WO2001043056A1 - Systems and methods for wirelessly projecting power using multiple in-phase current loops - Google Patents
Systems and methods for wirelessly projecting power using multiple in-phase current loops Download PDFInfo
- Publication number
- WO2001043056A1 WO2001043056A1 PCT/US2000/033307 US0033307W WO0143056A1 WO 2001043056 A1 WO2001043056 A1 WO 2001043056A1 US 0033307 W US0033307 W US 0033307W WO 0143056 A1 WO0143056 A1 WO 0143056A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- current loops
- loops
- current
- phase
- arrays
- Prior art date
Links
Classifications
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/12—Supports; Mounting means
- H01Q1/22—Supports; Mounting means by structural association with other equipment or articles
- H01Q1/2208—Supports; Mounting means by structural association with other equipment or articles associated with components used in interrogation type services, i.e. in systems for information exchange between an interrogator/reader and a tag/transponder, e.g. in Radio Frequency Identification [RFID] systems
- H01Q1/2216—Supports; Mounting means by structural association with other equipment or articles associated with components used in interrogation type services, i.e. in systems for information exchange between an interrogator/reader and a tag/transponder, e.g. in Radio Frequency Identification [RFID] systems used in interrogator/reader equipment
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06K—GRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
- G06K19/00—Record carriers for use with machines and with at least a part designed to carry digital markings
- G06K19/06—Record carriers for use with machines and with at least a part designed to carry digital markings characterised by the kind of the digital marking, e.g. shape, nature, code
- G06K19/067—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components
- G06K19/07—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components with integrated circuit chips
- G06K19/0701—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components with integrated circuit chips at least one of the integrated circuit chips comprising an arrangement for power management
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06K—GRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
- G06K19/00—Record carriers for use with machines and with at least a part designed to carry digital markings
- G06K19/06—Record carriers for use with machines and with at least a part designed to carry digital markings characterised by the kind of the digital marking, e.g. shape, nature, code
- G06K19/067—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components
- G06K19/07—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components with integrated circuit chips
- G06K19/0701—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components with integrated circuit chips at least one of the integrated circuit chips comprising an arrangement for power management
- G06K19/0715—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components with integrated circuit chips at least one of the integrated circuit chips comprising an arrangement for power management the arrangement including means to regulate power transfer to the integrated circuit
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06K—GRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
- G06K19/00—Record carriers for use with machines and with at least a part designed to carry digital markings
- G06K19/06—Record carriers for use with machines and with at least a part designed to carry digital markings characterised by the kind of the digital marking, e.g. shape, nature, code
- G06K19/067—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components
- G06K19/07—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components with integrated circuit chips
- G06K19/0723—Record carriers with conductive marks, printed circuits or semiconductor circuit elements, e.g. credit or identity cards also with resonating or responding marks without active components with integrated circuit chips the record carrier comprising an arrangement for non-contact communication, e.g. wireless communication circuits on transponder cards, non-contact smart cards or RFIDs
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06K—GRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
- G06K7/00—Methods or arrangements for sensing record carriers, e.g. for reading patterns
- G06K7/0008—General problems related to the reading of electronic memory record carriers, independent of its reading method, e.g. power transfer
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06K—GRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
- G06K7/00—Methods or arrangements for sensing record carriers, e.g. for reading patterns
- G06K7/10—Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation
- G06K7/10009—Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation sensing by radiation using wavelengths larger than 0.1 mm, e.g. radio-waves or microwaves
- G06K7/10316—Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation sensing by radiation using wavelengths larger than 0.1 mm, e.g. radio-waves or microwaves using at least one antenna particularly designed for interrogating the wireless record carriers
- G06K7/10336—Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation sensing by radiation using wavelengths larger than 0.1 mm, e.g. radio-waves or microwaves using at least one antenna particularly designed for interrogating the wireless record carriers the antenna being of the near field type, inductive coil
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q7/00—Loop antennas with a substantially uniform current distribution around the loop and having a directional radiation pattern in a plane perpendicular to the plane of the loop
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q7/00—Loop antennas with a substantially uniform current distribution around the loop and having a directional radiation pattern in a plane perpendicular to the plane of the loop
- H01Q7/04—Screened antennas
Definitions
- This invention relates to systems and methods for wirelessly projecting power and more particularly to systems and methods for wirelessly projecting power to microelectronic devices.
- RFID tags are used in the Automatic Data Collection (ADC) industry.
