KR20030065514A - Energy pathway arrangement - Google Patents

Abstract

Compact and integrated devices for the energy-adjusting device 800q with various predetermined paths 813a, 813b may be used to regulate the energy of single or multiple circuits, which may adversely affect certain applications with single or multiple circuit systems. Partly used for the purpose. Some energy-tuning variants may be provided for the multi-tuning operation.

Description

Energy path devices {ENERGY PATHWAY ARRANGEMENT}

These component device amalgams are undesirable, internally and / or externally, which not only simultaneously regulate energy in progress, but also have an undesirable effect on many circuit systems operating in combination with new, conventional component devices. It is to provide compact integrated isolation and invalid functionality for the desired energy portion in relation to the energy portion formed. Other energy regulator modifications not only provide a single common voltage reference function for one or multiple circuit systems, but also multiple isolated common to each circuit system or multiple discrete circuit systems simultaneously during multiple dynamic energy conditioning operations. It can be operated simultaneously to provide either a voltage reference or a single common voltage reference.

Today, as electronic circuit densities in the world's system applications increase, unwanted noise by-products from the structure can equally limit performance on both critical and non-critical electronic circuits. As a result, the avoidance of effects on unwanted noise by isolation or invalidation of circuit parts against undesirable energy or noise effects is an important consideration for most circuit and package designs.

Unwanted energy or noise effects in a circuit can be reduced by any device or circuit or by the use of various design techniques formed to reduce unwanted energy or generated noise. Unwanted energy or noise found in a single circuit could be reduced by the use of various layout techniques to insulate the noise energy (eg, guard rings or shields) that would otherwise disrupt the problematic circuit. Past findings by others indicate specific and general attempts to use various techniques that can be found in many well-written studies. However, the study was published in US Pat. No. 6,031,406, N. Verghese, T. Schmerbeck, D. Allstot, and in a paper written in Simulation Techniques and Solutions 235-253 (Kluwer Academic Publishers 1995) and P. Horowitz, W. The three related examples, Electronic Technology by Hill, pages 430-466 (Cambridge University Press 1989), are not limited.

Differential and common mode noise energy will be generated and traverse along and around the energy path, cable, circuit board track or trace, high speed transmission line and bus line path. In many cases, these types of energy conductors produce antenna radiation that exacerbates the problem at high frequencies so that the portion of energy proceeding using prior art passive devices causes increased levels of energy parasitic interference of various capacitive and inductive parasitic forms. It acts as an energy field. These increases are in part coupled with inherent manufacturing instability and performance defects that essentially form or induce the possibility of operating forward to form unwanted interference energy that is forwarded towards the application and coupled to the associated electrical circuits that form the shield from the desired EMI. Due to the combination of the required operational placement limitations of the functional and structurally limited prior art solutions.

In conclusion, for today's high frequency operating environments, the solution involves careful system layout, various grounding devices and techniques, as well as the combination of simultaneous filtering of input and output lines with expensive isolation, electrostatic and / or magnetic shielding. .

This application is a partial continuing application of co-pending application No. 09 / 982,553, filed October 17, 2001. This application also discloses US preliminary application 60 / 248,914, filed November 15, 2000, US preliminary application 60 / 252,766, filed November 22, 2000, US preliminary application 60 / filed November 29, 2000. 253,793, US preliminary application 60 / 255,818, filed December 15, 2000, US preliminary application 60 / 280,819, filed April 2, 2001, US preliminary application 60 / 302,429, filed July 2, 2001 and Claims the advantages of US preliminary application 60 / 310,962, filed August 8, 2001.

The present disclosure is a component device having a predetermined arranged energy control device of various elements including viable complementary energy paths, such as individual portions of a plurality of complementary pairs, and insulated electronic circuitry coupled to and shielding the energy paths. To compactly integrate

1 illustrates a plan view of a portion 6000 of the embodiment 6000 of FIG. 2A in accordance with this configuration.

2A shows an enlarged plan view of an embodiment 6000 which is an energy regulating device according to this configuration.

FIG. 2B shows a top view of a portion of the discrete component 6000 version of FIG. 2A in accordance with this configuration.

2C shows a multiple circuit arrangement using embodiment 6000 in one of many possible configurations in accordance with this configuration.

3A is a multiple circuit common comprising three separate complementary energy path pairs comprising a cross feedthrough pair 1, a straight feedthrough pair 1, and a bypass pair 1 having a common planar shield according to this configuration. An enlarged plan view of Example 8000, a mode and differential mode energy regulator, is shown.

3B shows a top view of a portion of component 8000 of FIG. 3A in accordance with this configuration.

4A shows an enlarged plan view of embodiment 10000, which is a multiple common mode and differential mode energy regulator comprising three separate complementary bypass energy path pairs in which the pair is coplanar (2).

4B shows a top view of a portion of component 10000 of FIG. 4A in accordance with this configuration.

4C shows a cross-sectional view of a portion of a shielding layer in accordance with this configuration.

5A shows a top view of a portion of a component layer in accordance with this configuration.

5B shows a top view of a portion of a component layer in accordance with this configuration.

6A shows a top view of a portion of a component layer in accordance with this configuration.

6B shows a top view of a portion of a component layer in accordance with this configuration.

7A shows an enlarged plan view of a multiple circuit arrangement using embodiment 1000 in one of many possible phrases in accordance with this configuration.

7B shows a top view of a multiple circuit device using embodiment 1200 in one of many possible configurations in accordance with this configuration.

8A shows an enlarged plan view of a multiple circuit arrangement using embodiment 1100 in one of many possible configurations in accordance with this configuration.

8B shows a top view of a multiple circuit arrangement using embodiment 1201 in one of many possible configurations according to this configuration.

9 illustrates a top view of a portion of component 9200 of FIG. 10 in accordance with this configuration.

10 is a sectional view of an embodiment 9200 which is an energy regulating device according to the present configuration.

11 is a sectional view of Embodiment 9210 which is an energy regulating device according to the present configuration.

12 shows a schematic plan view of a multi-circuit apparatus using embodiment 9200 in one of many possible configurations according to this configuration.

Thus, a single, uniquely applicable self-contained device using a simple device in the energy path with other elements that can be used in any multi-circuit application to provide as efficient and supportable noise suppression, shielding, elimination, elimination or invalidation as necessary. Included energy regulating device is aimed.

This application is part of the co-pending US application 09 / 982,553, filed October 17, 2001, which is incorporated herein by reference. This application is a partial continuing application of co-pending application No. 09 / 982,553, filed October 17, 2001. This application also discloses US preliminary application 60 / 248,914, filed November 15, 2000, US preliminary application 60 / 252,766, filed November 22, 2000, US preliminary application 60 / filed November 29, 2000. 253,793, US preliminary application 60 / 255,818, filed December 15, 2000, US preliminary application 60 / 280,819, filed April 2, 2001, US preliminary application 60 / 302,429, filed July 2, 2001 and Claims the advantages of US preliminary application 60 / 310,962, filed August 8, 2001.

One method disclosed is an integrated, physical make out in a functional capability that allows multiple energy paths or groups of electrodes to be physically close in position to be able to dynamically operate in close electrical proximity to others while simultaneously sharing a common energy reference node CRN. It is to provide an energy device and / or energy control device. This function occurs when manufactured by at least one electrode or energy path shielding structure found with one device amalgam or other element of the energy regulator.

The following is a detailed description of the only device or embodiment that is one of a number of possible applicable form variables of the device that is ubiquitous in the possible application potentials that can operate during use. This device description is intended to show only a few of the only applicable forms of energy control devices and should not be taken as limiting to all due to possible modifications to consume more of the tester's expensive time. Many variations, modifications, and improvements of the broad spectrum fall within the scope of the only applicable form of energy control devices as defined in the following many claims.

The language used throughout the entire disclosure for the sake of summary will be the term 'amalgam' as defined by the dictionary with the specific help provided as it implies the applicant. The term “amalgam” means “unaligned, aligned, complementary pairs, overlaps, including mixed three-dimensional relationships, both in discrete or non-discrete forms of non-energyized states that can be operated for dynamic uses and / or states. Actionable energy that is a single and / or grouped dimensional relationship, magnitude relationship, remote, musculoskeletal, adjacent, non-adjacent relationship sorting and placement, using both offset and / or combination of spaced alignments or both relative and non-relative. Means a general element bond comprising elements arranged in harmonious bonds or bonds, which may include single and / or groups of various material combinations and formats formed or made in a control embodiment, conductive, semiconductive and nonconductive material elements. It can be replaced with an energy regulator. The term amalgam, if used, is not "a variety of random alloys of different material numbers" as one finds in the dictionary as the first definition list of amalgam. Thus, amalgam may include those coupled to an energy path and coupling element, location and attachment structure as described above allowing at least one energized circuit system to use the disclosed embodiments in a generalized or specific manner. Various conventional amalgams (energy regulators) and / or energy regulators will be used in the disclosure.

Therefore, the technical criteria are many of the other possible devices for which those skilled in the art are not necessarily disclosed, and as a detailed guide that clearly leads and quickly assists the reader in the enlightenment direction such as those disclosed, these possible embodiments or possible forms. Placed or attempted to be restricted to Therefore, due to time constraints, in particular due to limitations inherent in the work of the investigator and the applicant, the same becomes a sampling of technical possibilities.

In addition, as used herein, the abbreviation "AOC" for the word is "predetermined region part that can operate during energy part convergence that is shielded and can be executed for complementary energy part interactions." AOC 813 is found in discrete or non-dispersed versions of amalgam or in energy control devices. AOC 813 is a relative boundary for shielded energy regulation as described for some of the ongoing circuit system energy. Conventional AOC allows for shielding portions of circuit system energy that proceed using these embodiment elements as disclosed to interact with each other in one or more predetermined ways or functions (eg, mutual cancellation of opposing h field energies). Physically or virtually aligned bounders of amalgams manufactured together (or not together) or parts of an energy conditioning device together (or not together). For example, the portion or element filling space distributed by overlapping alignment of the 805 peripheral electrode edge portion of the main body electrode portion 81 of the coupled, conductively coupled shielding electrode may be used to define the AOC 813. Is an excellent group.

The main body electrode portion 81 of the shielding electrode joined and bonded together in a typical new embodiment does not limit and shield the main body electrode portion 80 of the collecting, complementary electrode in any conventional new embodiment, Is considered to at least partially define the AOC 813. In addition, for the sake of clarity, the term 'external' or external 'as used herein generally refers to any energy found above and / or beyond the effective energy control range or influence, spacing or region of a conventional AOC, as defined herein. Is considered as the position of. This does not mean any labeled 'outside' or 'outside' that should be the distance of a typical embodiment or may not be adjacent to other elements including the device and AOC 813 disclosed or not disclosed. As used herein, the term 'external' or 'external' may apply to all or most 79 " X " extended portion positions of AOC 813 and its 'parent' complementary electrode. In general, despite the adjacent relationship to a larger (79 "x" 'S), main body electrode portion 80 itself is within the AOC 813 boundary of a typical embodiment.

The present amalgam and / or energy regulating device includes various pairs and / or complementary pair electrodes that can be operated for 'electrically complementary' operation, meaning that can be performed or operated for opposing electrical operation to occur in relation to others. Disclosed are discrete and non-discrete versions of an electrode device with conductive coupling multi-electrode shield structure and operability for multi-circuit operation.

The amalgam or energy regulator may include various harmony and / or homogeneous mixed energy partial progress modes, such as bypass and / or feedthrough modes or operations that simultaneously shield and smooth energy regulation operations for multiple circuits or a circuit. . New, conventional amalgams or energy regulators utilize a common reference node function supplied by a conductive 'ground' of multiple shielding electrodes or first electrodes, and multiple complementary electrodes and / or single or of new and common embodiments. It has been found to facilitate multiple energy regulation functions that can operate on various energy segments running along portions of multiple circuit segments.

With respect to most embodiments of current amalgan or energy conditioners and / or energy-regulating devices, Applicants are particularly well-manufactured in the circuit set, which can be selected and assembled in the final configuration of a particular embodiment. Consideration has been given to manufacturers with the option to combine a wide range of variations and ranges of possible materials that can maintain the desired grade of energy control function within a typical amalgan or energy regulator and / or energy regulator after it has been positioned and activated.

In general, a material 801 having predetermined properties may be inserted into a variable energy path or spacing or spaced function between electrodes (e.g., to facilitate conductive coupling between conductive portions). Non-conductive connections surrounding almost all points of the variable electrodes of the device to provide the device variable spacing (except for the locations normally found in each of the electrodes).

Materials and / or materials 801 having predetermined properties may not only provide energy insulation for the variable electrodes of the device, but also include case and / or structural supports; Provide the appropriate spacing required (similar to that described above) between the various shielded and shielding electrodes of the device.

Most of these material 801 components, alone and / or grouped, generally surround and relate to an electrode extending through and into a group of electrode path elements comprising predetermined pairings, and / or a number of various combinations. Oriented in adjacent relationship.

It should also be noted that the portion of the material 801 having predetermined properties, and / or the planar portion of the material 801 having only a single range or a single characteristic form of predetermined electrical properties, is not essential. In other forms of amalgan or energy regulators or energy devices, dielectrics, as well as varistor materials including spaced media, insulators, dielectrics, capacitive materials, and / or inductive, ferromagnetic, ferrite, materials 801 , Insulators, capacitive materials, varistors, metal-oxide varistor-like materials, ferromagnetic materials, material compounds or combinations having individual or any combined properties of ferrite materials and / or for the spaced energy paths of embodiments Embodiments of various forms of any combination that may be contemplated by the applicant.

In particular, the term 'material 801 alone', or 'dielectric only', allows a user to exchange most of any possible material 801 used. Material 801 may be particularly used as a material for spaced energy paths, or for supporting energy paths in amalgans or disclosed energy regulators, or some of which are not disclosed, in some other material 801 configuration Multiple operable energy conditioning functions to occur in some grades based on simple dielectric materials 801, such as those found in non-X7R materials 801 occurring in a grade, such as functions similar to user X7R yields. It may be allowed to be used to help form the.

For example, amalgan or energy regulators and / or energy regulators, including any combination of materials 801 and / or ferrite with ferrite properties, provide inductive properties in addition to the resistive properties inherent to the electrode.

Conductors, in addition to at least some spacing functions that may be generally filled by a dielectric, nonconductive, and / or semiconductive medium, a material in dielectric form, a material having predetermined properties, and / or a medium having predetermined properties, and What is considered to be non-conductive material portion 801 may be used.

Other forms of plates and / or portions of material 801, combinations of material 801, and / or lamination of material 801 may be used by self-supporting electrodes instead of other spacing materials such as air and / or any other spacing. It is not practical to accommodate electrode material deposits such that the material 801 is a chemically 'doped' and / or treated material.

More specifically, the material for the composition of an embodiment, for example, dielectric material 801 includes one and / or more material element layers that are generally not limited to any possible dielectric material and are compatible with the processing techniques available. can do. These materials may be semiconductor materials such as silicon, germanium, gallium-arsenate, gallium arsenide, and / or semi-insulating and / or insulating materials, but are not limited to any K, high K, and low K dielectrics, in particular It is not limited to any material having a dielectric constant K.

Note that the form of the electrically conductive semi-dielectric material 801 "SD" (not shown) with specific electrical resistance includes a negative temperature constant. These electrically conductive 'semi-dielectric' materials 801 " SD " are those materials and materials, as considered by the Applicant, with respect to methods of making and using new, typical amalgan or energy regulator components. The process was disclosed in International Patent Application Publication Wo 01/82314, filed April 25, 2000, and published globally on November 1, 2001, used herein. An electrically conductive 'semi-dielectric' layer 801 " SD " (not shown) is made from a green 'semi-dielectric' film or material and can be variously shielded and / or shielded electrodes according to user circumstances. Sintered together or combined with other materials 801 to allow the treatment to be performed at a particular electrode. Electrode lead portion 79 "X" may be conductively connected to couple electrode portion (s) or extension 798 "X" as is generally done. These electrode lead portions 79 " X " are separated from each other by a large shielding electrode 8 " XX " and are each complementarily insulated (within pairing) to complement the amalgan or different side portions of the energy regulator body. Are located according to associations.

One and / or multiple materials 801 and / or combinations thereof having different electrical properties from one another may be maintained between the shielded electrode and / or the shield electrode passageway and the shielded electrode of the device. Certain embodiment configurations and modifications of small forms having a thickness of several millimeters or less may include materials having defined properties and various optional electrodes, such as materials having different conductive properties including up to 10,000 and / or more layers. Can be implemented. Thus, a spacing material 801 in which a smaller size amalgan or amalgam or energy control subcircuit assembly is used by nanoscale electrodes, such as ferromagnetic materials and / or ferromagnetic materials, inductive-ferrite dielectric inducing materials, etc. You can take advantage of elements that contain). These materials provide structural support in most cases with various predetermined electrode path (s) within typical embodiments, but these materials with predetermined electrical properties allow all embodiments, and conductors to be part of a circuit network and / or activate a circuit network. And assists the circuit to be activated and / or maintained by simultaneously and continuously assisting the continuous transfer of energy portions that travel along various predetermined electrode path (s) that are intended and structurally supported.

Suitable conductor materials and / or electrode paths for the electrodes and / or electrodes can be selected from the group consisting of Ag, Ag / Pd, Cu, Ni, Pt, Au, Pd and / or such metals. Combinations of these metal materials of resistive materials suitable for this purpose may include suitable metal oxides (such as ruthenium oxide) that may be diluted with the appropriate metal depending on the context of the particular application. The other electrode portion, on the other hand, may be formed of an almost non-resistive conductive material. These self electrodes can use printed circuit board materials that follow any process that can form electrode paths from any material or material portion, material combination, film, formally non-conductive and / or semi-conductive material portion; Any material and / or process is not limited and may form conductive portions such as doped polysilicon, sintered polycrystalline (s), metal and / or polysilicon silicates, polysilicon silicates, and the like, as considered by the applicant. have.

In order to repeat the embodiment, it is not limited to any possible conductive material such as magnetic, nickel-based material. Also included is the use of additional electrode structure elements, including a strip portion or a mixture of conductive and nonconductive elements, multiple electrode paths of different conductive material portion compositions, material hybrids affecting the conductive field, and conductive polymer sheets. , Variously processed conductive and non-conductive laminates, streaked conductive deposits, multiple shields, associated electrode paths may be used for various types of magnetic material shielding and selective shielding, doping (where the conductive or non-conductive portion (s) of a typical new energy regulator). Is constituted by a doping process) or is conductively deposited on the material, such as by conductive soldering, and the various combinations and structural elements of the material can be individually and / or non-individual typical amalgan or energy regulators and / or to the user. Prior to energy control and / or manufacturing When placed in a predetermined configuration and / or large electrical system for energizing generally be used to provide a host and a variety of energy control options.

Typical device manufacturing tolerances and capacitive balances of opposite complementary electrode pathways are found between commonly divided typical amalgan or central electrode pathways of the energy regulator or electrode device portion, in particular measuring the opposite side of the divided electrode device structure. The use of an electrode conductive material portion, such as X7R and / or a common non-specific dielectric, which is found in the case and is commonly widely specified among the prior art discrete devices, facilitates at the capacitive or magnetic level formed at the factory during the manufacture of the energy conditioning device. Can be maintained.

Amalgans or energy regulators are designed to operate simultaneously in electrical complementary operation in A-line coupling in the A-line, as well as at least in the C-line and in the B-line to the C-line (C- The line is a conductive part), designed to operate on the C-line (GnD in many cases). The GnD potential or the voltage reference potential is the result of mutual distribution. Thus, the elements located on each opposite side of the C-line, complementary capacitive balance and / or tolerance balancing characteristics from each of the paired A-line to C-line for these types of energy circuits, these Micron proximity related positioning, as well as the size (loop area or portion) of the separation, allows for electrode placement, which is typically manufactured internally with 1-3% capacitive tolerance, and when placed in a system (this is exemplary and principle With respect to the energy distribution shielding electrode structure, for example, the original 1-3% capacity internally between the complementary energy path and electrical and / or charge alleles of the pair within a typical amalgan or energy regulator or electrode device. It maintains sex tolerance and passes through the activation energy of capacitive tolerance that may be related.

