said condensers in shunt relation with said winding sections; input and output connections extending from opposite ends of said winding; and/a common connection extending from said internal conductive surface of said core.
11. A lumped-parameter time-delay network for translating signal components included within a predetermined range of frequencies comprising: an elongated coil form of insulating material having a series of apertures spaced from one another along the length of said coil form dividing said coilform into an axially extending multiplicity. of coil-supporting sections; a distributed winding having a multiplicity of series-connected Winding sections individually wound around and supported by an assigned one of said sections of said coil form; an elongated core member of dielectric material positioned within said coil form and having one set of surface portions exposed by said apertures of said coil form; at least one conductive surface on said core in spaced, opposed relation to said exposed portions; conductive elements disposed in said apertures of said coil form, electrically connected to said winding intermediate successive sections thereof and mechanically connected to said exposed portions of said core to constitute, in conjunction with said conductive surface of said core, shunt-connected condensers for said network; and input and output connections extending from opposite ends of said winding.
References Cited in the file of this patent UNITED STATES PATENTS 2,413,608 Di Toro Dec. 31, 1946' 2,416,297 Finch et a1. Feb. 25, 1947 2,457,212 DiToro Dec. 28, 1948
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US331848A US2727213A (en) | 1953-01-19 | 1953-01-19 | Time-delay network |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US331848A US2727213A (en) | 1953-01-19 | 1953-01-19 | Time-delay network |
Publications (1)
Publication Number | Publication Date |
---|---|
US2727213A true US2727213A (en) | 1955-12-13 |
Family
ID=23295621
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US331848A Expired - Lifetime US2727213A (en) | 1953-01-19 | 1953-01-19 | Time-delay network |
Country Status (1)
Country | Link |
---|---|
US (1) | US2727213A (en) |
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2874358A (en) * | 1956-03-27 | 1959-02-17 | Jr Gurdon R Abell | Electrical delay lines |
US2892162A (en) * | 1955-06-22 | 1959-06-23 | Dynamic Electronics New York I | Electromagnetic delay lines |
US2894221A (en) * | 1955-10-11 | 1959-07-07 | Carl E Coy | Artificial transmission lines |
US2971158A (en) * | 1956-10-03 | 1961-02-07 | Admiral Corp | Delay line circuits |
US3283269A (en) * | 1962-03-12 | 1966-11-01 | Bel Fuse Inc | Tapped delay line |
FR2503957A1 (en) * | 1981-04-10 | 1982-10-15 | Radiotechnique Compelec | Lumped-constant delay line for TV decoder - has all windows mounted on same support also bearing capacitors and formed from single length of wire |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2413608A (en) * | 1945-03-12 | 1946-12-31 | Hazeltine Research Inc | Time-delay network |
US2416297A (en) * | 1944-10-26 | 1947-02-25 | Bell Telephone Labor Inc | Wave transmission network |
US2457212A (en) * | 1945-06-18 | 1948-12-28 | Hazeltine Research Inc | Time-delay network |
-
1953
- 1953-01-19 US US331848A patent/US2727213A/en not_active Expired - Lifetime
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2416297A (en) * | 1944-10-26 | 1947-02-25 | Bell Telephone Labor Inc | Wave transmission network |
US2413608A (en) * | 1945-03-12 | 1946-12-31 | Hazeltine Research Inc | Time-delay network |
US2457212A (en) * | 1945-06-18 | 1948-12-28 | Hazeltine Research Inc | Time-delay network |
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2892162A (en) * | 1955-06-22 | 1959-06-23 | Dynamic Electronics New York I | Electromagnetic delay lines |
US2894221A (en) * | 1955-10-11 | 1959-07-07 | Carl E Coy | Artificial transmission lines |
US2874358A (en) * | 1956-03-27 | 1959-02-17 | Jr Gurdon R Abell | Electrical delay lines |
US2971158A (en) * | 1956-10-03 | 1961-02-07 | Admiral Corp | Delay line circuits |
US3283269A (en) * | 1962-03-12 | 1966-11-01 | Bel Fuse Inc | Tapped delay line |
FR2503957A1 (en) * | 1981-04-10 | 1982-10-15 | Radiotechnique Compelec | Lumped-constant delay line for TV decoder - has all windows mounted on same support also bearing capacitors and formed from single length of wire |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US3723915A (en) | Acoustic surface wave device | |
US3451015A (en) | Microwave stripline filter | |
US3638147A (en) | High-frequency low-pass filter with embedded electrode structure | |
US3614675A (en) | Isolator comprising tuned lumped element circulator | |
WO2008013073A1 (en) | Noise filter array | |
US2258261A (en) | Coil with line properties | |
US2544508A (en) | Signal transfer apparatus | |
US2727213A (en) | Time-delay network | |
US2273955A (en) | Loop antenna | |
US2537959A (en) | Artificial transmission line | |
US2892163A (en) | Band-pass filters | |
US2715211A (en) | Ultra high frequency tuning systems | |
US2461061A (en) | Equalized delay line | |
US2519524A (en) | Multiple-tuned wave-selector system | |
US2554295A (en) | Variable inductance device | |
US2702372A (en) | Delay line | |
US2688119A (en) | Printed circuit network system | |
US3416104A (en) | Band-pass crystal filters | |
US2233748A (en) | High frequency coil | |
US3629761A (en) | Broadband high-frequency transformer | |
US3706949A (en) | High frequency filter | |
US2872649A (en) | Intermediate frequency transformer | |
JP2000261271A (en) | Lamination type low pass filter | |
US2080024A (en) | Filter | |
US2764742A (en) | Variable tuning structures |