- ADC Automatic Data Collection
- printed bar codes are now widely used in the ADC industry.
- bar codes may require line of sight reading, may hold limited amounts of information, may need to be read one at a time, may be subject to defacing and/or counterfeiting and may only provide fixed information.
- RFID tags need not require line of sight reading, can hold large quantities of information, can have high transfer data rates, can be read in groups, can be more reliable and more difficult to destroy and/or counterfeit and can update stored information.
- RFID tags generally may be classified into battery powered (active) RFID tags and RF powered (passive) tags.
- active tags may be more expensive, may have a defined shelf life, may deplete with operation, may have potential disposability problems, may be physically larger and may be environmentally constrained due to the presence of a battery thereon.
- passive tags can be less expensive, can have an unlimited shelf life without depletion, can be relatively safe to dispose, can be relatively compact and can withstand harsher operating environments.
- RF communication among electronic devices currently is used across the RF spectrum.
- cellular radiotelephones are widely used.
- FCC Federal Communications Commission
- the amount of power that is used to operate electronics may be orders of magnitude more than is used to exchange information. Accordingly, notwithstanding the advent of low power microelectronic devices, the ability to transmit enough power to be extracted by a remote microelectronic device may be difficult. In wirelessly projecting power to wirelessly power microelectronic devices, the biggest constraint may be the government regulations concerning permissible RF field strength.
- Electromagnetic field emanation from an antenna classically is categorized as “near field” and “far field.” Generally, electronic components that carry RF currents or voltages produce both types of fields. However, the relative amount of each field may vary greatly.
- near field generally refers to RF energy that is stored in the immediate vicinity of the component and that is recovered at a later time in the alternating RF current cycle.
- An ideal inductor is a perfect near field only device.
- Far field generally refers to the energy that radiates or propagates from a component as an electromagnetic wave.
- a real world inductor may produce some far field radiation.
- an ideal dipole antenna produces no near field components but produces significant far field radiation.
- Real world dipole antennas may produce some near field components but generate large amounts of far field radiation.
- the far field is the component of energy that permanently leaves an antenna or any other component, radiating or propagating into the environment as an electromagnetic wave.
- a near field is created and the energy associated with the near field is stored in the space around the antenna. As the near field collapses, the energy is transferred back onto the antenna and drive circuitry.
- near field and “far field” classically also may be defined relative to the wavelength of the energy under consideration.
- far field denotes energy at distances greater than about one wavelength, for example, greater than about 22 meters at 13.56 MHz and greater than about 31.6 cm at 950 MHz.
- near field refers to energy that is less than about one wavelength in distance.
- near field generally may be considered to be a fraction of a wavelength, while far field may generally be considered to be multiple wavelengths so that there may be an order-of-magnitude difference therebetween.
- Near field and far field also may be distinguished by the drop-off of power from the antenna.
- Power in the far field generally drops off from a source antenna without gain as a function of 1 /(distance) 2 .
- power in the near field generally may exhibit a more complex relationship.
- the individual current carrying elements of the antenna may produce a near field that decreases, remains constant or may even increase with distance.
- power generally drops off much quicker with distance compared to the far field, with some components dropping off as fast as 1 /(distance) , others closer to 1 /(distance) .
- Antennas generally are designed to communicate over great distances. Accordingly, antennas generally are designed to optimize the far field for a particular application. Accordingly, FCC regulations also generally are written for far field radiation. For example, radiation typically is measured based on FCC standards at a distance greater than one wavelength because it is assumed that near field energy is greatly reduced at that distance. However, there also are FCC guidelines that relate to maximum exposures to electromagnetic radiation that can impact near field intensity limits. For purposes of wirelessly projecting power to wirelessly power microelectronic devices, it would be desirable to increase the near field component of energy without increasing the far field component of energy sufficiently to violate FCC regulations. Preferably, the near field component also is not increased to the point where maximum exposure as stated by the FCC guidelines occurs too quickly.
- the microelectronic devices may be powered by the field that is stored in the space around the radiator.
- the energy that propagates outward and that is not reclaimed may be reduced, and violation of government regulations that govern far field energy may be prevented.
- the near field is increased in order to extend the range at which power may be projected to wirelessly power microelectronic devices, the far field also may increase, thereby increasing the likelihood of regulatory violations.