Where specially intended devices are manufactured, they may be formed, embedded, enclosed and enclosed in other sub-systems or various energy systems to effect deformation or line regulation, decoupling of energy propagation to the desired energy form or electrical shape, depending on the attached design. And / or may be inserted.

Such specially designed devices may be arranged between adjacent amalgans or energy regulators and / or energy control device elements grouped so that the energy control device configuration minimizes hysteresis and piezoelectric effects throughout the elements including voltage distribution and specially designed devices. Allows to utilize the energy balancing mechanism of opposing pressure found internally.

The device is transferred to the dynamic operation of the voltage distribution embodiment and typical embodiments that minimize and reduce the hysteresis and piezoelectric effects of the various material elements are more than would be possible with devices not owned by most of the active components utilizing these regulating energies. Assists to be maintained within AOC 813 of a typical amalgan or energy regulator and / or energy regulator to deliver a large number of acceptable energies.

The active component requires instantaneous energy to operate with an interference-free and harmonious energy supply to coordinate the effective energy utilization load behavior in which the energy utilization load (connected to the amalgam and / or energy regulator circuit) is performed. It undergoes a switching response under an internal load that requires a switching time limit designed to.

Harmonic energy without interference is totally arranged to be electrically and physically located on the same opposing side, the assigned common shield electrode (s) and / or common shield, electrode (s), arranged uniformly and amalgams of uniform size. The supply to the energy-utilizing rods is facilitated by a pair of complementary electrode paths that practically take into account part of each circuit system present in the amalgan or in the portion of AOC 813 of the energy regulator. Thus, the effect of such an arbitrated and shielded circuit portion is that the conductive coupling groups forming a varying number of covalent shields, common electrode (s) and / or voltage distribution functions may each comprise at least one pair of two opposing pairs of complementary conductors. Provides grouping (2) of half the voltage energy from the same size conductors (per multi-circuit device), circuits (per circuit), and allows for approximately half the energy per line of a pair of circuit systems or various circuit voltage utilization Actually distributes.

In dynamic operation, conductors or electrode paths (not complementary paths) within an activated circuit, because complementary pairs and electrodes of the same shielded size face each other in a charge-optical manner between physically and electrically mediated shielding associations. It is possible to recognize the existing voltage distribution relationship.

Activated circuits comprising complementary conductors in a typical amalgan or electrode device are internally balanced in a totally electrically and / or charge-opposite manner, with each circuit system in relation to a centrally located shielded, common and shared path. The electrode (s) to the member and / or part are amalgan and / or energy regulating devices.

Each common circuit system member and / or portion comprising an energy conditioner and / or energy conditioning formulation comprises a variety of energy transfer rates found in each of at least multiple circuits including at least a portion of an AOC 813 typing energy conditioner and / or energy conditioning formulation. Typically attached or (conductive) to a common region or portion and / or to a common electrode to provide an external common zero voltage for the energy assembly and / or specifically for the energy relationship to the " zero " reference circuit node of the typing energy conditioner. Combined).

As mentioned above, independent and / or non-independent, particularly suitably connected energy conditioners and / or energy conditioning formulations may be used to complete the energy source, each paired energy path, each energy usage load, and each circuit completing each circuit. Voltages using a variety of parallel positioning principles for a pair of external parts or for a plurality of paired circuit parts, typically from decoupled, filtered, independent or separate circuits, relative to each energy path returning to the energy source. It helps to achieve the ability to perform multiple and separate energy-conditioning functions simultaneously, such as balancing.

Thus, in the opposite case of conventional energy conditioners during opposing or reactive active operation, which can produce a wide range of hysteresis effects, material memory effects, angular stresses, swelling by thermal stressing of various materials in single lines and conventional devices, etc. Internally balanced circuit portions can operate to split the same effects and stresses symmetrically by the use of an insertion shielding energy path that each splits these forces into opposite complementary effects and stresses against each other. Thus, the opposite balanced and symmetrical compensating energy portions and / or forces mutually undergo opposite energy partial propagation states or dynamic operations, thereby compensating the voltage of a conventional energy conditioner that divides the performance of a conventional energy conditioner structure. AOC 813 initially offsets or negates each other.

On the contrary, by means of electrical offset and complementary positioning of portions of propagation energy operating along a pair of complementary internal electrodes in a balanced manner from opposite sides of the shielding energy path, the "0" voltage reference functions Simultaneously produced by electrically common electrically conductively coupled identically-positioned and shared shielding electrodes.

Piezoelectric effects are also minimized for materials that compensate for some of the embodiments. As such, the energy portion is not initially used or bypassed inefficiently within the AOC 813, so the performance of standard and common dielectric materials to perform functions by being designed for use in the AOC 813 and circuitry is broad and limited in use, saving costs. It is useful by energy use loads at significant dynamic increases in.

Conventional energy conditioners and / or energy conditioning formulations allow to exhibit increased performance of 801 materials (conventionally used) above the level of performance typically observed, especially when used with prior art devices, especially in the energized state. However, this increased performance of 801 materials would ideally be observed, and all the results of the energy path installations that enable energy partial transfers symmetrically and complementary to each other are in an efficient manner so that these materials are produced. It is a 801 material that operates in an 'uncontrolled' or unrestricted state of performance closer to the ideal performance development it contains, is intended for, and is used.

Thus, conventional conditioning formulations as a whole reduce or minimize observed physical inefficiencies that, in dynamic operation, additionally limit the possible certain properties of the 801 material when prior art devices are used in conventional circuit systems. .

The use of conventional energy conditioning equipment particularly suitably connected in the same circuit allows for a balanced partial symmetry of energy partial interactions to be achieved by complementary energy partial transfer occurring within the AOC 813 of conventional conditioning equipment or amalgams.

Thus, conventional conditioning formulations or amalgams as a whole are substantially dependent on the ideal state of the 801 material designed for the performance that the 801 material is generally masked (by conventional techniques) as the 801 material functions for a given circuit system. Create or generate closer energy conditioning functions.

The results are particularly designed to simultaneously achieve piezoelectric effects of 801 materials and minimization of portions of hysteresis of conventional 801 materials due to the absence of unbalanced energy or parasitics observed and nominally found in comparable circuits using conventional techniques in some cases. Can be observed.

Simultaneous minimization of hysteresis of conventional 801 materials and control of the piezoelectric effect of 801 materials typically occurs in AOC 813, which is observed in the opposite case. This simultaneous minimization of hysteresis and piezoelectric effects allows SSO states, power system decoupling, stress reduction, faster use of passive elements by active elements applied directly to such stress reduction, and delivered energy to use conventional embodiment configurations. The ability to switch or equalize to increase energy conditioning performance levels for applications such as an allowed balanced approach.

This situation is caused by the energy-in and energy-out paths (energy-in and energy) in which a typical installation connects and / or couples from an energy source to each energy use load and back to the energy source for return. The out-out path is relative to the energy usage load and energy source and is not essential to the embodiment, but in most cases it is placed in parallel to the energy usage load and energy source in a bypass structure as opposed to guiding the feedthrough facility. And a common, apparent open energy flow to both electrical sides of the common energy reference (first plurality of electrodes or shielded energy paths).

The feed-through electrode can be a bypass facility if the circuit path bypasses only the AOC 813, but at least through the integrator and vice versa, allowing all energy to pass through the AOC 813.

This is a parallel energy distribution design that allows the material to constitute most energy conditioner and / or energy conditioning equipment elements manufactured to operate or function more effectively and efficiently with energy source paths and energy use loads that are disposed as part of the overall circuit system. . Thus, the integrated body is a fully integrated, functional and compensatory energy conditioning network.

A conventional energy conditioning installation may be an electrode element with other predetermined elements, in particular in any connected circuit arrangement combination using a conventional energy conditioner electrode arrangement, which is a physical and generated energy distribution structure.

Odd-integer multi-electrode conductive couplings and / or conductive attachments, which are shields for external conductive regions or portions (not isolated or part of the compensation circuit) and compensation energy paths other than any compensation electrode or shielding path, are in particular standard conductive couplings and / or Or a variety of standard industrial attachment / bonding materials and attachment methodologies used to create materials that are operable to conductive bonds, such as soldering, resistive feet, leaf soldering, conductive attachment, etc., which are nominally standard industry acceptable materials and processes used for bonding. do.

Particular embodiments of the conductive coupling and conductive attachment techniques and methods in circuit installations, especially with respect to external energy paths, can be easily applied and / or simply applied to the user, easily and without additional constraints. Conductively coupling the electrodes together or as a group to an external common region or portion and / or path allows for the optimum energy conditioning function to be provided by conventional energy conditioning and / or energy conditioning equipment, which in particular is operable in most cases. While this energy conditioning function provides passive device characteristics, it is not limited to mutual cancellation of induction, mutual minimization of energy parasitics operable from opposing conductors.

It should be noted that there are at least three shielding functions that normally occur in conventional energy conditioners or electrode installations, especially when they are conductively coupled to each other because of a plurality of amalgamated electrodes, which are used for shielding, which is some function that depends more on variables than others. do. First of all, the physical turn function is typically the classic "metal barrier" for most kinds of electromagnetic fields, and is generally the same as the RFI that most people believe is actually shielding, but this metal barrier is the overall performance of the three shielding functions used. As a normal reinforcing element.

Other shielding functions used in the typical embodiments are specifically included and in the manner of relative sizing relations and relative positional relationships of opposite paired complementary electrode paths or predetermined positions or relative positions between respective shielding electrodes relative to a predetermined position. Can be partitioned in the manner of relationship and relative sizing relationship.

The electrode path is typically sandwiched between at least two shielding electrodes in reverse mirroring sandwiching for paired complementary electrode path mates, which are generally the same shape and size in each component, as conventional manufacturing tolerances permit. As such, the opposite paired complementary electrode paths are operable insertion of portions relative to each conductive portion of the conductive region of the shielding electrode or the conductive region of the paired complementary electrode path.

The physical shielding of the complementary electrode path portion of the paired, electrically opposite, second shielding function is fundamental to the complementary path involved and by the size of the conventional electrode path in relation to the complementary electrode path / electrode size. Prevent non-reverse binding of non-external parasitics to shielded complementary pathways, sometimes referred to in particular as parasitic coupling, and achieved by reduction of parasitics resulting from energized electrostatic suppression and / or sandwiched complementary conductors do.

Parasitic bonds are generally known as electric field ("E") bonds, and this shielding function primarily shields electrostatically diverse shielding electrodes against electric field parasitics. Parasitic bonds that include pathways that interfere with the transfer energy due to mutual and / or stray parasitic energy originating from the complementary conductor paths are generally suppressed in new unique electrode configurations. Conventional energy conditioner or electrode arrangements are nearly opposite phases in an integrated shielding structure, in particular with capacitive layer progression that provides an electrostatic and / or Faraday shielding effect, and predetermined layer positions and arrangements of layers arranged and coplanar (interlocked). Blocking capacitive coupling by developing a conductor

Coupling with an external common capacitive portion without capacitive coupling with a complementary electrode path is such that an inherent common capacitive portion, such as in a capacitive motor shell, can be used in a capacitive chassis and / or earth energy path and / or circuit, for example. As is not necessarily attached and / or (capacitively) coupled to the conductor and / or chassis energy path and / or conductor, and / or PCB energy path and / or conductor, and / or earth ground, which are system energy return. It may include parts described in common. The use of a set of internally placed common electrodes will be described as part of the energy propagation that propagates along the paired complementary electrode paths, which portion of energy is particularly relevant to conventional energy conditioners and / or energy conditioner assemblies AOC 813. Can be continuously moved to at least one commonly externally located capacitive portion, rather than a plurality of complementary electrode vias, resulting in dumping and suppression as well as the return of energy and unwanted EMI noise back to each energized circuit. Non-complementary energy paths, such as low impedance energy paths, can be used to block feedback.

Finally, there is a third type of shielding, which is generally more than an energy conductor location 'shielding technique', which is generally inductive energy and / or "H-field" and / or simply 'energy field coupling'. 'Is a combination of physical and physical inductive energy that is used for, and is generally simply an' energy field 'energy portion that is mutually inductively offset and / or "H-field" and / or separated and propagates along the opposite electrode path. However, the use of complementary pairs of electrode paths using physically shielding energy by means of a predetermined location scheme controls the size of the "H-field" current loop in the portion of the internal positioning circuit that includes the various parts that propagate the energy. Within an area or location as closely as possible in size to induce a 'shielding technique' and / or other types of shielding called intensified electrostatic and / or cage effects for inductive "H-fields" with mutually offset means. Allows insertion of complementary electrode paths that are accommodated in pairs.

Disturbance energy parasitics 'given back' and / or minimal to circuit systems obtained in particular embodiments, as they are generally passively operated in larger circuit systems simultaneously but separately from one another. While maintaining parasitic distribution, in particular the use of specific embodiments is possible for each, but in order to use a common low impedance path developed with its own voltage reference, among other things, isolate the circuit operation within a specific embodiment. At the same time, each shared circuit is potentially maintained and balanced at its relative energy reference point in a shared fashion.

Conventional electrode shielding devices or arrangements will be present within the same time, and the portion that propagates the circuit energy is limited to the complementary portion of the propagating opposing and shield energy contained within the portion of the AOC 813 related to the same common reference image. At the moment it will have a high impedance energy blocking function like a diode, and at that same moment, the low impedance energy void and the function for the energy part opposite the instantaneous high impedance for the energy part Operating in an ordinary, high-low impedance switching state, which occurs in a momentary and corresponding symmetrical manner, straddling opposite sides of the common energy path in a dynamic manner at the same instant of time, Everything related to the parts of energy is equilibrated and correspondingly Of the same, and are located opposite to each other electrically in the shielding device in a coordinated manner as a whole structure shared.

The internally located common electrode set is conductively coupled to the same common externally located conductive portion rather than the complementary electrode path, so that most circuit systems use this non-complementary energy path for undesirable EMI noise and energy. In addition to dumping and suppressing the return, it is also used simultaneously as a low impedance energy path associated with each operating circuit system to prevent the return from returning to the respective powering circuit system.

The propagation energy portions along the various circuit paths are dependent on the specific embodiments of the AOC because they simultaneously suppress the energy parasitics that contribute to the surrounding shielding electrode structure with the removal of the mutually opposed energy "H" field that contributed to the electrically opposed shielded electrodes. Occurring simultaneously within 813 and, in particular, through the simultaneous function as described in the AOC 813 of each and any conventional or specific embodiment within the circuit arrangement, H-field energy and E-field energy (E Field energy also allows for experiencing a conditioning effect of generating propagation energy in a form that minimizes the deleterious effects of near-field energy fluxes, in particular this is instantaneous, but paired, still distributed and shielded. Use by portions of energy found along propagation potential routing of complementary electrode paths Related to be constant and the dynamic switching that each is located on the opposite side to each other and including a simultaneous low and high impedance is relatively defined by the area of the energy path and maintain.

FIG. 1 is best shown by 800C in FIG. 10, which includes a predetermined, positioned centrally shared common shielding electrode 800 / 800-IM-C having a portion of material 801 having predetermined properties. A portion of shielding electrode 800 / 800-IM is shown that represents a portion of switching unit 800Q shown.

In FIG. 2, the shielded electrodes 845BA, 845BB, 855BA, 855BB, 865BA, 865BB are generally shown as smaller sized electrodes of two sets of electrodes of a second plurality of electrodes. In this configuration, the smaller-sized, main-body electrode portion 80 is used by the energy portion propagation 813B, but similar to the electrode portion of FIG. 1 and similar in shape to a single shielding structure (not shown). However, the larger sized, main-body electrode portion 81 of the unequal shielding electrode 800 / 800-IM-C is the center of the shielding electrode and the AOC 813 portion of similar effect as that shown in FIG. It will process the energy partial propagation 813A that moves out of the portion.

Referring back to FIG. 1, the electrodes and / or electrode paths 855BB and 855BT (not shown) that simultaneously sandwich the central shielding electrodes 800 / 800-IM-C in a predetermined manner, respectively, are centrally located. Are moving in both directions from the common shielding electrodes 800 / 800-IM-C. The main-body electrode portion 81 of each shielding electrode of the plurality of shielding electrodes is sandwiched by any corresponding sandwich of the plurality of shielded electrodes. It is important to recognize that the sandwiching of the shielded electrode is larger than the main-body electrode portion 80. A number of shielded electrodes are typically configured when shielded with a bypass electrode as described herein, but shielded feedthrough The feedthru electrode may be configured as necessary.

The manufacturer positioning the conductive material 799 as the electrode 855BA creates an insertion portion 806 and / or a distance 806, and / or a spaced portion 806, which is associated with the shielded electrode 855BA. It is related to the position of the shield electrode 800. This insertion relationship is typically better represented by and / or defined by the relative insertion spacing due to the different sizing between the two main-body electrode portions 80 and 81, wherein the main-body electrode portion 81 is one of the two electrodes. Is bigger. This relative sizing also relates to the positional arrangement of the various electrode portions 80 and 81 and their respective adjacent electrode portion extensions, designated herein as 79G and / or 79 "X" X ", the majority of which are conductive Located and arranged during the sequential layered manufacturing process of the material 799 and / or 799 "Z", the conductive material in turn has a designated electrode perimeter edge 803 of each electrode main-body portion 80. And the insertion relationship and / or appearance found between each designated electrode limit edge 805 of each larger electrode main-body portion 81.

In most versions of conventional energy regulators or electrode arrangements, in particular, the main-body electrode 80/81 is typically defined by two major surface portions, but the electrode of the material 799 of each electrode element used. It is formed to a desired extent to form the main-body portion 80 and / or 81 and typically the general portion size of the material 799 can be ordered. These electrode main-body portions 80 and / or 81 are adjacently coupled 79G and / or 79 " XZ " or 79 " XX " leads, such as defining the size of conventional main-body electrodes 80/81. It will not include any electrode portions that are considered to consist of electrodes and / or electrode extension portions.

The size of most electrode main-body portion 81 material 799 and / or the size of most electrode main-body portion 80 for any respective electrode is any conventional energy regulator and / or energy-controlled. Within the device (when allowing manufacturing limits) it can be of the same type per group 80 or 81 (mixed per individual sub-circuit device relative to a different set of sub-circuit device electrodes) and the insertion positioning relationship It should be appreciated that it may be optional.

In order to further suppress the parasitic energy portion and further shield the various parasitic energy portions, the insertion of complementary electrodes allows the electrode main-body portion 80 within the superimposed alignment of the larger-sized main-body electrode 81. This exists. By limiting the use of or including the electrode main-body portion 81, the parasitic energy portion suppression function can be operated in a very effective manner.

Restriction of the insertion of the complementary electrode main-body portion 80 into the footprint of the larger electrode main-body portion 81 limits the at least predetermined electrode main-body portion 80 of the two larger electrodes. Compared to configurations using devices that do not use the insertion of a predetermined electrode main-body portion 80 therein, it is possible to enhance the efficiency of a larger and overall shielding electrode structure for dynamic shielding (electrostatic shielding) of energy.

Insertion distance 806 is an insertion distance that is associated with a spaced apart multiplier between adjacent electrode main-body portion 81 and electrode main-body portion 80 of an electrode comprising an electrode arrangement, at least greater than zero. It can be limited to distance multipliers found to be larger. In an embodiment spaced apart of a material having a predetermined characteristic 801 found to separate and / or maintain separation between two conventional adjacent electrode main-body portions 80 and electrode main-body portions 81 Falling thickness multipliers can be used as insertion range determiners.