- the parent application provides an array of in-phase current loops that are disposed adjacent to one another to define a surface and to define a virtual current loop at a periphery of the surface that produces a same direction virtual current while current in adjacent portions of adjacent current loops flows in opposite directions, to thereby wirelessly project power from the surface.
- the array of in-phase current loops that are disposed adjacent to one another to define a surface and to define a virtual current loop at a periphery of the surface that produces a same direction virtual current while current in adjacent portions of adjacent current loops flows in opposite directions can provide acceptable power to RFID tags, while reducing the risk of violating regulatory constraints.
- in-phase refers to relationships at a given point in time.
- in-phase refers to instantaneous current relationships.
- in-phase refers to current loops that are substantially in phase and virtual currents that are substantially in the same direction or substantially in opposite directions or out-of-phase.
- current loops that are within ⁇ 20° of one another, more preferably ⁇ 10° of one another and most preferably of identical phase may be considered “in-phase.”
- Virtual currents that are within ⁇ 20° of the same direction, more preferably within ⁇ 10° of the same direction and most preferably identically in the same direction may be considered to be in the "same direction.”
- current loops or currents that are within 180° ⁇ 20° of one another, more preferably 180° ⁇ 10° of one another and most preferably 180° out-of-phase with one another may be regarded as being in the "opposite direction” or "out-of-phase.”
- the close-in near field refers to RF energy that is stored in the immediate vicinity an antenna, up to a distance of about the dimension of the antenna, such as the length of a dipole or the diameter of a loop.
- the mid field refers to RF energy that extends beyond the distance of about the dimension of the antenna to a distance of about one wavelength.
- the close-in near field may extend from the plane of the loop to a distance of about ten inches
- the mid field may extend from a distance of between about ten inches to about 22 meters
- the far field may extend to distances that are greater than about 22 meters. It will be understood, however that since both the close-in near field and the mid field are components of the near field, they both comprise RF energy that is stored and recovered in the alternating RF current cycle.
- an array of in-phase current loops that are disposed adjacent to one another to define a surface and to define a virtual current loop at a periphery of the surface that produces a same direction virtual current while current in adjacent portions of adjacent current loops flows in opposite directions can reduce far field radiation so that the likelihood of violations of government regulations can be reduced.
- the current in the array of in-phase current loops that are disposed adjacent to one another to define a surface and to define a virtual current loop at a periphery of the surface that produces a same direction virtual current with current in adjacent portions of adjacent current loops flowing in opposite directions can be increased to thereby allow an increase in mid field components. Sufficient mid field components to power RFID tags thereby may be provided, without violating government regulations concerning far field radiation.
- the array of in-phase current loops comprises an array of at least three wedge-shaped current loops, each having an outer portion and a pair of sides.
- the at least three wedge-shaped current loops are disposed adjacent to one another to define a surface such that the virtual current loop defined by the outer portions flow in same directions and current in adjacent sides of adjacent current loops flow in opposite directions.
- the wedge- shaped current loops may be identical or mirror imaged.
- Two wedge-shaped current loops also may be provided, wherein each wedge is semicircle-shaped.
- the array of in-phase current loops comprises an array of at least two polygonal current loops, such as hexagonal current loops, each having a plurality of sides.
- the at least two polygonal current loops are disposed adjacent to one another to define a surface and a virtual current loop at the periphery of the surface that produces a same direction virtual current, with current in adjacent portions of adjacent current loops flowing in opposite directions.
- currents in the sides of the at least two polygonal current loops that comprise the outer boundary are in-phase and currents in adjacent sides of adjacent current loops are out- of-phase.
- the current loops may be circular or elliptical in shape.
- the surface preferably is a planar surface.
- non-planar surfaces such as spheroidal surfaces also may be used.
- the surface may be a physical surface in which the array of in-phase current loops are mounted or may be a virtual surface defined by the array of in-phase current loops.
- Each of the current loops may be a spiral current loop, a concentric current loop and/or a stacked current loop.
- the length of each current loop preferably is less than a quarter wavelength.
- a driver drives the array of current loops at 13.56 MHz to thereby wirelessly project power.
- the frequency of 13.56 MHz preferably is used because the FCC allows relatively large amounts of field strength at this frequency.
- FCC regulations allow 10,000 ⁇ V/m, whereas immediately outside that range only 30 ⁇ V/m may be allowed.
- other frequencies also may be used in the United States and in other countries.
- a plurality of arrays of in-phase current loops may be provided.
- the multiple arrays of in-phase current loops are disposed adjacent to one another to define a surface.
- Each array of in-phase current loops may be configured as was described above.
- the virtual current loops of adjacent arrays of in-phase current loops produce different phase virtual currents from one another.
- four arrays of in-phase current loops may be provided that are arranged in two rows and two columns, such that the virtual current loops in the arrays in each row and each column are of opposite phase.
- the virtual currents in the arrays in each row and each column are approximately 90° out-of-phase from one another.
- the two rows and columns may be orthogonal or non-orthogonal.
- the two rows and two columns are obliquely arranged relative to the horizontal so that a tag passing across the plurality of arrays in the horizontal direction will encounter varying fields to thereby increase the likelihood of receiving sufficient power.
- six arrays of in-phase current loops may be provided that are arranged in four rows and two columns. In the first row, the phases of the virtual currents of the two arrays differ by approximately 60°. In the second row, the virtual currents of the two arrays flow in same directions, and in the third row, the phases of the virtual currents of the two arrays differ by approximately 60°. Viewed along the first column, the phases of the virtual currents are approximately 0°, 120° and 60° and along the second column the phases of the virtual currents are approximately 60°, 120° and 0°.
- a plurality of arrays of in-phase current loops are arranged in a circle, such that the virtual currents in adjacent arrays in the circle are of opposite phase.
- the phases may differ by approximately 360°/n, where n is the number of arrays of in-phase current loops that are arranged in a circle.
- the plurality of in-phase current loops also may be arranged in an elliptical shape or a polygonal shape. They may be overlapping or spaced apart. Accordingly, reduced far field radiation may be produced by systems and methods according to the present invention. By producing reduced far field radiation, the current in the current loops may be increased to thereby increase the mid field strength without violating government regulations for far field radiation.
- the outer portions of the wedge-shaped current loops also can be implemented as multiple loops that are spatially separated, while the sides of the wedges can remain the same.
- the close-in near field may be reduced so that exposure time under FCC guidelines can be increased.
- the systems and methods that were described above may produce undesirably large far field radiation in the plane of the current loops, normal to the axial direction.
- first and second spaced apart in-phase current loops may be provided that at least partially overlap in the axial direction.
- the current loops themselves may be actual current loops and/or any of the virtual current loops that were described above.
- first and second arrays of in-phase virtual current loops as described above may be provided, wherein the first and second arrays are spaced apart and at least partially overlap in the axial direction.
- First and second arrays of arrays also may be provided, that are spaced apart from one another and that at least partially overlap in the axial direction. Desirably high mid field strength may be provided without violating guidelines for far field radiation in the axial direction or in the plane of the loops.
- a third array of in- phase current loops, an array of third in-phase current loops and/or an array of arrays of third in-plane current loops also may be provided that is spaced apart from and at least partially axially overlaps the second loops, opposite the first loops.
- power may be wirelessly projected by providing a first array of in-phase current loops that are disposed adjacent to one another to define a first surface and to define a first virtual current loop at a periphery of the first surface that produces a same first direction virtual current while current in adjacent portions of adjacent current loops flows in opposite directions.
- the first surface includes a center, wherein two points on the periphery of the first surface and the center define a plane and an axial direction that is normal to the plane.
- a second array of in-phase current loops also may be provided that are disposed adjacent to one another to define a second surface and to define a second virtual current loop at a periphery of the second surface that produces a same second direction virtual current that is opposite the same first direction virtual current, while current in adjacent portions of adjacent current loops flows in opposite directions.
- the first surface is spaced apart from and at least partially overlaps the second surface in the axial direction.
- At least one of the first and second arrays may comprise wedge shaped current loops, polygonal current loops, spiral current loops, concentric current loops and/or stacked current loops as was already described.
- the first and second arrays of in-phase current loops may be of the same size.
- the first surface preferably is spaced apart from and completely overlaps the second surface in the axial direction.
- a receive antenna is provided between the overlapping portions of the first and second surfaces.
- the receive antenna is midway between the overlapping portions of the first and second surfaces and more preferably extends parallel to the overlapping portion of the first surface.
- a third array of in-phase current loops also may be provided, that are disposed adjacent to one another to define a third surface and to define a third virtual current loop at a periphery of the third surface that produces a same first direction virtual current while current in adjacent portions of adjacent current loops flows in opposite directions.