For example, the electrode main-body portion 80 of the 855BB is the electrode main-body portion 81 of the adjacent center co-planar electrode 800-IM similar to that of FIG. 1 and the electrode main-body portion 80 of the electrode 855BB. It may be said to be 20+ (or more) times the distance and / or thickness of a material having a predetermined property 801 found to separate and / or maintain separation therebetween. This amount or range distance or area of insertion is variable for each application, but the complementary electrode is where electrostatic shielding is efficient or any (adjacent) electrode adjacent to the shielding electrode is being shielded by it (any shielding electrode). Or no less than any one electrode next to the shielded electrode.

The electrode or energy path may be extended by 79 "XZ", "X" = "B" =-bypass or "F" -feedthrough, "Z" = electrode "A" or "B", depending on the radio wave used. If necessary, it will include a main-body electrode 80 having at least a first lead or extension portion designated as a numbered unit in which there is at least one extension portion per main-body electrode. For example, FIG. 1 uses 79BA as an extension of electrode 855BA. Complementary main-body electrode 80 of 855BA, which is not shown as having at least a first lead or extension portion, also has a first and second lead or extension portion of electrodes 855BA and 855BB (not shown). Will be designated 79BB since it is arranged complementarily opposite to the other electrode at.

Applicants should be aware that, in any array configuration, it considers the various size difference electrode pairs allowed between the various electrode main-body portions designated as 80 of multiple coplanar arranged electrodes. Although not shown, layers and / or portions of materials having predetermined properties 801 may include additional co-planar electrode layers. Each external electrode portion and / or electrode material portion 890A, 890B and / or designated 890 " X ", 798- for each of the plurality of electrodes to facilitate common conductive coupling of the various and identical electrode members. 1, 798-2, and / or designated 798- " X " (not all shown) are subsequently designated by any external conductive portion (not shown), energy paths (not shown all) Conductive bonding of the electrodes can be facilitated.

When focusing beyond the electrode extension portion (or simply the extension portion used herein) adjacent to the configuration for each electrode main-body portion 80 and / or 81, generally the electrode main-body portion 80 It is usually spaced apart but physically inserts a predetermined distance to create the insertion portion 806 relative to the electrode main-body portion 81. The electrode main-body portion 80 is typically smaller-sized (compared to the adjacent main-body shield electrode 81) and at least two spaced apart, but electrode main-body portions of the two larger shield electrodes. Overlaps within the coverage of 81, except that it is respectively operable for subsequent conductive coupling to adjacent internally separated electrode main-body portions 80 and above. It is an electrode extension part like a similar 79BA.

The same fabrication process places the 79 "XZ" or 79 "XX" lead electrodes and / or extension portions at the same time as non-integer and / or adjacent positions and / or processes and works very well, joins or any other of the new electrode device. The non-integer, 79 "XZ" or 79 "XX" (not shown) moiety is subsequently fused by or during the manufacture of the modification. Non-adjacent / integer generated 79 " XZ " or 79 " XX " parts, in which subsequently extended forms are permitted and still need to be conductively coupled in a manner that allows substantially the same conditions for adjacent versions of the application. And such combination of electrode main-body portions 80 will be used.

The electrode main-body portion 80 and / or 81 ends and the 79G and / or 79 " XZ " or 79 " XX " extension electrode portions are typically safe except to define conventional shielded electrodes and / or extensions. There is typically no exact way to determine the exact point to begin for the shielding electrode of the electrode, and the electrode main-body portion 80 for a conventional shielded electrode is a group of shielded electrodes found within an electrode device embodiment. Shielding electrodes forming a common electrode shielding limit edge 805 from a predetermined number of common overlapping devices of the electrode main-body portion 81, which may be any number of odd integers greater than one of the common electrode members, for shielding The average and / or average of predetermined distances found between and / or within the average common limits and / or conventional limits of shielding electrode edges 805 of adjacent shielding electrodes of Lee determined will be considered to be the part that is positioned in order to create a distance.

Therefore, it must include at least three shield electrodes in order to shield the paired complementary electrodes in a conventional energy regulator or electrode device, in particular associated with the electrode main-body portion 80 of the at least two shielded electrodes. The same conductive material 799 includes in particular the majority of electrodes of a conventional energy regulator or electrode device, and is thus heterogeneous by means of a predetermined electrode material in which the conventional energy regulator or electrode device is arranged in a particularly predetermined manner. While homogeneous electrode material 799 is equally sufficient.

At least two multiple electrodes are typically present, and in the first plurality of electrodes each electrode is of substantially the same size and shape relative to each other. These first electrodes of the first plurality of electrodes are also conductively coupled to one another, overlapping one another and aligned in parallel. These common electrodes are also spaced apart from each other so that a varying number of second plurality of devices are associated with each other (absence of the second plurality of electrodes) in the overlapping shielding device created by the first plurality of electrodes. To facilitate. This means that stacking or stacking of the first plurality of electrodes can be done regardless of the axis of rotation of the superimposed group of the first plurality of electrodes with respect to the horizontal of the earth.

Within this first plurality of electrodes, the device or superimposed stacking will comprise at least a portion of the 801 material having predetermined properties. The number of configurations of the first plurality of overlapping electrodes is one or more odd numbered integers.

These electrodes are conductively coupled to each other by at least a portion of a conductive material that provides adjacent and common conductive bonds along at least the edges of each common grouped electrode of the electrodes such that the plurality of non-grounded single common conductive structures, non-grounded Function as a shielded conductive cage or a non-grounded Faraday cage. In many configurations, at least two portions of the conductive material will provide adjacent and common conductive bonds along at least the edges of each common grouped electrode of the electrodes on at least two portions of the grouped edges and will be separated from the others. When this portion or portion of the current shielding structure is conductively coupled to an external conductive potential, a ground or reference state will be created.

The total number of the second plurality of electrodes is an even integer. Also, the plurality of second electrodes may be composed of two groups or sets, which may be considered to be divided into half of the same number of the plurality of second electrodes including the first electrode set, wherein two of the same number of electrodes It is considered to be supplemented to the other half of the electrode set and has paired electrodes corresponding to each other as in only two electrodes in each of the pair of electrodes (according to the description below, such a set includes at least first and first 2 may be characterized as multiple electrodes).

The electrodes are arranged in spaces separated from each other. If they are considered to be in the same plane as the devices of the other electrodes of the first set of electrodes when they are found in one layer, the second electrode of the plurality of second electrodes on the second same planar layer of the electrodes Each electrode in the set pairs correspondingly to the oppositely arranged electrodes that are replenished with each other. As shown in FIGS. 5D-5C, 6A, and 8A, the electrodes of each first or second electrode set may be on the same plane and intersect with each other, but like a pair of electrodes spaced in opposite directions in another layer. Each of the electrodes of the same plane may be interspersed.

Although the electrodes of certain complementary pairs are shielded from one another, the second complementary electrode pairs disposed separately from each other having substantially the same size and shape, and generally having the same size and shape, are the first beams shown in FIGS. 3A and 4A. Like the electrodes of the electrode pair, each does not have to correspond to the same size and shape.

As part of the overall electrode arrangement of most energy conditioners, the (shielding) first electrode pair and the (shielded) second electrode pair maintain their respective size and shape relationships from each other. The first electrode pair and the second electrode pair of the plurality of second electrodes may include electrodes having substantially the same size and shape, but are not required. Just as a pair of electrodes operates 'individually', any pair of complementary electrodes needs to be maintained as two electrodes of the same size and shape with each other such that a complementary relationship is created between a particular pair of electrodes.

In another example, the second electrode pair may have the same size as the first electrode pair, but the second electrode pair may have a different shape than the shape of the first electrode pair. That is, it may have an opposite shape. Other electrode pairs added to the at least two electrode pairs may also maintain sizes and shapes different from those of the first two electrode pairs as part of a total new energy conditioner having an electrode device.

Subsequently, although not shown, the following examples provide a variety of different electrode combinations, each associated with a particular embodiment shown, but consistent with the main purpose of the present invention. It is a primary object of the present invention to provide at least two independent and electrically insulated circuit systems that are shielded and shielded electrode devices so that they can utilize one conventional discrete or non-dispersive energy conditioner dynamically with one another with electrode devices therein. It is to provide an electrode combination.

Thus, among other things, the new conventional passive architecture, as used by certain embodiments, can be configured to examine and / or minimize the various types of energy fields (h-field and e-field) that can be seen in the energy system. have. Certain embodiments generally do not necessarily have to be configured to inspect more than one type of energy field than another, but other types of materials may be used to set up embodiments that can perform specific inspections on one energy field than another. It is contemplated to be added and / or used in combination with several electrode sets. Various thicknesses of dielectric materials and / or media and embedded shielding electrode structures can take advantage of conductive parts in which the dynamic and adjacency distance relationships within a circuit architecture are non-conductive or the same semiconductive distance between each other. have.

As shown in Figs. 2A and 2B, an embodiment such as 6000 above all means that at least two independent parts of the electrically isolated circuit system are dynamically used and combined with each other, as shown in Fig. 2C, with associated predetermined element parts and size relations. And a group of predetermined elements, each arranged in accordance with a defined element separation-placement and positional relationship, wherein at the same time one common circuit reference potential or node is provided separately by the shielding electrode portion of a given energy conditioner, the shielding of which The part is conductively combined with the common voltage potential of the conductive part located above the conventional energy conditioner, among other AOC813.

Conductive coupling of multiple shielding electrodes to an external common conductive portion disposed on the AOC813 is accomplished using known standard coupling means such as brazing material (not shown) or resistive pit coupling (not shown) or other physically accomplished means. At that time, the shielding structure extends through the conductive 'melt' or conductive integrated portion of the resulting larger shield. The shielding electrode structures 830, 820, 810, 800 / 800-IM-C of the electrode are conductively extended to the electrode extensions 79G-1,79G-2,79G-3,79G-4, and 798G-1,798G-2,798G-3,798G-4 ) To final physical action with conductive part 007 by known standard means, which may be coupled to and may include any or most of all types of bonding methods, processes or conductive materials, (substances concomitant with certain selected uses), and the like. Combined, the conductive portion 007 functions as part of a conventional energy conditioner circuit arrangement in which the CRN or common reference node shown in FIG. 2C is established during a dynamic or energy supply operation and the shielding structural elements include conventional embodiments. It is a simple extension of the outer conductive portion 007 disposed adjacent to and parallel to the order of several microns in the circuit path portions that face each pair for each circuit.

The typical energy conditioner configurations shown here are shown in FIGS. 2A, 3A, 4A, 5A, 6A, 7A, respectively, illustrating embodiments 6000, 8000, 10000, 1000, 1100, 1201, 1200, 9200, 9210, respectively. 8A, 10, and 11. Among these embodiments, there are at least three types of multi-circuit energy conditioner devices disclosed herein, which are of the straight stack multi-circuit device, the straight coplanar stack multi-circuit device and the straight / coplanar multi-circuit device. Combination, each having an internally integrated configuration. In general, the energy conditioner includes at least two internally located circuit portions to the circuit system, of which two circuit portions are each considered to be part of a larger circuit system.

Each circuit portion may include a first and a second energy path portion, each of which is a portion considered at some point of a conventional energy conditioner within AOC813. For example, the first and second energy paths of each isolated circuit system are S-LC2, L-S-C2 and S-L-C1, L-S-C1. Each of the first and second electrode portions of the energy paths 855BA and 855BB for C1 and the energy paths 845BA, 845BB and 865BA and 865BB for C2 exists as an energy path of an energy source (002 = C2,001 = C1). The energy-using rods L2 = C2 and L1 = C1 are part of the overall multi-circuit system apparatus 0000 and are each arranged for complementary electrical operation with respect to others. Each of the circuitry located inside each of the paths for C1 (855BA, 855BB) and the path for C2 (845BA, 845BB, 865BA, 865BB) is connected to the first and second energy paths via extensions and, if necessary ( To external electrodes C2-890BB, C2-890BA, C1-890AA, C1-890BB, which are external to the energy conditioner.

For example, conductive connection with a portion of an energy conditioner made at a predetermined location (C2-890BB, C2-890BA, C1-890AA, C1-890BB) may be achieved by soldering, by a predetermined conductive connection process or method, or by a predetermined physical connection technique. It can be carried out using predetermined materials used in electrical connection techniques such as melting machine chemical connection means, such methods being used today or in future soldering (not shown) or resistive fittings (not shown) or the like. All standard industrial means of conductive connection or conductive connection are included. Such internal circuitry can be considered an electrode path or the complementary energy path described above. In general, the internal circuitry does not include shielding electrodes 835,825,815,800 / 800-IM, 810,820,830,840, as described, of which the shielding energy paths are located away, and are predetermined from directional electrical connections that can provide space separation function, insulation. It is insulated from the directional electrical connection by at least a portion comprising a material having the properties 801.

The first and second circuit systems (C / 2C1 in FIG. 2C) each having at least two pairs of circuit sections each have at least one energy source (002 ==) for at least a first energy path and at least a second energy path per circuit. C2,001 = C1) and an energy-using rod portion (L2 = C2, L1 = C1), respectively. Each circuit system generally starts with a first energy path derived from a first side of the energy source, which can be considered the supply-side of the energy source, the first energy path being substantially the first of the energy usage rod. Connected to the side, which is considered the energy input side of the energy usage rod.

The connection made to the point of the energy source and the energy usage rod is for the first energy path, which is a second position where this position is challenging physically between the energy usage rod and the energy source, like the return energy path to the energy source. It is contemplated to cause electrical isolation from the positioning device of the first energy path. Thus, at least the second energy path leaving the second side of the energy source (after some energy has been converted by the energy-using rod for use or operation) and considered as the return-out side of the energy usage rod is an energy-using rod. Is connected as the energy return-in side of the energy source.

Each of the at least three types of multicircuit energy conditioner devices is surprisingly different; Stack multi-circuit energy conditioner devices include devices in which the circuitry is positioned or positioned in a relationship that does not necessarily have to complement or complement other circuit system portions of electrical operation above the other circuitry. Furthermore, at least two pairs of circuit system sections are oriented in relation to the other pairs in the device such that a "nurled" interaction between two separate circuit systems occurs within the same energy conditioner, and two pairs of pairs of electrical system sections Divides the voltage reference used by the "grounded" shielding structure including a plurality of shielding electrodes that are conductively connected to each other and conductively connected to any respective circuit system or pair of outer conductors.

In some cases, conductive connections to one part of the complementary energy path by one circuit system pair, rather than the other part, are connected to each other by conductive connections of this type of arrangement or biasing of one arrangement or vice versa. Favoring a circuit system for one would be desirable for some users to be fully considered by the applicant.

However, when the conductive insulation of the shielding structure is maintained, the path of least impedance generated by connecting to the non-complementary energy path of the circuit system dynamically creates a low impedance energy path common to the energy of at least two isolated circuit systems, These are arranged for interrelated operations, such as the straight stacking of embodiment 6000, and are stacked in sequence with respect to at least one respective positioning representing a stacked or adjacent arrangement between a plurality of shielding electrodes.

2A-2B, an embodiment of an energy conditioner 6000 is shown. Above all, the energy conditioner 6000 shown in FIG. 2A is shown in an exploded view showing the individual electrode layers formed or disposed on the material layer 801 as described above. The predetermined embodiment structure of FIG. 2A is an odd shield of electrodes of the same size and shape of electrodes 835, 825, 815, 800 / 800-IM, 810, 820, 830, 840 that are conductively connected together to provide shielding to a portion of a circuit path pair of a small size already named. A predetermined shielding electrode arrangement comprising the arrangement. In addition, the shield arrangement of the odd numbered electrodes of the same size and shape may include an optional shielding electrode (not shown) to image the plane shielding electrodes (-IMI "X" and / or -IMO "X").

In addition, the energy conditioner 6000 may include a plurality of second electrodes (C 845BA, 845BB, 865BA, C2) that are generally the same size and shape as the at least a plurality of first electrodes 835,825,815,800 / 800-IM, 810,820,830,840 of the same size and shape. 865BB, and 855BB for C1), and these electrodes can be configured for several combinations of hosts with multiple single or sub-multiple electrode configurations (845BA, 845BB) of two multiple first and second multiple electrodes. , 865BA, 865BB electrodes), which combinations are provided with a conventional energy conditioner in any possible number of uniformly grouped pairs of electrodes, which electrodes also have a second majority with a first plurality of electrodes. It can be seen that the electrodes are collected to include an electrode set.

In FIG. 2B, the energy conditioner 6000 operates with eight possible couplings to each external electrode portion 798-1,798-2,798-3,798-4,890AA, 890AB, 890BA, 890BB. Among the possible couplings, the energy conditioner 6000 may be connected to the five conductive insulation paths 001A, 001B, 002A, 002B and the conductive region 007 as shown in FIG. 2C. Thus, each pair of complementary paths is in the direction of two 1- to 180-degree circuit pairs of at least two independent isolated circuit systems C2 / C1 (this is the angle or range direction of the physical possibility to be manufactured that can operate dynamically 798-1,798-2,798-3,798-4 may be connected to the conductive region 007, respectively, such that the energy conditioner 6000 is used independently of the others in the form of each other, and are dynamically pressed each other. 002B is connected to 890AA and 890AB and 001A, 001B is connected to 890BA and 890BB, respectively (for example 001A, 001B is connected to 890AA and 890AB and 002A, 002B is connected to 890BA and 890BB, respectively).

In another example, 798-1, 798-2, 798-3, and 798-4 are each conductive region 007 and 890AA, 890AB, and 890BA, respectively, for example, for a single circuit attachment at C1 only, among others. It should be recognized that, in 890BB, access to 001A, 001B can be made.

There are also a number of ways to describe the same type of embodiment. Thus, many approaches or labels are reaching embodiments of the same goal. For example, the embodiment 6000, which may be described in the first combination of the number of the plurality of structures or possible combinations for the general energy control device, is 9:00, 12, 3 o'clock as in the case of the structure 6000. And at least one electrode of 855BA, 855BB, 865BA, and 865BB with an individual expanding 70 "XZ" or 79 "XX" facing in at least one of four possible 90 degree angular directions, such as six o'clock. A first plurality of electrodes with a second plurality of electrodes divided in more directions, in at least two or four directions.

An embodiment 6000 which can then be described, for example, in a second combination of the number of the plurality of structures and possible combinations of the general energy regulator, among others, is considered a 'fixed' pair or at least 90 degrees in the mutual direction. Coincide with a second plurality of electrodes divided into a group of supplemental pairs having an applied direction of propagation energy provided at at least one pair of clock positions 180 degrees apart that are located in a range of directions that are considered not aligned vertically; It can be described as including the electrode of. In this example, the pairs overlap the same axis, such as in a direction crossing each other with respect to the same axis of rotation (eg, across the same rotation axis) in a direction "0 degrees" or 90 degrees away from each other (in the same axial direction). From alignment) or in similar axes or in a rotated position, but are not well aligned with each other. In FIG. 2A, considering a pair such as a clock hand, 9 o'clock + 3 o'clock is set at 12 o'clock + 6 o'clock, which is arranged at "0 degree" (90 degrees in this case).

Thereafter, the embodiment 6000, which can be described, for example, in a third combination of the number of combinations possible for a plurality of structures or a general energy control device among other embodiments, is divided into at least two sets of electrodes. It includes a first plurality of electrodes together with the electrode. The first electrode set also includes a pair of supplemental electrode groups that include supplemental electrodes 845BA, 845BB and supplemental electrodes 865BA, 865BB. The second of the at least two sets of electrodes includes a pair of supplemental electrodes 845BA and 845Bb. As later shown in FIGS. 2A and 2C, the first set of electrodes of the second plurality of electrodes includes the portion of the first circuit of the plurality of possible circuits having a supplemental portion using a general energy regulator, among others. The second set of electrodes of the second plurality of electrodes comprises a portion of the second circuit of the plurality of possible circuits having a supplemental portion using a general energy regulator, among others.