- the third surface is spaced apart from the second surface, is opposite the first surface and at least partially overlaps the second surface in the axial direction.
- third and fourth arrays of in-phase current loops also may be provided.
- the third array of in-phase current loops are disposed adjacent to one another to define a third surface and to define a third virtual current loop at a periphery of the third surface that produces a same first direction virtual current while current in adjacent portions of adjacent current loops flows in opposite directions.
- the third surface includes a center, wherein two points on the periphery of the third surface and the center define a second plane and a second axial direction that is normal to the second plane and that is different from the first axial direction.
- a fourth array of in-phase current loops also may be provided that are disposed adjacent to one another to define a fourth surface and to define a fourth virtual current loop at the periphery of the fourth surface that produces a same second direction virtual current that is opposite the same first direction virtual current while current in adjacent portions of adjacent current loops flows in opposite directions.
- the fourth surface is spaced apart from and at least partially overlaps the third surface in the second axial direction.
- Alternate embodiments of the present invention provide a plurality of first arrays of in-phase current loops and a plurality of second arrays of in-phase current loops wherein the plurality of first arrays of in-phase current loops define a first surface and the plurality of second arrays of in-phase current loops define a second surface, and wherein the first surface is spaced apart from and at least partially overlaps the second surface in the axial direction.
- four arrays of current loops may be provided, for example in two rows and two columns and/or a circle of arrays of in-phase current loops may be provided.
- the individual arrays of in-phase current loops may be provided as was described above.
- a plurality of third and fourth arrays of in-phase current loops also may be provided as was described above to reduce nulls.
- a first in-phase current loop that defines a first surface and that produces a first direction current.
- the first surface includes a center, wherein two points on the periphery of the first surface and the center define a plane and an axial direction that is normal to the plane.
- a second in-phase current loop defines a second surface that produces a second direction current that is opposite the first direction current.
- the first surface is spaced apart from and at least partially overlaps the second surface in the axial direction.
- the first surface completely overlaps the second surface in the axial direction.
- Third and fourth in-phase current loops also may be provided as was described above to reduce nulls.
- multiple in-phase current loops may be used to wirelessly project power in the mid field without violating far field radiation guidelines in the axial direction or normal to the axial direction.
- Fig. 1A is a schematic diagram of systems and methods for wirelessly projecting power according to the parent application
- Fig. IB illustrates another embodiment of systems and methods for wirelessly projecting power according to the parent application
- Figs. 2A-2E conceptually illustrate various embodiments of current loops according to the parent application
- Fig. 3 A illustrates an array of in-phase spiral current loops according to the parent application
- Fig. 3B illustrates an array of in-phase elongated spiral current loops according to the parent application
- Fig. 3C illustrates an array of in-phase spiral current loops that are disposed adjacent to one another to define a non-planar surface according to the parent application;
- Fig. 4 illustrates field cancellation in a local cancellation area according to the parent application;
- Figs. 5A-5D illustrate alternate configurations often wedge-shaped spiral in- phase current loops according to the parent application
- Fig. 6 illustrates an array of identical hexagonal-shaped in-phase current loops according to the parent application
- Fig. 7A illustrates two arrays of in-phase current loops according to the parent application
- Fig. 7B illustrates two rows and two columns of arrays of in-phase current loops according to the parent application
- Fig. 7C illustrates a plurality of arrays of in-phase current loops arranged in a circle according to the parent application
- Fig. 8 illustrates a grounded shield surrounding an array of current loops according to the parent application
- Figs. 9A, 9B, 10 and 11 illustrate printed circuit board embodiments of the parent application
- Fig. 12 schematically illustrates widening of an array of current loops according to the parent application
- Figs. 13A and 13B illustrate embodiments of receiving devices according to the parent application
- Fig. 14 illustrates sweeping the phase across an array according to the parent application
- Fig. 15 illustrates three arrays that project into a volume according to the parent application
- Fig. 16 illustrates a pair of spaced apart arrays according to the parent application
- Fig. 17 illustrates a pair of far field cancellation antennas about an array according to the parent application
- Fig. 18 illustrates a single current loop
- Figs. 19, 20 and 21 graphically illustrate a simulated magnetic field as a function of distance, for a single current loop of Fig. 18;
- Figs. 22, 24, 26, 28, 30, 32, 34, 35 and 37 illustrate various configurations of arrays of current loops according to the parent application; and Figs. 23, 25, 27, 29, 31, 33, 36 and 38 graphically illustrate a simulated magnetic field as a function of distance, according to the parent application.