Among other things, the first plurality of electrodes and the second plurality of electrodes generally including the energy regulator 6000 may be classified into a plurality of shielding electrodes and a plurality of shielded electrodes. The first plurality of shielding electrodes designated as 835, 825, 815, 800 / 800-IM, 810, 820, 830, and 840 includes 79G- "X" electrode enlargement direction associated with the 6000 energy regulator and 845BA, 845BB, as described above. Common shielding structure (not numbered) when connected conductively to the identifier in terms of the second plurality of electrodes and positions designated 855BA, 855BB, 865BA, and 865BB and their respective 79 "XZ" or 79 "XX" electrode enlargement directions May be given the name GNDG.

The plurality of GNDG electrodes are usable as shielding electrodes and are conductively connected to each other to function as a single means for shielding at least the second plurality of electrodes. The odd number of shielding electrodes provides a path of least impedance for multiple circuit systems (C2 and C1 in this case) in groups, and a plurality of GNDG electrodes are conductively connected to each other in groups or configurations so that they are externally designated common conduction. Conductively connected to the portion or passageway 007.

Another combination of the number of combinations of the first main plurality of electrodes and the second main plurality of electrodes in the structure 6000 is equally divided as described below only as the current second adjacent plurality of electrodes and the third plurality of electrodes. 835, 825, 815, 800 / 800IM, 810, 820, having a plurality of main electrodes, and serving as a shielding electrode having a respective one of the first plurality of electrodes, generally designated GNDG, as an energy regulator. At least first, second, and third plurality of electrodes disposed within the first plurality of electrodes, designated 830 and 840. This is illustrated by two pairs 845BA of the embodiment 6000 arranged in pairs facing 0 degrees in another, in this case not present at 90 degrees, in a multi-circuit device having a common reference node CRN of FIG. Keystone 8 "XX" / 800-IMC center electrode of the first plurality of electrodes, as shown by the overall electrode 810 GNDG, which becomes the center shielding electrode 810 / 100-IM-C of 845BB and 855BA, 855BB) And a function for operating as a general energy regulator. Therefore, the 8 "XX" / 800-IMC center electrode and the general energy regulator of the first plurality of electrodes can be identified from at least a series of cross sections given to cut the general energy regulator in half.

In the sequence of electrodes of FIGS. 2A and 2B, each electrode of the second and third plurality of electrodes is arranged, shielded, and fitted between at least two electrodes GNDG of the first plurality of electrodes. In addition, the mated electrodes of the second and third plurality of electrodes are arranged such that matching electrode pairs sandwich at least one electrode GNDG of the first plurality of electrodes.

Accordingly, the minimum sequence electrode of the energy regulator 6000 may be the first electrode 845BA of the second plurality of electrode pairs disposed away from the first electrode GNDG and the second electrode GNDG described below. The second electrode 845BB of the second plurality of electrode pairs is spaced apart from the second electrode GNDG and the third electrode GNDG described below. The first electrode 855BA of the third plurality of electrode pairs is disposed apart from the third electrode GNDG and the fourth electrode GNDG described below. The second electrode 855BB of the third plurality of electrode pairs is spaced apart from the fourth electrode GNDG and the fifth electrode GNDG described below. In the minimum sequence, each electrode of the second and third plurality of electrodes is insulated from each other and from the first plurality of electrodes GNDG.

In FIG. 2, similar to FIG. 1, electrode 855BA individually has main-body electrode portion 80 sandwiched by main-body electrode portions 81s of electrodes 800 / 800IM and 810 simultaneously. Thus, it means that the shielded main-body electrode portion 810 is generally of the same size and the same shape (which are in fact physical homologous to each other using standard manufacturing methods and processes, or at least the size and shape associated with another one is the same. Each large portion of the main-body electrode portion 80 receiving two others at the same time, namely the same part of the shielding function associated with the electrode edge 803 of the main-body electrode portion 80 Electrode 855BA has two overlapping and aligned shielding main-body using electrode edge 805 currently commonly connected to all of the first plurality of electrodes, i.e., electrodes 800 / 800-IM and 810 It is held in the area 'DMZ' or portion 806 established by the fitting parameters of the electrode portion 81.

With reference now to FIG. 2B, the energy regulator 6000 is shown assembled, among others. The outer electrode portions 798-1, 798-2, 798-3 and 798-4 and 890AA, 8890AB, 890BB are arranged separately around the conductor body. The common shielding electrode GNDG comprises a plurality of connecting electrode portions or extension portions 79G-1 (shown in FIG. 2A) electrically conductively connected to the plurality of outer electrodes 798-1 to 798-4 in a discrete version of 6000. Include. The non-discrete version cannot have the outer electrode, but continues to be directly connected to the circuit.

In the minimum sequence of electrodes described above, the first electrode 845BA of the second plurality of electrode pairs includes an electrode extension portion 79BA (shown in FIG. 2A) that is conductively connected to the outer electrode 890BA, The second electrode 845BB of the third plurality of electrode pairs includes an electrode extension portion 79BB (shown in FIG. 2A) that is conductively connected to the outer electrode 890BB. The first electrode 855BA of the second plurality of electrode pairs includes an electrode extension portion 79BA (shown in FIG. 2A) that is conductively connected to the outer electrode 890BA, and is formed of the third plurality of electrode pairs. The second electrode 855BB includes an expansion portion 79BB (shown in FIG. 2A) that is conductively connected to the outer electrode 890BB. The outer portion of the extended portion and the matching electrode pair are arranged at an angle of 180 degrees to each other allowing energy cancellation.

In order to increase the available capacitance in one or both of the connected circuits, additional electrode pairs are added to the energy regulator 6000 among others. Referring again to FIG. 2A, additional electrode pairs 865BA and 865BB are added to a stacking sequence that is oriented in direction with the first electrode pair of the second plurality of electrodes. The first additional electrode 865BA of the third plurality of electrode pairs is arranged above the fifth electrode GNDG and below the sixth electrode GNDG. The second additional electrode 865BB of the third plurality of electrode pairs is arranged above the fourth electrode GNDG and below the fifth electrode GNDG. The first additional electrode 865BA is commonly conductively connected to the outer electrode 890BA and electrically connected to the first electrode 845BA of the second plurality of electrodes. The second additional electrode 865BB is commonly conductively connected to the outer electrode 890BB and is conductively connected to the second electrode 845BA of the third plurality of electrodes. The additional electrode pair may be arranged adjacent to the first electrode pair 845BA, 845BB instead of the adjacent second electrode pair 855BA, 855BB. Although not shown, the capacitance available in one or both of the connected circuits can be increased by adding additional electrode pairs and electrodes GNDG.

FIG. 2C is a multicircuit design diagram that is not limited to energy regulators present in multiple circuit devices in the illustrated configuration, but may be expanded to illustrate the various uses of energy regulators present in multiple circuit applications. In a multi-circuit device with a common reference node CRN, the energy regulators (two pairs 845BA, 845BB and 855BA 855BB of embodiment 6000 arranged in pairs facing zero degrees on the other side in this case not present at 90 degrees), A pair of devices that reverses the shielded energy of one circuit C2, which may include the supplemental portion of the overall circuit system, and matches the reverse mirror image of the supplementary electrode group of electrodes 845BA, 845BB as shown in FIG. 2A. 2A with a first means for inclusion and the shielded energy of another circuit C1, which may include supplemental parts of the overall circuit system of C1, and individually shielded elements as members of a pair of devices, as shown in FIG. A pair of devices that match the reverse mirror image of the supplementary electrode group of electrodes 855BA, 855BB (eg, conductively connected to another electrode) A partial circuit of each of C2 and C1 as disclosed by means for shielding at least a plurality of shielding electrodes of the same shape and size, the mirror image being an electrode (e.g., 810 / 800-IM-C of FIG. 2A). 830, 820, 810, 800 and 815 having at least 810, the shielding means (plural shielding electrodes as discussed) also comprising first means for reversing the shielded energy (described above). And second means for inverting the shielded energy (described above) from each other. This is shielded from at least two separate circuits and other circuits by means for shielding the individual circuit parts of C2 and C1 into the circuit parts (as discussed).

The multi-circuit scheme of FIG. 2C is not particularly small but includes the entire body of the multi-circuit device 0000, each of two separated with at least energy sources 001 = S1, 002 = S2 and energy usage rods L2, L1. There are a total of three pairs of embodiments 6000 as shown in FIG. 2A connected to have circuit systems C2 and C1, each of which provides any supplemental portion within the energy regulator 6000, among others. And sandwiched between the members of the plurality of shielding electrodes and electrically conductively separated from each other. Each of the pairs of circuit portions 845BA, 845BB, 855BA, 855BB and 865BA, 865BB, which are each individually located therein, are connected to corresponding first or second electrode connection portions 890BA and 890BB, respectively.

Separate circuit system C1 is the SL-C1 (energy source-to-energy load-to-circuit 1) outer path portion of each supplemental energy path that exists from energy source 001 to energy use rod (L1) and LS-C1 ( Load-to-source-to-circuit 1) Each individual aspect and energy source of L1 and S1 for supplemental electrical operation in connection with the other, respectively, from the energy source 001 to the energizing rod L-1 by the outer path portion In other aspects to the energy use rod side of C1 is arranged, positioned and conductively connected (all not shown) in relation to the other.

Separated circuit system C2 is the SL-C2 (energy source to energy usage rod to circuit 1) outer path portion of each supplemental energy path present from the energy source 002 to the energy usage rod (L1) and LS-C2 ( Rod to Source vs. Circuit 1) Each individual aspect and energy source of L2 and S2 for supplemental electrical operation in connection with the other, respectively, from the energy source 002 to the energizing rod (L-2) by the outer path portion In other aspects to the energy use rod side of C2 is arranged, positioned and conductively connected (all not shown) in relation to the other.

The C1 / C2 isolated circuit system is coupled to the external electrode portions 890AA, 890BA on the SLC " X " shown in FIG. 2C on the first side of the circuit (each circuit side) and each on the second side of the circuit (each circuit side). Coupling to external electrode portions 890AB, 890BB on LSC " X " shown in FIG. 2C, the electrode portions being known in the art for each circuit portion such as, for example, braze material coupling (not shown). It is formed by a simple conductive coupling portion on each circuit side using the ring method and / or material. These physical couplings and methods, designated equally for location, are generally paired for the complementary aspects of each circuit.

Accordingly, C1-890AA and C1890AB and C2-890BA and C2-890BB are shown as respective identifiers indicating that respective conductive coupling connections are formed. For example, C1-890AA is formed for the 890AA external electrode portion that couples to the external energy path S-L-C1. This aspect of the circuit is the path by going from the first side of the S1 energy source to the first side of the L1 energy-using rod as the 'energy-in' path, C1-890AB is coupled to the external energy path LS-C1. 890AB is formed for the outer electrode portion This side of the circuit is the path by progression from the second side of the L1 energy-using rod progression to the second side of the 001 energy source as an energy-returning path.

For circuit 2 or C2 or C "X" systems, the proper designation has the same element but is changed on the identifier replaced by C1 to C "X" or C2 for Figure 2C. C2-890BA is formed for the 890BA outer electrode portion that couples with the external energy path S-L-C2. This aspect of the circuit is the path by progression from the first side of the S2 energy source to the first side of the L2 energy-using rod as an energy-in path. C2-890BB is formed for the 890BB outer electrode portion that couples with the external energy path L-S-C2. This aspect of the circuit is the path by progression from the second side of the L2 energy utilization load progression to the second side of the 002 source as an energy-return path.

For certain exemplary embodiment devices, each circuit system portion of the plurality of circuit system portions may comprise at least two line-to-reference (or ground) conditioning relationships (previously two identical, line-to-line) (conductively isolated or not). The reference (or ground) relationship comprises a number of respective capacitive, inductive or resistive line to reference (or ground) relationships). This at least two, line-to-reference (or ground) conditioning relationship is operable between each of the at least two complementary electrodes and the same shielding electrode, each of which at least two complementary electrodes each sandwich the same electrode between themselves (usually Sandwich a larger electrode, rather than a complementary pair of electrodes). Thus, at least a first reference (or ground) relationship is operable between a first complementary electrode and a first shielding electrode of the at least two complementary electrodes, and at least a second reference (or ground) relationship is among the at least two complementary electrodes. It is operable between a second complementary electrode and the first shielding electrode.

Moreover, for any same general embodiment device having at least two line to reference (or ground) conditioning relationships just described, the same circuit system portion of the multiple circuit system portions is at least (conductively isolated or not) at least. At least one line to line conditioning relationship, including capacitive, inductive or resistive, and a line to line relationship operable between at least two complementary electrodes.

The energy conditioning relationship value of the at least one line to line energy conditioning relationship value (e.g., measured capacitance available to each circuit part of the plurality of circuit parts) is generally the same type of energy conditioning relationship value (e.g., For example, given a value between 1% and 99% for any one line to reference energy conditioning relationship of capacitance) and two line to reference energy conditioning relationship values that can be measured for each relative individual relationship. It is within the range of at least a predetermined percentage of the value.

Thus, with or without a new general embodiment such as 6000, it includes at least two circuit system portions (e.g., at least two sets on the shield of the complementary electrode), and a general embodiment such as 6000 has at least four line-to-base (Or ground) conditioning relationship and at least two line-to-line conditioning relationship. This also includes at least two of the at least four line to reference (or ground) conditioning relationships and at least one of the two line to line conditioning relationships to be isolated and belong to at least the first circuit system and to at least four line to reference (or Ground) allows the remaining two of the conditioning relationship and at least one of the two line-to-line conditioning relationships to belong to the second circuit system.

Finally shown are the external common electrode portions that are electrically conductively coupled (not shown) with the 79G-1, 79G-2, 79G-2, and 79G-4 extension portions (if required), respectively. Designated 835, 825, 815, 800 / 800-IM, 810, 820, 830, commonly coupled to the conductive portion 007 shown in 2B and schematically shown in FIG. And through all of 798-1, 798-2, 798-3, 798-4 through expansion portions 79G-1, 79G-2, 79G-2 and 79G-4, respectively, via a first plurality of electrodes comprising 840; Equally provide both a voltage reference node or a common reference node (CNR) for energy using the paths 845BA, 855BB, 855BA, 855BB and 865BA, 865BB.

These 6000 embodiment shield components are conductively coupled to each other to utilize a common conductive coupling or electrode shield structure (predetermined circuit system, C " X ") formed from a larger conductive portion 007 as previously described. By 'grounding' (which consists of electrodes in the ringed first plurality of electrodes).

Those skilled in the art will also appreciate the two separations of FIG. 2C as described using the multi-circuit apparatus 6000, which is a conductively insulated coupling of all 798-1, 798-2, 798-3, 798-4 having a common reference node. Operable for at least one of a plurality of operations of at least the first two groups of three pairs of complementary electrodes spread to include an integrated circuit system, wherein the CRN comprises at least first means for blocking the shielded energy of one circuit and the other circuit Means for shielding said shielded energy of said first and second means, respectively, wherein said at least two sets of capacitive networks are individually And by C2 and C1, respectively. Thus, each capacitive network is typically each shared circuit system integrated as unit (X2Y-1) and unit (X2Y-2), respectively, as described in FIG. 2A in the same energy regulator as a result of being exclusively shared. It further comprises at least one line to line capacitor and two line to reference lines or 'GnD' capacitors. (The reference line is the common conductive portion 007, GnD or reference potential 007, which is exclusively shared by both C2, C1, as a result of the vitality of the two insulated circuit arrangements and the respective fusion portions, as described.)

Although FIG. 2A illustrates an electrical null arrangement position operable to be at least 90 degrees out of phase in electrical operation between C2 and C1, the electrical null arrangement position is for example one for different inactive or active states between C2 and C1. It is considered to operate during at least one active state with respect to the system.

In this particular configuration, FIG. 2A shows that although C2 and C1 are at the same 90 degree physical angle with respect to the other, such physical 90 degree angle is not a limitation, and any other directional position is such that the partial electrical null arrangement is relative to each other. It is considered to be operable for each h-field flux emission that has a detrimental effect, which is fully considered by the applicant.

By arranging a stack or a plurality of arranged circuits that do not need to be physically oriented at 90 degrees from other circuits and by achieving the same efficiently or by placing the circuits at vertical distance intervals where the partial null effect function is satisfactory. . For example, this can be done by adding additional 801 material layers with or without additional -IMI- "X" shielding electrodes (not shown).

Thus, the null position associated with at least two insulated circuit portion pairs is related to the electrical null relationship and the relative effect or degree of interference between the at least two directional field flux positions of each insulated circuit portion pair contained within the new general energy regulator. Can be anywhere from 1 degree to 90 degrees relative to at least two or three axes positioning from a center point relative to the 8 " XX " /-IMC center shielding electrode to develop a first position and a second position to determine Can be.

Thus, with respect to at least two or three axes from the center point relative to the 8 "XX" /-IMC center shielding electrode, when a conventional energy regulator is activated, a partial or full "null effect" is insulated from each pair. Will occur on an energy field (if any) that interacts with each other along the portion of the circuit system, whereby certain complementary bypass and / or feedthrough electrode paths may be placed at the position of the insertion shielding electrode of a conventional energy regulator. In this regard, one may operate within certain embodiments “electrically intercepting pairs” in complementary bypass and / or feedthrough electrode pairs in a manner that is physically oriented from at least one to 180 degrees from each other. .

These first plurality of electrodes are conductively coupled to each other, and the five members of the first plurality of electrodes are shielded with the same amount of shielding on each large side of the shield or at least two resistant portions of the energy path receiving physical shield. It has been commonly coupled to be a single uniform shielding structure or function generally to provide a sandwiched portion of each shielded electrode.

Thus, circuit systems C1 energy paths 845BA, 865BA are complementary paired to 845BB, 865BB, while circuit system C2 is a plurality of two isolated circuits with complementary electrodes 855AB, 855BB that are electrically nulled to each other at the same time. It works.

By using these seven shield members 830, 820, 810, 800, 815, 825, 835 of the first plurality of electrodes conductively coupled to each other to function as a single caged shield structure or grouped shield, The electrodes use both complementary conductors 845BA, 865BA, 845BB, 865BB, 855AB and 855BB to provide both physical and dynamic shielding (electrostatic shielding) of portions of energy.

In total, Example 6000 will be operable coupled to the C2 and Cl systems to establish or form a fixed complementary physical relationship, which in turn is considered as a proportional corresponding stop direction arrangement relationship between two complementary energy paths. For example, in this relationship the pair to C2 is energy paths 845BA, 865BA and complementarily and correspondingly 845BB, 865BB, while C1 acts as a complementary and correspondingly paired electrode 855AB and 855BB. Since two sets of paired circuit system portions comprise these pairs of electrodes, the set of paired circuit system portions is a grouping that forms an electrically null relationship with each other. All electrodes shown in this case are generally of the same shape and size, and both match or correspond with respect to the other so as to "face-to-face" to match the surface portions that each block with the other. This is not necessary.

This is a balanced, corresponding physical and complementary relationship between the C2 energy paths 845BA and 865BA, respectively, and complementarily pairs to 845BB and 865BB, respectively, while C1 is a balanced, corresponding physical and complementary between the complementary electrodes 855AB and 855BB. It works in a complementary relationship.

While electrically nulling with respect to each other as shown in FIG. 2C, this is not yet possible with respect to circuit C1 or C2 as the set of paired circuit system C1 and C2 energy propagates to two opposite phases at the same time. Allowing them to be independent or dynamic, the energy portions will be null predictable or operable with respect to each other. At the same time, this same portion uses one of each of the two pairs of C2 energy path pairs, while the C1 energy of this system is each pair of C2 energy path pairs with respect to each other in a balanced and complementary dynamic relationship associated with the other at the time of activation. Use

In general, the operation of conventional activated energy regulators utilizes this AOC 813 within a portion of one of the plurality of activated circuit systems to balance and ongoing, durable complementary electrical conditioning operations for this predetermined subsequent energy. Is in dynamic operation to establish and maintain In each circuit system (C1 / C2, etc.), the portion of energy paired with the other can have its proportional resistivity removed efficiently according to the interaction or co-mixing of the two corresponding portions and the next portion of energy in the dynamic. Exclusive h-fields that eliminate each other according to rules formed by the science of Ampere's Law, including lifelong achievements such as Faraday, Maxwell, Tesla, Einstein, and Planck that state that propagation can be sustained Establish radio waves;

The use of an embodiment results in a structurally balanced configuration of generally equivalent capacitance layers (typically equivalent capacitances are not required) located between each of the resistive, paired energy paths in the embodiments in a generally balanced, electrical manner across multiple circuits. Will provide.

The converter is also widely used to provide common mode (CM) isolation and is dependent on differential mode transmission (DM) through the input to magnetically link the primary winding to the secondary winding at implementation to deliver energy. As a result, the CM voltage through the primary winding is rejected. One defect inherent in the manufacture of a transducer is the propagation energy source capacitance between the primary and secondary windings. As the frequency of the circuit increases, the capacitive coupling also increases; Circuit insulation is then configured. If sufficient parasitic capacitance is present, high frequency RF energy (fast transients, ESD, light, etc.) can pass through the transducer and cause confusion in the circuit on the other side of the isolation gap that receives this transient event. Depending on the type and application of the transducer, shielding may be provided between the primary and secondary windings. This shield, coupled to a common energy path reference source, is designed to prevent capacitive coupling between multiple winding sets.

For the deployment of a new exemplary embodiment, a single circuit portion of the complementary circuit portion paired with a large circuit system is used by propagating energy in which this energy emits an energy field. Due to their proximity to various other in-pair physical arrangements, the propagating energy interacts with each other and mirrors within their ratios the complementary symmetric circuit paired with the circuit system path. Therefore, these proportional propagation energies act in mutually opposite ways and thus mutually cancel the field effects due to their mutual adjacency, but undergo opposite propagation operations as described above. Paired groups of complementary symmetric pair electrodes provide an internally balanced opposing resistive load function for a single individual circuit portion of a pair of complementary circuit portions of a large circuit system or by using a typical new energized embodiment. Can be separated. Thus, the exemplary embodiment also fully functions or mimics the functionality of at least one electrostatically shielded transformer per circuit system portion according to the embodiment. Typical embodiments improve and reduce the need for transformers in typical transformer-request circuitry. A typical new embodiment may be used in some applications for its energy-adjusting capability as an alternative to the functionality of at least one electrostatic shielding transformer per paired circuit system portion. The new exemplary embodiment does not use only physical and relative, common electrode shields to suppress parasitics, but functions efficiently like relative positioning of common shields (other pairs of electrodes or circuit pairs / layers) and transformers. To do so, conductive bonds are used in the common conductive region in the combination. If the circuit system is confused by the transient current, the electrostatic shielding transformer function of this typical new embodiment of this type has the effect of suppressing the transient current and at the same time protects it and functions as a combined differential mode and common mode filter. . The shielding electrode structure is generally conductively coupled to one common energy path.

The linear stacked multi-circuit operable energy conditioner comprises an electrode arrangement of at least two multiple electrodes. One of the two plurality of electrode paths includes an electrode that is considered a shielding electrode in the arrangement. The first plurality of electrode paths may be uniform in physical composition, appearance, shape and size with respect to each other. The components of the first plurality of electrode paths in a vertical or straight stack arrangement will be placed or positioned overlapping one another such that the peripheral edges 805 are the same height and aligned with one another. Each energy conditioner multi-circuit arrangement of at least three multi-circuit energy-conditioner arrangements couples to a circuit reference node, CRN during energy and operation, and to an energy potential for grounding of the common shielding electrode structure of any multi-circuit energy-conditioning arrangement. Each single common conductive part will be used as the common.

In some cases, energy-regulated arrangements in stacked multiple circuits include horizontal or co-flat distributed insulation circuit arrangements with respect to one another but not necessarily stacked on top of one another. The operational capability of a particular embodiment in circuit arrangement refers to the regulation of complementary propagation of various energies along pairs of the same size and / or efficient and substantially the same size, among others, and complementary conductors and / or electrodes and / or Or an electrode path counterpart, (all with electrode paths), is mostly the separation of the gaps between the electrodes, depending on whether the separation is air or the material has a predetermined property and / or is a simple medium and / or a material having a predetermined property. Most parts are physically isolated at least by some kind. Next, the regulation of the complementary energy portion propagation is largely separated by mutual overlap and physical large positioning of the common shared multiple energy conductors or electrode paths, and these conductors or electrodes are separated from each other as described above. Conductively coupled but not to complementary electrode path pairs. This structure is grounded, and an energy path structure, a common energy path structure, a common conductive structure or a shielding structure functions as grounding, using complementary conductors among others and complementary conductors of certain embodiments in circuit arrangements. For both sets of energies Faraday cages have energy conditioning capabilities using DC, AC and AC / DC hybrid propagation of energy along energy paths in the energy system and / or test device. This involves the use of specific embodiments in circuit arrangements to regulate energy within a system that includes many different types of energy partial propagation formats in the system, including many kinds of circuit propagation characteristics within the same energy system platform, among others. .

The present invention provides an existing centrally located common energy path electrode as shown to provide discrete and discrete characteristics that can enhance or shape multiple circuit energy-regulation with the number of discrete discrete energy circuits contained therein. 8 " XX " / 8 " XX " -IM-C Consider an additional centrally located common energy path electrode 8 " / 8 " As shown in Figures 3A, 4A and 4C, additionally an external shielding electrode, denoted by -IMO- "X", is located. The internally shielded electrodes (except 8 "XX" / 8 "XX" -IM-C), which are additionally represented by -IMI- "X", are optional; additionally located external and internal shielded electrodes are also connected to each other. Conductively coupled, and any other number of the plurality of shielding electrodes in the final static energy-controlled arrangement and the central shielding electrode designated 8 "XX" / 8 "XX" -IM-C. As mentioned above, most of these relationships are for two-dimensional positioning relationships, only from the two-dimensional perspective shown in FIG. 4C. The material 801 spacing or spacing equivalents (not shown overall) separation distances are indicated as 806, 814,814A, 814B, 814C, and 814D and are always associated with the device. Looking at the cross-section as provided in FIGS. 4C and 10, the observer notes the other important vertical distances and the vertical separation relationship (not shown entirely), which shows the shown preset electrode and energy path stack arrangement (not shown overall). to be. As shown in Figure 4C, when only one additional common shielding electrode 800-1 is inserted adjacent to the 800 / 800-IM common electrode path, the balance of shielding electrode structure polarization is shifted and the induction of polarity unbalance is common. For each circuit that is electrically opposite to each other with respect to the shielding electrode path. However, if two additional shielding electrodes 800-1 and 800-2 are positioned to sandwich the common shielding electrode 800 / 800-IM so that they form a three-layer stack of 800 "X" shielding electrodes, The balance of shield electrode structure polarization for circuit operation is maintained internally for additional common electrode shield paths for each pair of separate circuit portions that are electrically opposite each other relative to the common shield electrode within 9210. By using the various distance and separation relationships designed, 806, 814, 814A, 814B, 814C, and 814D (not shown in their entirety) are closely spaced as previously described as previously described for common shielding stacking arrangements as they will be used. You can use various effects for extra spacing relationships.

At least even or a pair of -IMIs that will switch the common center shield electrode labeled 800 / 800-IM-C as shown in FIGS. 4A, 4B and 4C, except for 8 " XX " / 800-IM. There are " X " and, in use, a plurality of shielding electrodes are conductively coupled, including a common center electrode labeled 800 / 800-IM-C in any final static energy-controlled arrangement. Any position located as a central group or center of shielded electrodes located in the overall energy-controlled arrangement, with or without the additionally positioned internally placed common shielding electrode labeled (# -IMI- "X") in place The number of shielding electrodes will be at least one odd number of shielding electrodes. Conversely, the total number of electrodes of the first plurality of electrodes or the plurality of shielding electrodes as the total number found in the total energy-controlled arrangement is generally an odd integer and is at least three. The additionally located outer shielding electrode, denoted IMO- "X", generally increases the shielding effect of the overall disposed energy-regulating arrangement. These electrodes assist in providing additional shielding effects from both the outside and inside of the original EMI for energy-controlled deployments, and -IM adjacent to shielding complementary electrodes (except 8 "XX" / 800-IM) It facilitates the shielding electrode which is not marked with "X"-"X". In addition, the center shielding electrode 800 / 800- denoted as the center electrode of any of a plurality of total placement electrodes comprising an energy-controlled arrangement and the total number of center electrodes comprising any of a plurality of first or shielding electrodes. Except for IM-C, the remaining electrode, known as the remaining electrode of the first plurality of electrodes or the remaining electrode of the plurality of shielding electrodes, is equally and evenly divided into the opposite side of the center shielding electrode 8 "XX" / 800-IM. appear. Thus, the two symmetric groups of the remaining electrodes of the plurality of shielding electrodes (meaning to exclude the shared center shielding electrode 800 / 800-IM-C) will generally be even in total, and the center shielding electrode 8 "XX" Taken with / 800-IM and when summed results in the total odd integer number of electrodes comprising a plurality of shielding electrodes that act as a physical shielding structure when conductively coupled to a single and shared image "0" voltage reference potential with respect to each other .

For example, at least the minimum odd number functioning as a shielding electrode required for deployment using typically co-flat or stacked / linear / co-flat hybrid embodiments, such as FIGS. 3A, 4A and 7A, among others. Three electrodes are required.

For several embodiments, among others, such as a typical straight-line separated circuit design, such as FIGS. 2A and 8A, at least the minimum number of odd electrodes or five electrodes is required to function as the shielding electrode.

At least static or dynamic shielding for at least two sets of paired conductive and energy path portions or energy portions propagating along the electrode main body portion 80, all sandwiched and shielded in the means for shielding, both sets of minimum odd integers It is performed as an electrostatic shielding structure or means for shielding which provides both functional and physical shielding functions.

The electrostatic or dynamic shielding function component of an odd integer number of electrode sets for any stack design allows the energy-adjusted arrangement to be energized and the odd number of connected electrodes conductive to a potential of one of the individual sources, although a plurality of connected electrodes of the odd number are not essential or essential. Occurs when coupled to an energy-using load circuit system that includes a separate circuit system energy-in or energy-out path. The physical shielding functional component of a set of odd integer electrodes for any stack design occurs or is energized for a typical energy-controlled arrangement.

Referring to FIG. 3A, another exemplary embodiment of a multi-circuit energy-regulating component 8000 is shown in an enlarged view. In this embodiment, multiple co-planar electrodes are located on material layer 801. In a minimum configuration, component 8000 includes at least a first paired conductive means for the propagation energy portion of the primary circuit, a second paired conductive means for the propagation energy portion of the at least secondary circuit, and a propagation of the at least tertiary circuit. A third paired conductive means and shielding means for the energy portion. The shielding means shields the first, second, and third paired conductive means for the propagation energy portion, respectively, and against each other.

The first paired conductive means for at least the propagation energy portion of the primary circuit is provided by electrodes 845FA and 845FB of the first paired complementarity set. A second paired conductive means for at least the propagation energy portion of the secondary circuit is provided by electrodes of the second paired complementarity set 845BA, 845BB. A third paired conductive means for at least the propagation energy portion of the tertiary circuit is provided by electrodes of the third paired complementarity set 845CFA, 845CFB.

Each of the first, second, and third paired conductive means for the propagation energy portion and the means for shielding them against each other are provided by a plurality of electrodes, generally referred to as GNDD. In particular, one pair of electrodes of each pair of complementary GNDD electrodes 820, 810, 800 of the plurality of electrodes may be provided with shielding means located at a predetermined position, each of which is located on the material layer 801. Include. Half of the paired electrodes of each pair 846FA, 845BA, and 845CFA are separated from each other and placed co-flat on the material layer 801 denoted 845PA. The second electrode and corresponding paired electrodes 845FB, 845BB, and 845CFB are separated and co-planar with respect to one another on another material layer 801 denoted as 845PB and within the same position on the second material layer 801. Located.

The first plurality of co-flat complementary electrodes 845FA, 845BA, 845CFA and the second plurality of co-flat complementary electrodes 845FB, 845BB, 845CFB are dispersed in the plurality of electrodes GNDD. The plurality of GNDD electrodes operate as shielding electrodes, and they provide a common shielding structure or means for providing the shielding described above, such that the plurality of GNDD electrodes provide a minimum of circuit energy for at least one and / or at least secondary circuit system. Conductively coupled to each other external electrode portions 798-1, 798-2, 798-3, 798-4 (not entirely shown, see FIG. 3B) to operate to provide a common path of impedance.

Therefore, the minimum electrode arrangement for a three-circuit system arrangement may include a plurality of electrodes GNDD (mutually conductively coupled) and a first plurality of co-planar complementary electrodes spaced apart from one another and electrically insulated from each other. . The second plurality of co-flat complementary electrodes are spaced apart from each other and electrically insulated from each other. It is also directed to both sides, for example as a member of the first and second plurality of co-planar complementary electrodes, the electrode pairs 845FA and 845FB, 845BA and 845BB, 845CFA and 845CFA respectively associated with the remaining electrodes. Allowing the positions to correspond to each other and still maintaining the position of the arrangement such that the electrode pairs 845FA and 845FB, 845BA and 845BB, 845CFA and 845CFA are shielded from each other as electrode pairs (not coplanar).

The 845FA and 845FB, and 845CFA and 845CFA electrodes are shown as feedthru electrodes and the complementary electrode pairs 845BA and 845BB are shown as bypass electrodes. The coplanar electrodes can be configured as a combination of bypass or feedthrough and are not limited to the configuration shown.

In another variation, electrodes GNDI are disposed in a coplanar relationship between the coplanar electrodes, providing additional shielding and separation, and the GND "X" electrodes are all coupled to the previously mentioned common conducting portion or path. Improve the common path of the lowest impedance for each coupled circuit system. Electrodes GNDD are conductively coupled to the outer electrode portions 798-1-4, described below, and when using an optional GNDI electrode, the outer electrode portions 798-1-6 are connected to all the plurality of electrodes. It is used to shield the conductive coupling to each other. Conversely, each electrode pair 845FA and 845FB, 845BA and 845BB, 845CFA and 845CFA are each conductively separated from each other and from the electrodes of the plurality of GND "X" electrodes.

At least, a three-circuit configuration has been described above, but additional electrode pairs and coplanar electrode layering may be added to adjust the coupling of additional circuit systems. Referring to FIG. 3A, electrode pairs 845CFA and 845CFB are feedthrough variations referred to as crossover feedthrough electrodes. Although not shown, additional coplanar electrode pairs may be added. Additional capacitance can also be added to component 8000 by adding coplanar layers of additional GND " X " electrodes and corresponding electrode pairs 835FA and 835FB, 835BA and 835BB, 835CFA and 835CFB, respectively, above and / or below the existing layer. Can be added to.

3B, a multi-circuit, energy regulating arrangement 8000 is shown assembled. The outer electrode portions are disposed around the conditioner body. The common shielding electrodes GNDD and GNDI include a plurality of extension portions 79G-1-6 (shown in FIG. 3A) conductively coupled to the plurality of external electrode portions 798-1-6.

Electrodes 845FA and 835FA that are still members of other electrode pairs and overlap each other include two extension portions 79 "XZ" or 79 "XX", each on opposite ends (always numbered in FIG. 3A). (Not shown) is conductively coupled to the external electrodes 891FA and 891FB, respectively. The electrodes 845FB and 835FB, which are still members of other electrode pairs and overlap each other, comprise two extension portions 79F "X", each on opposite ends (not always numbered in Figure 3A). Is conductively coupled to the external electrodes 890FA and 890FB.

The electrodes 845BA and 835BA, which are still members of other electrode pairs and overlap each other, comprise one extension portion 79B "X", each on the end (not always shown numbered in FIG. 3A) externally. Conductively coupled to the electrodes 890BB, respectively. Electrodes 845BB and 835BB that are still members of other electrode pairs and overlap each other include one extension portion 79B "X", each on the end (not always numbered in FIG. 3A) externally Conductively coupled to the electrode 890BA, respectively.

The electrodes 845CFA and 835CFA that are still members of other electrode pairs and overlap each other include two extension portions 79CF "X", each on opposite ends (not always numbered in Figure 3A). Silver is conductively coupled to the external electrodes 891CFA and 891FB, respectively. Electrodes 845CFB and 835CFB that are still members of other electrode pairs and overlap each other include two extension portions 79CF "X", each on opposite ends (not always numbered in Figure 3A). Is conductively coupled to the external electrodes 890CFA and 890CFB. The extension portions and the outer electrodes of the corresponding electrode pairs are disposed approximately 180 degrees from each other and allow for optimal energy cancellation.

The previous embodiment provides a typical multilayer energy conditioner or energy conditioning configuration that provides multi-circuit coupling capability by adding electrodes arranged in stacking 6000 and by adding coplanar electrodes with coplanar stacking 8000. To start. A variation of these embodiments is a typical hybrid energy conditioning configuration 10000, which provides multi-circuit coupling for at least three circuits as shown in FIGS. 4A and 4B. (Among other things, such multi-circuit embodiments may also be coupled to fewer circuit systems in a pre-set manner.)

Referring to FIG. 4A, a typical energy conditioning configuration 10000 is shown in an exploded top view, showing each electrode layering formed or disposed on a layer of material 801 as described above. The conditioner 10000 includes a first complementary means for adjusting the first circuit, a second complementary means for adjusting the second circuit, a third complementary means for adjusting the third circuit and a first for individual adjustment. Means for shielding the second, second, and third complementary means from each other.

First complementary means for adjusting the circuit are provided by a plurality of first complementary bielectrodes 845BA1 and 845BB1. Second complementary means for adjusting the second circuit is provided by a plurality of second complementary bielectrodes 845BA2 and 845BB2. Third complementary means for adjusting the third circuit is provided by a plurality of third complementary bielectrodes 855BA and 855BB. Such means for shielding the first, second, and third complementary means for individual adjustment from each other are provided by a plurality of fourth electrodes, generally referred to as GNDG, as in FIG. 2A.

An electrode of one of each pair of first and second complementary dipoles is disposed at a predetermined location on a first layer of material 801. Corresponding second electrodes of each pair of first and second complementary dipoles are disposed at the same location, but with respect to first electrodes of each pair of first and second complementary bipoles Is oriented opposite on the second layer. The plurality of first complementary bielectrodes 845BA1 and 845BB1, the plurality of second complementary bielectrodes 845BA2 and 845BB2, and the plurality of third complementary bielectrodes are interspersed in the plurality of fourth electrodes GNDG. The plurality of fourth electrodes GNDG provide the common shielding structure described above, with the result that the plurality of fourth electrodes GNDG can act as shielding electrodes and are conductively coupled to each other and as described with reference to the GNDD electrode of FIG. 3A. Provide a path for impedance.

The first electrode 845BA1 of the plurality of first electrodes and the first electrode 845BA2 of the plurality of second electrodes are coplanar with each other, and are disposed above the first electrode GNDG and below the second electrode GNDG. The second electrode 845BB1 of the plurality of first electrodes and the second electrode 845BB2 of the plurality of second electrodes are coplanar with each other, and are disposed above the second electrode GNDG and below the third electrode GNDG. The first electrode 855BA of the plurality of third electrodes is disposed above the third electrode GNDG and below the fourth electrode GNDG. The second electrode 855BB of the plurality of third electrodes is oriented oppositely toward the first electrode 855BA, arranged above the fourth electrode GNDG and below the fifth electrode GNDG. In this minimal sequence, each of the plurality of first, second and third electrodes is conductively separated from each other and from the plurality of fourth electrodes GNDG.