- Fig. 39A illustrates a single in-phase current loop according to the parent application
- Figs. 39B-39D graphically illustrate simulations of electric field intensity at 30 meters, electric field azimuth pattern and magnetic field, respectively, for the in-phase current loop of Fig. 39 A;
- Fig. 40A illustrates two in-phase current loops that are spaced apart from one another to at least partially overlap in the axial direction according to the present invention
- Figs. 40B-4D graphically illustrate simulations of electric field intensity at 30 meters, electric field azimuth pattern and magnetic field, respectively, for the two in- phase current loops of Fig. 40A;
- Fig. 41 illustrates a receive antenna between overlapping portions of first and second current loops according to the present invention
- Fig. 42A illustrates three spaced apart at least partially axially overlapping current loops according to the present invention
- Fig. 42B-42D graphically illustrate simulations of electric field intensity at 30 meters, electric field azimuth pattern and magnetic field, respectively, for the three current loops of Fig. 42A;
- Fig. 43 illustrates first and second sets of spaced apart axially overlapping current loops having different axial orientations according to the present invention;
- Fig. 44 illustrates a first current loop and a pair of second current loops that are spaced apart from and axially overlap the first current loop according to the present invention.
- the present invention provides antenna configurations that can emphasize the mid field without producing undue amounts of close-in near field or far field. Thus, greater powering distances may be achieved that may not violate governmental regulations and/or guidelines. Accordingly, the present invention provides antenna configurations that can effectively project the mid field while simultaneously reducing at least some of the far field and distributing the close-in near field to reduce the peaks thereof. The mid field therefore can be extended without generating undue amounts of close-in near field or far field.
- Existing RFID systems may use the far field to power the RFID tags. These systems may use high frequency ranges because the wavelength is short and the close- in near field and even the mid field is attenuated after a few centimeters. By using a higher frequency, physically smaller antennas may be used and faster operation and collimation of energy beams may be provided.
- the mid field by using the present invention, at least two advantages may be provided. First, the FCC and other regulatory agency regulations generally are measured in the far field and are not violated by mid field radiation. Moreover, since the energy of the mid field may be recovered, except for those portions which are lost due to parasitic resistive loading and very low levels of radiated field each cycle, the overall power that is used to extend or project the field into the mid field may be reduced.
- the use of the magnetic field rather than the electric field may have advantages.
- the magnetic field lines form a loop, starting on one surface of the antenna and looping around to the other. Any loop or series of loops through which the flux lines penetrate can be used to extract power.
- Electric fields also may have more of an effect on the human body than magnetic fields. Accordingly, many of the newest standards may allow for higher exposure limits for magnetic fields.
- electric fields generally do not penetrate conductors whereas magnetic fields can penetrate non-ferrous materials such as aluminum and copper.
- Fig. 1 A is a schematic diagram of systems and methods for wirelessly projecting power according to the parent application. It will be understood that more complicated embodiments and more simple embodiments also may be provided as will be described in detail below.
- an array 100 of four wedge-shaped in-phase current loops HOa-llOd are disposed adjacent to one another to define a surface in the plane of the antenna (corresponding to the plane of the paper of Fig. 1 A) and to define a virtual current loop 120 at a periphery of the surface that produces a same direction virtual current.
- the in-phase nature of the current loops HOa-llOd is indicated in three different ways in Fig. 1 A. First, "+" and "-" signs are included for each current loop HOa-llOd to indicate how the loops may be driven from a common voltage and/or current source. Second, arrows in each leg of each current loop indicate direction of current flow at a given point in time.
- an arrow 112a-112d inside each current loop indicates counter-clockwise in-phase current flow in each current loop HOa-llOd at a given point in time. Accordingly, the current that flows in the same direction at the outer legs 114a-114d of current loops HOa-llOd produce the same direction virtual current 120.
- the outer legs need not be straight. They may be arced, rippled and or may comprise multiple straight segments. In contrast, current in adjacent portions 116a-116b, 118b- 118c, 116c-116d and 118d-118a of adjacent current loops HOa-llOd flows in opposite directions.
- an array 100 of in-phase current loops 110 can reduce far field for approximately the same value of near field compared to a single current loop. Acceptable power to RFID tags thereby may be provided while reducing the risk of violating regulatory constraints.