Referring to Figure 4B, the 'hybrid' energy conditioning configuration 10000 is shown assembled as a separate component.The outer electrode portion is disposed around the conditioner body. -1, 79G-2, 79G-3 and 79G-4 (shown in FIG. 4A), wherein the plurality of extending portions comprise a plurality of external electrodes 798-1, 798-2, 798-3 and 798 Conductively coupled to -4) A first electrode 845BA1 of the plurality of first electrodes includes an extended portion 79BBA1 (shown in FIG. 4A) conductively coupled to the external electrode 890BB, The second electrode 845BB1 of the first electrodes includes an extending portion 79BBB1 (shown in Fig. 4A) conductively coupled to the external electrode 890BA. Includes an extension portion 79BBA2 (shown in FIG. 4A) conductively coupled to the external electrode 891BB, and includes a plurality of second electrodes The second electrode 845BB2 includes an extension portion 79BB2 (shown in Fig. 4A) conductively coupled to the external electrode 891BA. An extension portion 79BA (shown in FIG. 4A) conductively coupled to 893BB, and a second electrode 855BB of the plurality of third electrodes is conductively coupled to the external electrode 893BA. (Shown in Fig. 4A) The outer electrode of the coupling electrode portion or the extending portions and the corresponding electrode pair is disposed 180 degrees from each other and allows energy cancellation. On the other hand, each circuit pair portion in which each corresponding electrode pair is set is included in various directing relationships, for example, a plurality of first and second electrode pairs constituting the first circuit pair portion and the second circuit pair portion, respectively. Is also electrically Side by side in a (null) relationship, they are physically parallel to each other. This can also be referred to as an electrically parallel null relationship. In another embodiment, the plurality of third electrodes is also a third circuit pair portion, wherein the third circuit pair is oriented physically at 90 degrees with respect to the first and second circuit pair portions, respectively. Thus, the first and second circuit pair portions are also electrically nulled relative to the second electrode pair portion respectively when subjected to energy.

While the illustrated electrode pairs are configured for bypass, this or any other embodiment among others may include any combination of bypass, feedthrough, and / or crossover feedthrough electrode pairs, If necessary, the arrangement and number of external electrodes can be easily finely adjusted. The outer electrode of the combined electrode portion or the extended portion and the corresponding electrode pair is disposed 180 degrees from each other and allows energy cancellation.

Although not shown, the capacitance available for one, two, or almost all combined circuit portions and each circuit system (not shown), with or without FIGS. 2A, 3A, and 4A or the remaining figures shown, may be In an embodiment it may be further increased by further adding additional electrode pairs and electrodes GNDG. The increased distance of separation between 845BA and 865BA and 845BB and 865BB increases the capacitance given by C2 as opposed to decreasing the capacitance given by C1.

5A-5D, 6A-6B, 7A-7B, and 8A-8B, various embodiments are shown. These embodiments are shown as specific forms of embodiments or in more detail as annular embodiments. Although the energy path or various electrodes are formed, among other things, the dynamic energy conditioning function naturally works the same as the previously disclosed embodiments depending on its configuration. They are each operable for propagation energy (not shown) using energy conditioning components, in that they each include both various energy paths or electrodes as partly relative groupings, and in conjunction with previous embodiments disclosed herein. It is similar to the embodiment disclosed above in that it forms parts of a circuit system pairing.

Shaped embodiments, such as annular ones, among others, may be used in different applications, such as motors, for example, or where specific forms of energy conditioning configurations are possible combinations of these individual or non-individual versions of the components. It can be used for anything that can add flexibility to access.

5A and 5B, the planar and annular electrode layer 855BA is shown in FIG. 5B, and the annular main body portion 80 of the conductive material 799 disposed on the annular material portion 801. Has Similarly, referring to FIG. 5B, the planar and formed electrode layer 855BB is shown in FIG. 5B and has a main body portion 80 formed of conductive material 799 disposed on the forming material portion 801.

In these parts of the typical shaped embodiment among others, the material 801 having an annular shape is also larger than the formed main body portion 80 of the conductive material 799 for each electrode 855BA and 855BB. . The outer peripheral circumferential edge 817-O of the material 801 is larger than the outer peripheral circumferential edge 803-O of the electrode body portion 799 for the electrodes 855BA and 855BB, respectively, and the electrode body portion 799. Formed by extending an outer insulating portion 814-O, the portion where no electrode material 799 is present, along at least one predetermined portion position adjacent and parallel to the outer peripheral circumferential edge 803-O of do. The inner peripheral circumferential edge 817-I of the material 801 is smaller than the inner peripheral circumferential circumferential edge 803-I of the energy path or electrode body portion 799, and is parallel to and adjacent to the illustrated hole 000, And forming an inner insulating portion 814-I extending in parallel adjacent to the inner peripheral circumferential edge 803-I of the energy path or electrode body portion 799.

The formed energy path or electrode of these embodiments also extends outwardly with respect to the hole 000 for the electrode 855BB and at least one energy path extension extending inward with respect to the hole 000 with respect to the electrode 855BA. A portion (or simply an 'extension portion'), wherein the extension portion may extend from the electrode main body 80 portion, both externally and internally, in other configurations, respectively.

As shown in FIG. 5A, four energy paths or extension portions 79-I1, 79-I2, 79-I3, 79-I4 define the inner peripheral circumferential edge 803-I of the energy path material portion 799. Gina extends inwardly with respect to the hole 000 to the inner peripheral circumferential edge 817-I of the shaped material 801 through the inner insulating portion 814-I. Conversely, as shown in FIG. 5B, the extended portions 79-I1, 79-I2, 79-I3, 79-I4 are externally insulated past the outer peripheral circumferential edge 803-O of the electrode body portion 799. It extends outward with respect to the hole 000 to the outer peripheral circumferential edge 817-O of the shaped material 801 through the portion 814-O.

Alternative versions of the plurality of planar coplanar energy paths are electrodes that are separated from at least one other corresponding layer and made coplanar or coplanar layers, as shown in FIGS. 6A and 6B, respectively. 6A and 6B, only the 801 material layer is annular or only the 801 portion has a hole therein. In particular, in the layer of this embodiment, the co-planar energy paths or co-planar electrodes are shaped into a number of main-body portions 80. Like the published constant energy hardness or electrodes, the shaped portions can be a bypass or feedthrough electrode application having a bypass shaped section and a feedthru shaped section, the application being the same 801 material They can be mixed or separated in the same plane in the hierarchy.

With reference to FIG. 6A, a plurality of bypass, shaped electrode portions 855AB1, 855AB2 are separated and located in opposite directions with respect to each other, disposed in shaped material 801 and as shown below. Are in the same size and shape relationship. The bypass shaped partial electrode 855AB1 has an energy path or extension portion 79-OB1, which portion is the hole from the outer peripheral range edge 803-O of the electrode body portion 799 of 855AB1. (000) outward or through the outer insulation portion 814-O to the outer peripheral edge 817-O of the shaped material 801.

Referring to FIG. 6A, the bypass shaped partial electrode 855AB2 has an air path or extension portion 79-IB1, which portion is the outer periphery range edge of the electrode body portion 799 of 855AB2. 803-O) extends inwardly into the hole (000) or through the outer insulating portion 814-1 to the outer peripheral edge 817-1 of the shaped material 801.

Referring again to FIG. 6A, a plurality of bypass, shaped electrode portions 855AB1, 855AB2 are separated and located in opposite directions relative to each other, and the shaped, bypass, energy paths or electrodes Disposed between material 801 between 855AB1 and 855AB2 and in the same size and shape relationship as shown below.

Each feedthrough electrode 855ACF1, 855ACF2 has a first energy path or a first extension portion 790CF1, 790CF2, each extending outwardly and outwardly with respect to the hole 000, and with respect to the second energypath. One energy path or first expansion portion 791CF1, 791CF2 extends inwardly into the hole 000.

Referring to FIG. 6B, compared to FIG. 6A, the same coplanar electrode layer 855AB1 is shown repeatedly except that it has been rotated 180 degrees, and the feedthrough electrodes 855ACF1 and 855ACF2 have been flipped, 855BCF2 and 855BCF2 Each of the two layers are arranged in an array with each other, and the shaped energy path or electrode portion directly above or below will complement each other for the other.

Referring to Figures 7A and 7B, there is shown one abstract embodiment 1000 for an energy conditioning component that uses all of the bypass electrode sections identical to the bypass sections of Figures 6A-6B. An example is typically a typical minimum-layered sequence for connecting a plurality of separate circuits.

Complementary pairs of coplanar bypass main body electrode sections 80 on an arranged layer are shown arranged in a number of larger, shaped electrodes 800, 810, 815. Each shaped supporting main body electrode 81 of the electrodes 800, 810, 815 is formed of a larger electrode on the material 801 portions 800P, 810P, 815P. Each coplanar electrode layer comprises four equally sized main body electrode portions 80s, each having at least one extension portion 79- "X".

Each co-planar electrode layer is disposed between at least two shaped main body electrode portions 81s of the plurality of protective electrodes comprising at least electrodes 800.810, 815. Among the plurality of protective electrodes, each protective electrode has a plurality of extension portions 79- "X" proximate the main body 81, each extending inward and outward from the hole (000). The shaped layer of 801 material layer 9008 is disposed as the last layer after the shaped protective electrode 810, as shown.

The shaped energy paths or electrodes 855BA1, 855BA2, 855BA3, 855BA4 of the first coplanar layer are complementary to their corresponding counterparts, but in the opposite direction of the second coplanar layer, the shaped energy paths or electrodes ( 855BB1, 855BB2, 855BB3, and 855BB4 are the stacking sequences, respectively, at the time of manufacture. This occurs when taking into account the shape given by the 79 " X " extension that is proximate to the added area. When a corresponding pair occurs in the stacking sequence during fabrication without taking into account the 79 " X " extension in close proximity, the electrodes from each corresponding pair of corresponding shaped energy paths or shaped energy paths or electrodes Each is overlaid with a corresponding edge 803. Thus, the only 79 " X " extension that is in close proximity does not receive the protection of the various protective electrodes which are clearly disclosed below.

Referring to Figures 7B, 5A and 5B, one abstract embodiment 1000 is shown for an energy conditioning component that may use the layers of Figures 6A-6B or 7A, which is typically It is a typical minimum-layered sequence for connecting multiple discrete circuits.

Energy conditioning component 1200 is shown using the minimum layered sequence of FIG. 7A. Each of the shaped electrodes 855BA1, 855BA2, 855BA3, 855BA4 of the coplanar layer and each of the shaped partial electrodes 855BB1, 855BB2, 855BB3, 855BB4 of the second coplanar layer each have its outer electrodes 890A-890A. Has at least one extension connected to). On the other hand, the inner extension portion is each connected to its respective inner electrode 890B-894B in the minimum layered sequence of FIG. 7A.

In each outer family, an extended portion is conductively connected to an outer electrode portion disposed along the outer periphery region edge 817-0, and in each of the inner portions, the extended portion is shown in the illustrated energy regulation component ( It is conductively connected to the inner electrode portion disposed along the inner peripheral region edge 817-1 of 1200. The shaped electrodes 800, 810, 815 having respective electrode extension portions 79 "X" are connected to respective outer electrode portions 798-I (s) and 798-O (s).

Another type of typical annular embodiment of the energy conditioning component of FIG. 8A is the energy conditioning component 1100, among others shown in a minimal layered sequence connecting at least one or more separate circuit systems.

In one embodiment, among others, many of the exemplary embodiments are stacked multiple electrodes that are conductively connected to each other (thus not all electrodes are arranged but they are of the same size and shape for protection). It is published as an energy regulator that consists of: Multiple electrodes, all of the same size and shape, will include at least first and second electrode pairs, each of which is conductively separated from each other. The electrodes of the first electrode pair are each conductively separated and in opposite directions to each other. This also applies to the electrodes of the second electrode pair. It should be noted that any one of the stacked plurality of electrodes is larger than any one of the second plurality of electrodes. In particular, the first and second electrode pairs are arranged protected against each other. They are directed in pairs from crossed positions with respect to each other. While the need for intersecting positions for others helps to form an active null relative relationship during separate situations for other reasons, joint active operation is present in the AOC 813 of a typical embodiment. The energy regulator or the arrangement of the electrodes of the energy regulator includes a substance having the predetermined characteristics described above in handling, as described above, at least by a plurality of material portions or substances each having certain characteristics. The plurality of stacked electrodes and the plurality of electrodes are each because they are spatially separated from each other.

In FIG. 8, the first plurality of paired and annular electrodes 855BA, 855BB and the second plurality of paired and annular electrodes 865BA, 865BB form a third plurality of annular electrodes ( 800, 810, 815, 820, 825, which are the respective shaped electrodes of the third annular electrodes. 800, 810, 815, 820, 825 are formed on a material 801 of the same size and shape, designated 800P, 810P, 815P, 820P, 825P, respectively. Each shaped electrode 800, 810, 815, 820, 825 has a plurality of expansion portions 79G-I "X" and 79G-O "X", the expansion being inward and outward and the hole (000) Extends outward from

In a feedthrough / bypass structure, each of the mated annular electrodes 855BA, 855BB and 865BA, 866BB has at least one extension portion designated 79 " X ". The annular electrodes 855BA, 865BA have at least two extension portions 79-11, 79-12, which extend inwardly outward with respect to the hole 000, and have annular electrodes ( 855BB and 865BB have at least two expansion portions 79-01 and 79-02, which extend outwardly with respect to the hole 000.

The electrode extension portions of each electrode are connected to respective outer electrode portions 890A-894A, and for each of the inner extension portions of each electrode, each inner portion in a minimum layered sequence as shown in FIGS. 7A and 7B. Connected to electrode portions 890B-894B.

Although not shown, the connecting electrode portion or the expanded portion of the mated electrodes can be offset relative to each other at a predetermined relative angle, for example 90 degrees, but the cancellation effects of the noise energy are at opposite angles of 180 degrees. Is maximized.

The various groups of the plurality of electrodes are arranged in any method or sequence that allows for separate connection to at least one separate circuit system. Each of the shaped electrodes among the first and second plurality of annular electrodes is superimposed and protected between at least two annular electrodes of the third plurality of electrodes. Thus, the electrode 855BA shaped out of the first annular electrodes is arranged overlapping and protected between the annular electrodes 825, 815, and the electrode shaped out of the first plurality of annular electrodes. 855BB is superimposed and protected between the annular electrodes 815, 800. The electrodes 865BA, which are shaped among the first annular electrodes, are arranged overlapping and are protected between the annular electrodes 800, 810, and the electrodes 865BB that are shaped among the first plurality of annular electrodes. Are superimposed and protected between the annular electrodes 810, 820. A shaped layer of material 008 is disposed after the last shaped electrode 820, as shown in the exemplary embodiment above.

The stacking sequence, shown in FIG. 8A, is a minimal sequence of fabrication stacking for an energy conditioning component that can be connected to at least one or more separate circuit systems. To increase the capacitance, each additional electrode is placed between two of the third plurality of electrodes providing protection for the electrode pair as well as the path of the minimum impedance for the filtered energy as described above. During deployment, one additional electrode pair may be added among the first and / or second plurality of electrodes.

Referring to FIG. 8B, the energy regulation component 1201 is shown using the minimum layered sequence of FIG. 8A. Each extension portion is connected to an outer electrode disposed along the outer diameter corner and an inner diameter corner of the energy control component 1201. The third plurality of annular electrodes 800, 810, 815, 820, 825 are conductive to the outer electrode portions 798-1, 798-0 as they are conductively connected to each other. It is connected. Conversely, the paired annular electrodes 855BA, 855BB and 865BA, 865BB are conductively separated from and with respect to the third annular plurality of electrodes 800, 810, 815, 820, 825, respectively. It is.

In an alternative embodiment of the invention, the annular electrodes operate with conductive, non-conductive bias or insulated conductive bias, designated 500-1, 500-2, 500-3 and 500-4. It may further comprise a plurality of holes.

The third plurality of electrodes 800, 810, 815, 820, 825 may each be a portion or region that prevents a conductive connection to the aperture of the electrode, as shown or not shown. 1) is shown to be conductively separated from the conduction bias 500-1-4. In a typical embodiment, one of the plurality of biases or holes is conductively connected to one annular electrode of the first or second plurality of electrodes, but certain residual multiple biases may be equal to the application needs. Insulated or conductively connected from the electrode. Thus, each is at least conductively coupled with at least one complementary annular electrode in a minimal configuration, but not conductively coupled with the shield electrode. However, it is contemplated and contemplated that there exists a configuration in which this is achieved.

In this embodiment, the electrode extending portions of the first and second plurality of electrodes are optional because the circuit coupling is through vias. Such a bias may be comprised of a solid conductive material or a conductive aperture, or may be insulated and non-insulated holes that allow the conductor to be conductively coupled or insulated through the various electrodes as desired.

Accordingly, the new embodiments disclosed simultaneously include low and high voltage circuit applications by using a balanced shield electrode structure that incorporates paired, and smaller size (compared to common shield path electrodes) complementary path electrodes. Suitable for electrical systems In addition, the novel feedthru embodiments disclosed among others can be combined with and suitable for multiple electrical systems including a variety of low and high current circuit applications. Various heterogeneous combinations of a pair of complementary feed-through energy paths, both of equal or mixed equivalent size and pair of equivalent size bypass and electrically opposite, various energies in which the pair of operations are aligned or coplanar or described The partial propagation modes are used to combine stack and coplanar mixing and matched complementary circuit paths.

9, various types of external conductive coupling portions for shielded energy paths and / or complementary energy paths may be used together or as a combination of embodiments. Such outer conductive coupling portion arrangements may include conductive coupling of various outer differential paths to the outer coupling electrode portions, such as 498-SF1 (T / B), 498-SF2 (T / B), 490A and 491A. Can be. For example, 400, 401, 402, and 403 propagation among the various respective energy portions are presented along external paths (not shown) and enter a typical embodiment such as 9200 of FIG. One possible attachment scheme in 498-SF1 (T / B) (straight feedthrough energy propagation) is the upper (relative to the position of the drawing) and the lower (drawing position) of the conductive coupling portion of each 498-SF1 (T / B). Allow an external differential energy path (not shown) at the end. In this conductive coupling type, the propagation energy portions continue out of the 797SF1B into the 797SF1A, and they experience energy-regulation as part of the internal complementarity paths through the embodiment, among others, and then the bottom shown in the lower part of FIG. Continue to 498-SF1B (relative to the drawing position) and the outlet start is coupled along the start of the portion of the external differential energy path (not shown). Various such coupling and energy partial propagation schemes allow portions of an external differential energy path (not shown) that normally terminate at the entry of an embodiment, while others are now external or adjacent below 9200 and also conductive at 498-SF1T. Coupling points between 498-SF1T and 498-SF1B are internally transferred through 9200 to allow portions of propagation circuit energy to be transferred outside of the typical embodiment, and in others (not shown) internally using embodiment 9200. Maintain a feedthrough path. Of course, this propagation scenario also applies to the 498-SF2 (T / B) coupling side.

10 shows electrically opposite complementary electrode pairs 497SF2 and 497SF1. Each complementary electrode 497SF2 and 497SF1 comprises' split'-electrodes 497SF2B and 497SF2A, 497SF1A and 497SF1B, respectively, forming straight feedthrough complementary electrodes including portions of a typical embodiment such as 9200, among others of FIG. The respective 'split'-complementary electrodes of 497SF2 and 497SF1 are located in close proximity so that the' split'-complementary electrodes 497SF2B and 497SF2A, 497SF1A and 497SF1B operate as one single capacitor plate 497SF2 and 497SF1 when they are electrically constrained. do.

497SF2B and 497SF2A, 497SF1A and 497SF1B comprise two very adjacent and parallel pairs of thin energy path electrode parent 497SF2 and 497SF1 element units. These dual plate elements 497SF2B and 497SF2A, 497SF1A and 497SF1B respectively define two complementary energy path electrode matrix 497SF2 and 497SF1 electrode elements, which are a pair of electrically opposed pairs with cooperatively increased total electrode skin surface portions. And this skin surface portion responds to a corresponding increase in current handling capacity of powered circuit 1A without significantly increasing the total volume size of the entire multi-circuit energy-regulating structure 9200.

A typical embodiment such as 9200 allows the use of such 'split'-complementary electrode pairs, and the 497SF2B and 497SF2A, 497SF1A and 497SF1B are located at portions 814B spaced apart by one micron with respect to each other to direct these energy paths. Each group of 'split'-electrodes presented in circuit 1A (not shown) allows a portion of the propagation energies carried along to utilize the closely arranged split pairs 497SF2B and 497SF2A, 497SF1A and 497SF1B. To be an electrode, which can be done without the need to construct additional common shielding electrodes. The advantage of using a pair of 'split'-electrodes is that the additional part obtained by using an additional electrode equals the current handling capability of the two electrically opposed, complementary energy paths 497SF2 and 497SF1 electrode elements without this feature. Size, a significant increase over the current carrying capacity of a pair of groups with electrically opposite energy paths.

Although the 'split' electrode structure can double the current transfer capability compared to approximately one single pair energy path grouping, this electrode characteristic can be implemented by any voltage driving function of the embodiment between other embodiments such as 9200 and 9210. Various 499 electrode material elements further utilizing the advantages of the examples, increasing the embodiment through increased reduction in size between different circuit voltage distribution structures and the total current handling capability of the other embodiments and including the various 499 electrode material elements of the embodiments. It maintains an energy-controlled environment with relatively less strain on the fields.

49SF " X " used to designate electrode extension portions of the portions that propagate energy along internally located electrodes arriving from an external conductive coupling structure (not fully shown) coupled by standard industrial means and methodology. Allow flow. In order to simplify and further refine the elements presented, among other things shown in FIG. 10, the embodiments are used for certain energized circuits, but at the same time also used for the functionality for circuits using high voltage energy paths. The ability to provide the multi-circuit, high-low voltage processing capability provided within a circuit energy regulation embodiment is now disclosed and the regulation function within the same multi-layer embodiment is now disclosed.

Thus, some of the embodiments include a pair, and smaller size (relative to common shield path electrodes), as well as a pair of bypass configurations and a pair of feedthrough configurations as shown in FIG. The use of a balanced shielded electrode structure incorporating the conductive and electrically opposite electrodes of C is suitable for a set of simultaneous electrical system part pairs including low and high voltage circuit applications that provide excellent reliability.

Among other things, the new exemplary embodiment has the same or less volume size compared to the non-split use structure and includes the same size non-split use which includes a larger number of the same size split equivalent feedthrough conductive complementary electrodes. 'Split'-electrodes located close to each other in such a way that each set of split compensation electrode planes of electrode materials is shown as consisting of a finished 9200 with more energy processing capacity and more efficient than that found in the device Configure the feedthrough version.

The difference is that the new embodiments use more energy transfer or energy partial transfer capability, among other things, multi-circuit energy for multiple energy paths simultaneously using less deposition, less occupancy, and more circuit conductive coupling. It addresses the need for regulation but allows for significant deployment only within this new embodiment.

Thus, 497SF1 and 497SF2 are defined as at least two single equally-sized, same-shape complementary position energy paths separated by at least a larger common energy shielding electrode, the shielding electrodes being located in an inverted position inserted relative to one another. In a typical embodiment such as 9200, it is shared by 497SF1 and 497SF2 for the energy-regulation and voltage reference for circuit 2A (not shown) reference function (larger shield electrode).

Referring again to FIG. 10, another exemplary hierarchical electrode / 801 material stacking is presented as energy-regulating component 9200. Each of the outer coupling electrodes 498-SF2B, 498-1, 498-SF1A, 491A, 498-SF1B, 498-2, 498-SF2A, 490A, designated by respective outer conductive coupling structures, encloses 9200 individual bodies. The multi-circuit energy regulation component 9200 includes two external common connection electrodes 498-1 AND 498-2 for common coupling to an external common energy path or common energy portion (not fully shown). External differential with straight feedthrough external coupling symmetric complementary electrodes 498-SF1A + 498-SF1B and a first external differential energy path (not shown) and a second external differential energy path (not shown) of the first circuit path Symmetric complementary electrodes 498-SF2A + 498-SF2B for path conductive coupling. Finally, the bypass external coupling electrodes 490A and 491A are for differential conductive coupling to the third and fourth external differential energy paths (not shown) of the second circuit path.

Along these electrode paths and in the direction to the portion of the energy propagation in the first or second discrete circuit generated when the symmetric complementary electrodes 497SF1, 497SF2, 455BT.465BT are energized among the various containers. In terms of internal complementary electrodes (497SF1,497SF2,455BT.465BT) providing energy-regulation, it is designated 800 " X " and disposed within the overlapping field energy and the overlapping physical 900 " X " cage-like shield structure. Will now be described.

In a powered configuration for the 9200, the symmetric complementary electrodes 455BT and 465BT where a portion of the energies taking entries in the 9200's 813 AOC take a momentary path of zero impedance path or are sealed almost exactly the same. ) And 9200 with a set of symmetric complementary electrodes (498-SF2A + 498-SF2B) in the symmetric complementary electrodes (498-SF1A + 498-SF1B) and the shielding electrode containers (800C, 800D, 800E, 800F). An interconnected, shared, and joined shield electrode structure 900B + 900A + 900C is found that includes a portion of the shield electrode container that forms a bonded shield electrode structure 900B + 900A + 900C, which is shown in FIG. It forms one shield structure found.

Thus, a general embodiment such as 9200 is operable for dynamic convergence of opposite phase energy (not shown) within AOC 813 which interacts with each other in a harmonious and complementary manner, while at the same time the same dynamic convergence of opposite phase energies. This dynamically developing, zero-impedance state can be generated, developed, and used to allow portions of energies to pass outside the 813 AOC impact along the external common energy path 6803. A portion of the material 499G or the various shielded common electrodes 800 / 800-IM-C, 810F and 820F, which are located along the conductive surfaces formed by the internal common electrode material 499G and 499G, are "fully presented" And other conductively coupled “8X” shield electrodes are directly applied when used at the same time by C1, C2, etc. via respective opposite pair symmetric complementary electrodes such as 465-BT, 455BT, 497SF1 and 497SF2. And indirectly assisted, 465-BT, 455BT, 497SF1 and 497SF2 are also available in a non-conductively coupled manner, as are the same external common energy path 6803 for energy propagation and circuit voltage references. .

At the same time, the larger 810F common shield electrode, which allows the energy transfer along this portion of conventional embodiment 9200 to move into the common energy path 6803, common to both 455BT and 465BT compensation electrodes, Note that 455BT and 465BT use 810F simultaneously, as they are positioned in an inverted mirror fashion between the compensation bypass electrodes, which is opposite to. Both the 455BT and 465BT compensating electrodes are electrically connected to other operating circuits using opposing pairs of identically sized electrodes 467SF1 and 497SF2, which also simultaneously use the very same common energy path 6803 for energy partial transfer for other partial energies. Note that it doesn't necessarily work in series.

The transfer of the energy portion follows the very same internally shared common energy path / inner electrode shields 820F, 810F, constituting 900B, 900C, and 900A, respectively, along the 497SF1, 497SF2 equally sized energy paths of the operable second circuit system. 800, 810B, 820B). Any portion of energy utilizing the common energy path is via the common energy path or via shield electrode extension 49 " X " (not fully shown) and conductive coupling means 6805 (described in detail below). To exit the external common energy path 6803.

As noted above, the various circuit usage transfers and adjustments obtained by the portion of the transfer energy that is inherently external from the 9200 are, in most cases, the same sized energy circuit paths built up inside and the various externally located energy paths simultaneously after energization. Occurs along electrode pairs (individually the electrode pairs are sized and shaped relative to one another in the same size and shape), moving along a number of directions arranged in some coplanar embodiments and most intermediate points These portions of the delivered energy may be subjected to various energy control actions described in some way.

This energy transfer occurs simultaneously, while the other energy portions are internally shared and internally coupled, cooperating, common energy path / internal electrode shields 820F, 810F, 800 / 800-IM-C, 810B, 820B. It will be delivered to an internally shared, cooperative common energy path / inner electrode shield having an electrically shielded Faraday cage-like shield structure 900B and 900A, as well as additional optional 850F. And each of the / 850-IM and 850B / 850-IM image / shield electrodes, most of which are electrically conductively distinct from those of the two sets of electrically opposite, external energy circuit paths. Some portion of the energy using a common energy path (not shown) may include shield electrode extensions 49 "X '(not shown) and external conductive coupling means (e.g.) onto the common energy path or an external common energy path 6803. 6805) (hereinafter described in detail).

Insulating material 801 may be used to separate conductive attachment means and / or methods used as a common coupling to a common energy path or an external common energy path 6803, so that each separate operation in combination with 9200 The compensating electrode path transfer energy portion of a possible circuit 1A and 2A (not shown, respectively) is in physical contact with any of the other external energy paths of a nearby separate circuit or with the external common energy path 6803 itself. To prevent electrical contact or short circuit.

As shown in FIG. 10, the solder indicated at 6805 or a conductive material operable for coupling only, or a physical coupling method such as a resistive fit or spring tension, or the like may also have the same portion or the same external energy path 6803. It provides a means for conductively coupling to, thereby facilitating ultimate development of common energy path conductive coupling and shared voltage reference point or phase (not shown) after voltage application.

Energy path electrode shield structure (all not shown) with internally shared, internally coupled, cooperating, common energy path / internal shield electrodes 820F, 810F, 800 / 800-IM-C, 810B, 810B ), As well as the larger conductive Faraday cage shaped shield structures 900B, 900C and 900A, as well as additional optional 850F / 850-IM and 850B-850-IM image / shield electrodes, respectively, (Not fully shown) internally zero volts or unbiased (each circuit simultaneously) for each set of electrically opposed compensation energy paths electrically located on opposite sides of the energized energy path electrode shield structure Allow the same voltage).

The ability of each half of each circuit 1A and 2A (not shown) to use and share a circuit voltage reference (not shown) arranged in a self-contained form is inverse mirror Internally shared, mutually shared, common energy path including internally coupled, concurrently acting common energy path / internal electrode shield 820F, 810F, 800 / 800-IM-C, 810B, 820B. Split electrodes located within 9200 as well as electrode material components 455BT, 465BT and split electrodes 497SF1 to be electrically positioned simultaneously (for each respective pair of compensation element sets) across a portion of the inner electrode shield Providing desired energy regulation features to each half of the electrically opposite compensating energy path junction, each of which divides the embedded circuit voltage (not shown) between the 497SF2, and the electrode shield is shaped as a conductive Faraday cage Shield structure (900B, 900C and 900A) as well as additional optional 850F / 850 physically providing opposing sides of the internally connected inner shield electrode structure for use with respective compensation electrodes including electrically opposite compensation energy path junctions. Configure the IM and 850B / 850-IM phase / shield electrodes, respectively.

AOC 813 is shown in FIGS. 10 and 9, where the location points that make up part of the manual regulation network have been developed within the 9200 embodiment given the voltages shown in FIGS. 10 and 9, as well as the voltage separation network portion. It was developed within the integrated form 9210 with this voltage. Typically, 9200 and the like, which are conductively coupled to at least two separate energy circuit paths (not fully shown), each coupling circuit depending on its own individual energy source and its own individual energy utilization load for energy partial delivery. By using the same embodiment, the relative parallel positioning of each circuit unit provided by each single compensation circuit path including a compensation path with electrically opposite phases results in only the electrode material component in which the user is statistically located. Rather, circuit elements that effectively develop RFI storage, EMI energy minimization, parasitic energy suppression, as well as many active energy transfers that result in mutual cancellation of mutual inductances established along adjacent prepositioned electrically opposed energy paths. The simultaneous interaction of various circuit energies of this In the presence of the common shield electrode structure so as to obtain the opportunity to do is to operate in the essentially electrically shield the protection and zero cross convergence (nullconvergence).

10 and 9, the energy exit points for the escape of the externally generated energy portion for the compensated bypass path (not fully shown) shown and positioned to the right and left, including 491A and 490A, are approximately equal to each other. While positioned at 180 degrees, the 498-SF1A, 498-SF1B and 498-SF2A and 498-SF2B and 498-SF2B electrode energy exit / entry points for the exemplary embodiment 9200 and the like are positioned 180 degrees relative to one another and 498-SF1A The + B and 498-SF2A + B outer electrodes are between two 498- "X" common energy exit points of the common energy path 6803 (not fully shown) of the internal common shield structure (not fully shown). Also in parallel with each other, this arrangement of energy exit points 498- "X" is an electrically opposite compensation energy in an external pair conductively coupled to the 498-SF1A + B and 498-SF2A + B external electrodes. circa Bypass connection electrode 490A with respect to each other conductively coupled to a separate externally paired electrically opposed compensation energy path circuit 1A (not shown) rather than furnace circuit 2A (not shown) And 90 degrees, or perpendicular, from the physical 180 degrees discrete separation positions of 491A).

The cross-section provided in FIG. 10 will indicate other significant distances and separation relationships, indicated as 806, 814, 814A, 814B, 814C, and 814D, as intended for the illustrated vertical electrode and energy path stack arrangement. The various energy path location directions of the paired discrete circuits of opposing compensation pairs of energy paths 498-SF1 and 498-SF2 and 465BT and 455BT are, for example, 498-SF1A + B with respect to each other. And 498-SF2A + B, but also at the same time typically collide with each other due to a 90 degree orientation for the energy partial transfer relationship, but not in this case, but not in all cases, for example physical orientation bias. 180 present along a paired pair of electrically opposite compensation electrode paths (498-SF1A + B and 498-SF2A + B) used to take advantage of the null effect induced on possible H field energy that may not It should also be noted that it uses degree orientation.

Most separation intervals of the elements in the device are related to the various electrode path structures embedded in the device, and are not necessary for many multi-circuit energy regulation applications, but to maintain balance control within certain system circuits. Note that these material distance relationships should be within the embodiment spacing considerations and distributions.

Large deviations or inconsistencies with the volume or spacing of these pairs of materials have been tested with any anomalies that are possible but not optimal, which are disadvantageous for circuit balance for most common electrical applications of the embodiments.

Separation interval 814 has common shields 810B and 820B, as shown in FIG. 10, respectively, and these structures implement an energy partial transfer that can be established within this specified location in the state of being energized in one example. An energy portion transfer which comprises a compensating energy path 497SF2, comprising adjacent or bordering portions along the electrode material surface or " skin " of the electrode material, and which can be established within this specified position in the energized state for another example. Common shield electrode comprising an arrangement of single or split compensation electrodes, such as 800F with compensation energy path 465BT, including adjacent or bounding portions along the electrode material surface or " skin " Appropriate pre-determined three-dimensional gaps or gaps measured between energy passage containers 800C, 800D, 800E, and 800F, respectively. Requires partial or separate application.

The separation gap 814A is generally a shield on the common electrode path 850B / 850B-M, including for example a thin material 801 or an equivalent gap (not fully shown) or other type of spacer (not shown) and It is part of a spacing or three-dimensional separation gap established between a plurality of adjacent common electrode material paths, such as common electrode path 820B.

The separation gap 814C is a separation made between the common electrode path 820B and the compensation electrode path such as the compensation electrode path 465BT. Separation distance 814B is a vertical separation between split compensation energy paths, such as split compensation energy paths 497F1A and 497SF1B.

These unique combinations of dynamic and static forces (not shown) occur simultaneously within the containment of the shield electrode structure due to its use as a conduit to a common energy path separate from the compensation path. Thus, not only dynamic energy relationships occur within the conducting circuit paths, but also new usefulness or multi-circuit energy regulation by utilizing and combining various laws of physical element spacing and energy field separation between energy paths, materials 801, and non-conductive materials. Ability is provided.

Separate and electrically opposed, complementary electrodes 497SF1 and 497SF2 comprise a pair of pairs and comprise portions of similarly sized conductive material used as paired and opposite complementary electrodes. These two similarly sized conductive materials or electrode portions are two parallel pairs of thinly spaced pairs of thin electrode elements 497SF1A, 497SF1B and 497SF12A, 497SF12B, and four spaced apart in parallel by a thin layer of casing material 801, respectively. Grouping the distinct electrode elements. In particular, each conductive 497SF1 and 497SF2 electrode material or energy path comprises tightly spaced thin conductive plate elements 497SF1A, 497SF1B and 497SF2A, 497SF2B pairs, which is the total of the paired and electrically opposed 497SF1 and 497SF2 complementary energy paths. Effectively doubles the conductive surface portion. Similarly, it should be noted that in each common, the shield electrodes do not include corresponding tightly spaced thin common pairs. Since the shield electrode element uses this configuration, no common shield electrode structure element is required for these shield electrodes to double the total electrode surface portion, and the common shield electrode structure element is an energy main input or output as in the prior art. It includes a wide and common common shield electrode structure architecture consisting of hierarchically stacked processes that do not regulate the energy partial transfer path function. Rather, the common shield electrode structure element is used in a representative implementation such as 9200 or the like, or in an implementation such as 9210 or the like, and in most cases, an additional energy transfer path that is not an external energy path (not shown).

The spacing between electrode element pairs 497SF1A, 497SF1B and 497SF2A, 497SF2B should preferably be minimized to less than 1.0 millimeters or until the spacing is allowed, mostly due to the electrode material energy steering characteristics that are recognized for the existing manufacturing tolerances and desired effects While distances 814C and 814 can be seen inserted and of the same size, the common energy path electrodes 810B, 497SF2A + 497SF2B, for example 820, are substantially greater than the spacing of 814C.

Each pair and the 'separate'-electrode paths are very similar in conductive part size, but the same is desirable for a pair of separations. Thus, the open plate is designed with 497SF2B and 497SF2A, 497SF1A and 497SF1B, each of which is simply a mirror image of another opposite electrode material. However, electrically paired electrode pairs of the same size, 497SF2, and 497SF1 include 497SF2B and 497SF2A, 497SF1A, and 497SF1B, and with respect to their position within a representative embodiment such as 9200, each of which is a mirror image opposite to each other as a whole. Can be considered as.

In practical implementations, such as 9200, the fabrication sequence for making one particular energy path structure will be outlined and described as discrete changes in FIG. Initially, deposition or placement of material 801 is made, followed by layering of electrode material 499G for forming 850B / 850B-M, followed by a thin layering of material 801 or 801X ( 814A, or a gap is made, and the location of electrode material 499G layering for the formation of the common shield electrode path is deposited. After this layering is made, layering of the material 801 is made to establish the spacing 814C, layering of the electrode material 499G to form the energy path 497SF2A, and then material 801 or 814B thin layering or spacing of 801X is made, layering of electrode material 499G for formation of energy path 497SF2B is made, application 814C of material 801 is located, and common shield electrode path ( The layering position of the electrode material 499G for the formation of 810B is made, followed by the layering 814C of the material 801, and the layering of the electrode material 499 for the formation of the energy path 497SF1A. Next, a thin layering 814B or spacing of material 801 or 801X is made, followed by another layering of electrode material 499 for formation of energy path 497SF1B, and layering of material 801 (814C) And layering of electrode material 499G for the formation of a shared common shield electrode path 800 / 800-IM-C, and a center shield electrode structure balance point, material 801 of a representative embodiment such as 9200, etc. Layering 814C, layering of electrode material 499 capable of forming bypass electrode path 455BT, followed by deposition 814C of material 801, and common energy shield electrode path 810F. Layering of the electrode material 499G for the formation of the < RTI ID = 0.0 >), < / RTI > layering 814C of the material 801, and layering of the electrode material 499 allowing formation of the bypass electrode path 465BT. ; Layering 814C of material 801 is made, followed by a common energy shield electrode path 820F, followed by a very thin layering 814A of material 801, and common energy shield electrode path 850B. Layering of electrode material 499G for the formation of 850 / IM), and finally the deposition or placement of material 801 is made to include some major foundation layering and physically stacks the 9200 configuration. Support.

Referring to FIG. 11, the configuration architecture previously shown in FIG. 10 has been modified and the first pair of bypass electrodes 455BT and 465BT have been replaced with separate-feed through electrode paths 497F4A and 497F4B, 497F3A and 497F3B while 497F1A and 497F1B And the bottom portion of the 9200 (relative to the position of the figure), including 497F2A and 497F2B 'separation'-electrode feed-through electrode paths, are capable of conductively coupling two separate and externally electrically complementary complementary energy path circuits. Maintains an energy-controlling circuit configuration, such as 9210, which may be used. The conductive coupling is shown in FIG. 12 including two separate energy paths, which are shown at the top (relative to the position of the figure) of the completed energy-regulating circuit configuration 9210.

In FIG. 12, a PCB layer 6806 has an external opposite energy path or trace (not shown) for combining various energy utilization loads and sources of energy as shown in FIG. 11. It is shown as a complete energy-regulating configuration 9210 mounted over (represented by a wide outer circle). Externally coupled electrodes 498-1, 498-F1A, 498F2A, 498-2, 498-F4A, 498-F3B, 498-3, 498-F1B, 498-F2B, 498-4, 498-F4B, and 498-F3A Each is designed with an outer coupling structure surrounding the body 9210. Beneath layer 6806, the second conductive portion or layer of the PCB, separated by an insulator or material 801 (not shown), or common energy path 6803 (represented by a wide square in circle 6806) is an insulator. Or a common energy path and circuit voltage image reference node, CRN (not shown), separated from layer 6806 by material 801 (not fully shown). Energy-regulating configurations, such as 9210, have four outer bond bands or electrodes, respectively, which couple the outer common energy path or portion 6803 by conductive coupling means (not shown) by conductive openings or filled vias 6804. 1, 498-2, 498-3, 498-4. Conductive openings or filled vias 6804 are insulated from layer 6804B by insulator portion 6804B. The transfer of energy through energy-regulating structures such as 9210 will now be described.

Referring to a first circuit coupled with an energy-regulating structure such as 9210, the energy transfer portion is crossed from energy source-1 toward feedthrough outer coupling electrode 498-F1A along an energy path (not shown fully). And an energy flow arrow along the separate-feedthrough electrode path 497F1A-B toward the externally coupled electrode on the opposite side of the configuration 9210 and along the external energy path (not fully shown) towards the energy utilization rod-1.

The energy portion is then configured via AOC along the separate-feedthrough electrode paths 497F2A and 497F2B, from the energy utilization rod-1 along the energy path (not shown fully), to the outer coupling electrode 498-F2A. Toward the outer coupling electrode 498-F2B on the opposite side of the () and behind the external energy path (not fully shown) towards energy source-1.

With reference to the first circuit in combination with an energy-regulating structure such as 9210, the energy transfer portion is cross-separated from energy source-2 to external coupling electrode 498-F3A along an energy path (not shown fully). Along the feed-through electrode path 497F3A-B toward the outer coupling electrode 498-F3B on the opposite side of the configuration 9210, and as an energy flow arrow toward the energy utilization rod-2 along the external energy path (not fully shown) .

The energy portion is then configured via AOC along the separate-feedthrough electrode paths 497F4A and 497F4B, from the energy utilization rod-2 along the energy path (not fully shown), to the outer coupling electrode 498-F4A. ) Toward the outer coupling electrode 498-F4B on the opposite side of the panel and toward the energy source-2 along the back of the external energy path (not fully shown).

Although the above-mentioned technique is a general description of the majority of the energy portion flowing through an energy-regulating structure such as 9210, the regulating function of the structure will be described soon. Thus, the energy transfer portions flowing along the separate-feedthrough electrode paths 497F1A, 497F1B and 497F1A, 497F1B are internally shared and simultaneously operate a common energy path / internal electrode shield 820F, 810F, 800 / 800-IM- C, 810B, 820B, respectively, are electrostatically shielded and physically shielded from internal and external influences, which are more compact, conductively coupled, with each additional and optional 850F / 850-IM and Produces 850B / 850-IM image / shield electrodes as well as prison-like electrostatic shielding or prison-like shield structures (900B, 900C and 900A).

At the same time, the portion of energy delivered along the separate-feedthrough electrode paths 497F1A, 497F1B, and 497F1A, 497F1B has magnetic or "H" -field radiation in the direction of transfer that follows the Enfer right hand law. This magnetic field or " H " field is the opposite magnetic or " H " formed by the energy transfer portion in the opposite general direction along the respective pair of separate-feedthrough electrode paths 497F1A, 497F1B, and 497F1A, 497F1B. Is partially offset by the field.

The separate-feedthrough electrode paths 497F4A, 497F4B, and 497F3A, 497F3B have a 90 degree angular direction relative to the delivered energy parts obtained through the separate-feedthrough electrode paths 497F1A, 497F1B, and 497F2A, 497F2B. It is formed to be. Separation-feedthrough electrode paths such as paired 497F4A + 497F4B and 497F3A + 497F3B and remaining separation-feedthrough electrode paths (497F1A + 497F1B and 497F2A + 497F2B), respectively, have separate 90 ° orientation Minimal impact on each H field energy transfer portion to each other, and constructively or destructively, to negate or zero any potential effect on each C1 and / or C2 and the like.

The other energy portions are delivered to a common energy path / inner electrode shield 820F, 810F, 800 / 800-IM-C, 810B, 820B, which are internally shared, mutually coupled, and operating simultaneously, each of which further and Creates conductive, prison-like electrostatic shielding or prison-like shield structures (900B, 900C, and 900A) as well as optional 850F / 850-IM and 850B / 850-IM image / shield electrodes, intensively common conductive openings or filled vias Conductively couples with an external common energy path (6804). The multi-point coupling commonality of these grouped shield electrode paths provides an improvement on the use of the reference voltage node and on the improvement of the low impedance path with respect to any other possible path of high impedance operable in conduction. The low impedance energy path common to the parts of a multi-circuit system provides control over circuits (1 / 1A) and other parts of energy using overvoltage and surge protection (not shown) of circuits (2 / 2A). It helps to provide. The energy-regulation between each pair of electrically opposite electrode positions is not only balanced in each of them within the AOC, but also in relation to the reference voltage node where each circuit (1 / 1A) and circuit (2 / 2A) is used. Note that it is balanced.

Thus, variations and standards of embodiments similarly constructed or manufactured by almost all embodiments and standard means are used, and dielectric differences as only significant modifications between multiple, paired line circuit locations and only equally formed embodiments. An exception is, among other things, for calculating an implementation in an insertion loss performance measurement scheme. This represents a circuit using a novel common conductive shield structure and an external conductive attachment element that will operate in common using electronic capacitive shield suppression and physical shields, among other things being implemented within one of a number of circuit system parts that are particularly feasible. The impact on the regulation of energy represents a representative new implementation.

Various embodiments The user of the device can use any type of industry standard connection to conduct conductive coupling of all common energy paths to common energy paths and other energy paths that are normally separated from paired complementary circuit paths of the same size. . The conductive coupling of the common electrode uses electrical positioning and described principles for opposing sides of the "0" voltage reference generated on opposite sides of the electrode structure arranged in a single sandwich, such as voltage and signal separation, filtering and voltage balancing. Have the simultaneous ability to perform multiple and individual energy conditioning functions.

Although the conductive energy paths are symmetrically balanced and described as shown in FIGS. 3A and 4A, the common energy path coupled to the intrinsic center common energy path and denoted by (# -IM) improves shielding effectiveness in various ways. Note that it increases. These paths are additional common energy paths disposed externally, and sandwiches between internally disposed paths have a broader purpose than the purpose of adding capacitance to a typical embodiment.

The sandwich function of an equally sized energy path in pairs between groups of paired conductive shielded containers 800X is a common conductive part and a shielding energy path and / or externally coupled to simultaneously generate voltage image reference correction (IM) It is more efficient when propagating the energy portion compared to the common conductive portion. If the shielding conductive container structure constructed in one embodiment is in equilibrium, any additional single common conductive shield path layer added by mistake can potentially save money in the manufacturing process without disturbing or attenuating energy conditioning operations, The automated layer process can add additional outer layers or layers as described. Intentional or accidental minimal errors have a minor effect on the overall performance for a number of applications, which have been fully recognized by the applicant as described.

Within any fine variation of the exemplary embodiment, at least three individually different energy conditioning functions will occur while shielding of complementary energy paths within the footprint of the region or portion that inserts the shielding energy paths is maintained and included within AOC 813. .

Phenomena such as cages or electrostatic shielding suppress the charge contaminants of the internally generated energy parasitics shielded from the complementary energy path main body portion 80s. Electrostatic shielding provides a protective film in the complementary conductive energy path to prevent the release of internally generated energy parasitics. The electrostatic shielding function minimizes the parasitic of the energy imparted to the complementary energy path provided with energy by full physical shielding sealing or total restraint of the main body electrode portion 81s of the sandwich shielding energy path or the insertion complementary circuit portion in the partial footprint. .

The insertion portion of the conductive and non-conductive material portion is used as a conductive material for the electrode, which is a shielding function or shielding electrode, which is used in spite of finely separating the counter-phase electric complementary operation included in the common energy path in a controlled manner. Including but not limited to the above shielding. Optimal operation occurs when a bond to the pain-conducting portion is made, so that the energy portions using the same magnitude and electrically opposed energy paths are in parallel electrical equilibrium between the opposing sides of the common conductive shield structure. Can be operatively crossed.

The special mutual energy flux removal of the various energy portions propagating along the paired and electrically opposed conductive energy paths is an electrically opposite complementary operation using simultaneous stray parasitic suppression and suppression, which acts as a series enhancement function in a typical new embodiment. Spaced apart from each other by one or both of direct separation or indirect separation. The H-field flux propagates by the right hand law (ampere law) along the transmission path, trace, line or conductor or conductive layer portion. In order for the energy input path and the energy return path to be close to each other, the minimum separation by the shielding energy path corresponding to the complementary energy field part and the at least two material parts 801 will be combined for mutual elimination or minimization of individual phenomena. . Mutual deletion is effective so that mutual symmetry paths are close.

In most embodiments where multiple paths are shown, both the common energy path electrode and the same sized differently charged bypass and / or feedthrough conductive energy path electrode are energized positioning between the circuit energy source and the circuit energy utilization load. It can be multiplied in some way to create multiple conductive energy path element bonds in a physical parallel relationship that is considered parallel to the same element as well as parallel to the same element. This structure will add to produce an increased capacitor value.

A common "0" voltage or simple common voltage reference is generated for complementary circuit systems that share a common shielding energy path or electrode when not connected to a common shielding energy path or common conductive portion other than the electrode. Additional shielding energy paths (almost but not all) surrounding the combination of shared centered shielding energy can be used to provide caged or caged electrostatic shielding functionality and increased inherent ground along the increased surge dissipation area or portion. have. A plurality of isolation circuit portions collectively share a shared counter electrode shield grouping that is conductively coupled to the same common energy path to share and provide a common voltage and / or circuit voltage reference between at least two isolation sources and at least two two loads. It will be appreciated by those skilled in the art that it can be used as. Additional shielding common conductors may be used in one of a number of embodiments to provide an increased common path low impedance state for multiple circuits fully recognized by the applicant.

It is particularly noted that retained electrostatic shielding is an energy providing shielding function when a typical embodiment provides energy for a period of time. Thus, some new exemplary embodiments and / or new exemplary embodiment circuit structures can be used for sustained electrostatic shielding of energy propagation.

Thus, a typical new embodiment, individual or non-individual, uses a common conductive shield structure and an external conductive attachment element, and can also be modified from embodiments in non-individual integrated circuit dies, such as fabricated non-capacitor applications or in nanoscale energy conditioning structures. A separate dielectric is used primarily for any electrical conditioning function or result, including any individual capacitive or inductive structure or any stratified application employing electrodes capable of incorporating. In addition, almost any shape, thickness and / or size may vary depending on the electrical application. Typical embodiments may be integrated into integrated circuit microprocessor circuits or chip wafers. The integrated circuit is integrated with a passive conditioner that has been pre-made and etched in the die area so that the new structure can be easily integrated with the available technology.

The shape, thickness or size may vary depending on the electrical application derived from the common conductive shielding electrode and the accessory structure to form at least two conductive containers that produce at least one large single conductive and homogeneous Faraday caged shield structure. As is apparent from a number of embodiments, the Faraday caged shield structure is uniformly and heterogeneously mixed in individual or non-individual modes of operation in at least one energy providing circuit, but paired with electrodes or pairs of equal size. Contains part of the energy path.

As can be seen from the foregoing detailed description, the energy conditioning structure of the present invention achieves various objects as described above. While the energy conditioning structure of the present invention has been described, it is understood that other modifications and variations can be made by those skilled in the art without departing from the scope and spirit of the energy conditioning structure of the present invention.

Those skilled in the art should understand that various features of the elements of the various embodiments may be exchanged in whole and / or in part and that the foregoing detailed description is described by way of example only and limited by the energy conditioning structures described in the appended claims.

Claims (35)

As an energy conditioner, A plurality of overlapping first electrodes conductively connected to each other; And A plurality of second electrodes having at least one first and second electrode pair insulated from each other and having the same size and shape, The first electrode pairs are respectively insulated from each other and disposed to face each other, The second electrode pairs are respectively insulated from each other and disposed to face each other, At least one of the plurality of overlapping electrodes is larger than any one of the plurality of second electrodes, And the first and second electrode pairs are each oriented and intersected with respect to each other and arranged to shield. The method of claim 1, The energy conditioner further comprises a material having a predetermined characteristic, wherein the plurality of overlapping first electrodes and the plurality of second electrodes are connected to each other by at least one material having the predetermined characteristic. As an energy conditioner, A plurality of electrodes conductively connected to each other; A plurality of first electrodes shielded and present on the same plane; And A plurality of second electrodes that are shielded and present on the same plane; And the plurality of first and second electrodes on the same plane are insulated from each other. The method of claim 3, And the plurality of first and second electrodes on the same plane are shielded from each other. The method of claim 4, wherein It further comprises a plurality of material portion, Wherein each electrode of the energy conditioner is spaced apart from another electrode of the energy conditioner by at least one material portion of the plurality of material portions. The method of claim 4, wherein It further comprises a plurality of material portion, Each electrode of the energy conditioner is sandwiched by at least two material portions of the plurality of material portions, respectively. As an energy conditioner, A second electrode sandwiched and shielded by at least the first and third electrodes, a fourth electrode sandwiched and shielded by the third and fifth electrodes, a sixth sandwiched and shielded by the fifth and seventh electrodes A plurality of electrodes having an electrode and an eighth electrode sandwiched and shielded by the seventh and ninth electrodes, The second, fourth, sixth and eighth electrodes are each substantially the same size and smaller than the first, third, fifth, seventh or ninth electrode, The second, fourth, sixth and eighth electrodes are arranged to be insulated from each other, The first, third, fifth, seventh and ninth electrodes are conductively connected to and overlapped with each other to shield the second, fourth, sixth and eighth electrodes, At least the second and fourth electrodes are arranged and oriented in such a manner as to sandwich the fifth electrode to a position opposite to each other. The method of claim 7, wherein At least the first, third, fifth and ninth electrodes are shield electrodes. The method of claim 7, wherein At least the first, third, fifth, seventh and ninth electrodes are shield electrodes and at least the second, fourth, sixth and eighth electrodes are shielded electrodes. The method of claim 8, And the number of shield electrodes is odd, and the number of electrodes of the plurality of electrodes is odd. The method of claim 8, And the second and fourth electrodes are positioned in an orientation in a range that is at least not perpendicular to the position orientation of the sixth and eighth electrodes. The method of claim 7, wherein Wherein each electrode of the plurality of electrodes has at least an extension. The method of claim 9, Wherein each shielded electrode of the plurality of electrodes has at least a first extension, and each shielding electrode of the plurality of electrodes has at least a first and a second extension. The method of claim 16, More ingredients, One of the plurality of electrodes is spaced apart from the other of the plurality of electrodes by at least the material. The method of claim 16, It further comprises a plurality of material portion, Wherein each electrode of the plurality of electrodes is sandwiched by at least two material portions of the plurality of material portions, and each material portion of the plurality of material portions has at least one predetermined electrical characteristic. The method of claim 16, And said fifth electrode is a center electrode of said plurality of electrodes. As an energy conditioner, A plurality of overlapping electrodes comprising at least first, second, third, fourth and fifth electrodes conductively connected to each other; And At least two pairs of complementary electrodes comprising at least first and second complementary electrode pairs, The at least two pairs of complementary electrodes have the same size and shape and are insulated from each other with the plurality of overlapping electrodes, Each electrode of the plurality of overlapping electrodes is larger than any of the two pairs of complementary electrodes, The first complementary electrode of the first complementary electrode pair is sandwiched and shielded by the first and second electrodes, and the second complementary electrode of the first complementary electrode pair is connected by the second and third electrodes Sandwiched and shielded, the first complementary electrode of the second complementary electrode pair is sandwiched and shielded by third and fourth electrodes, and the second electrode of the second complementary electrode pair is Sandwiched and shielded by 5 electrodes, And said plurality of overlapping electrodes and at least two pairs of complementary electrodes are spaced apart from each other by a material. The method according to any one of claims 1 to 17, At least a portion of the energy conditioner is formed by a doping process. The method according to any one of claims 1 to 17, The energy conditioner is at least part of an energy-regulating capacitive network. The method according to any one of claims 1 to 17, And said energy conditioner has at least two separate capacitive networks. The method according to any one of claims 1 to 17, And said energy conditioner has at least one bypass capacitor. The method according to any one of claims 1 to 17, And said energy conditioner has at least one feedthrough capacitor and at least one bypass capacitor. The method according to any one of claims 1 to 17, The energy conditioner has at least two separate voltage dividers. The method according to any one of claims 1 to 17, And said energy conditioner is a voltage divider. The method according to any one of claims 1 to 17, The energy conditioner is selected from the group of energy conditioners comprising a bypass energy conditioner, a feedthrough energy conditioner and a cross-over energy conditioner. The method according to any one of claims 1 to 17, The energy conditioner is connected to a component selected from the group of components consisting of a substrate, a motor and a circuit. The method according to any one of claims 1 to 17, The energy conditioner prevents a portion of the adjacent-field electron flux from being emitted from the energy conditioner. The method according to any one of claims 1 to 17, The energy conditioner is operative to be used for supported electrostatic shielding. The method according to any one of claims 1 to 17, The energy conditioner is an annular shape. The method according to any one of claims 1 to 17, The energy conditioner further comprises an annular portion. The method according to any one of claims 1 to 17, The energy conditioner further comprises at least one aperture. The method according to any one of claims 1 to 17, The energy conditioner can operate as part of a first circuit, and the energy conditioner can operate as part of a second circuit. The method according to any one of claims 1 to 17, The energy conditioner is operative to regulate the separated energy of at least the first and second circuits, respectively. The method according to any one of claims 1 to 17, And wherein some of the energy conditioners are split electrodes. The method according to any one of claims 1 to 17, The energy conditioner is energized.