- Fig. IB illustrates another embodiment of systems and methods of the parent application that can provide additional reduction of far field and further increase of the mid field.
- the systems and methods 150 include a plurality of arrays lOOa-lOOd of in-phase current loops.
- the arrays lOOa-lOOd of in-phase current loops are disposed adjacent to one another to define a surface.
- each array of in-phase current loops defines virtual currents 120a-120d such that virtual currents of at least some adjacent arrays of in-phase current loops are out-of-phase with one another.
- each array of in-phase current loops lOOa-lOOd can contain a structure such as was described in Fig. 1 A and will not be described again.
- the parent application preferably uses an electrically small spiral or loop antenna for a current loop 110, which may be an inefficient radiator or producer of a strong far field. This may be achieved by using loops or spirals that are electrically very short. Preferably, the loop or spiral is much less than one-quarter of a wavelength.
- Figs. 2A-2E conceptually illustrate current loops 110 comprising a single loop, multiple loops, a two-turn spiral, a multi-turn spiral and concurrent loops, respectively. The length of each of the conductors is preferably much less than one- quarter of a wavelength to thereby provide an inefficient far field radiator. Spirals may be used to maximize the number of ampere turns in a planar environment and hence develop a strong mid field. Figs.
- 2C, 2D and 2E illustrate that the strength of a magnetic field created by current flowing in a wire may be increased by increasing the current or the length of the wire in the loops or spirals. In a plane, as on a printed circuit board, the length also may be increased with more turns in the spiral.
- Fig. 3 A illustrates another embodiment of systems and methods of the parent application.
- loops, spirals or polygons can be arranged such that adjacent current segments are out-of-phase and the periphery produces the in-phase virtual current loop.
- all of the loop currents flow clockwise to produce a clockwise virtual current 120.
- the loops are physically close, the currents of adjacent loops flow in opposite directions.
- the outer portions of the current loops are spatially separated to reduce the close-in near field without significantly effecting the mid field. Both the close-in near field and the mid field may be related to the size of the current loops and the number of ampere turns.
- the far field may not be completely independent of these parameters either.
- by using multiple arrays of arrays of in-phase current loops far field emissions can be reduced more than the reduction in the mid field projection.
- Fig. 3B illustrates an array of in-phase elongated spiral current loops.
- Fig. 3C illustrates an array of in-phase spiral current loops that are disposed adjacent to one another to define a non-planar surface 310.
- the spirals are mapped onto the surface of the sphere.
- the virtual current creates a magnetic field (B) which loops around the virtual current loop.
- the virtual current loop with the virtual current flowing through it creates a dipole of magnetic field which appears like an oval of revolution.
- the magnetic field is normal to the plane of the loop. The bigger the loop, the farther the mid field projects. Closer to the wire segment, the field loops around the wire.
- Figs. 5A-5C illustrate configurations often wedge-shaped spiral in-phase current loops 510 that produce a virtual current loop 520. As shown, cancellation of current in adjacent legs of the wedges may take place so that the mid field projection may be produced by the outside legs of the wedges that define the virtual current loop 520. Since the currents on the outside legs are the same distance from the driving point of the array, they are in-phase. Accordingly, the configurations of Figs. 5A-5C can use a reduced amount of canceling wire, thereby using less power, while generating less far field.
- Fig. 5 A illustrates ten identical wedge-shaped three-loop spiral in-phase current loops. It will be understood that any number of wedges may be provided and any number of loops may be provided in the spirals.
- the virtual current loop 520 is created by the in-phase current contributions of the three outer portions 501-503 of the wedges.
- Fig. 5B illustrates a similar configuration to Fig. 5A, except that alternating wedges are mirror images of one another. In this configuration, an even number of wedges preferably are provided.
- the virtual current loop 520 is created by the in-phase current contributions of the three outer portions 501-503 of the wedges.
- the fields created by the legs of adjacent wedges, such as legs 504 and 505 substantially cancel. Improved cancellation may be obtained compared to Fig. 5A because pairs of canceling legs may be the same length and the same distance from the "+" driving point.
- the + and - signs indicate how the array may be driven, with all + points electrically connected together and all - points electrically connected together.
- Fig. 5C illustrates a similar configuration to Fig.
- the legs of the wedges are moved physically closer. They may even be stacked on different layers of a frame or multilayer printed circuit board so that they overlap one another.
- the closely spaced or overlapping legs can provide improved cancellation so that virtually all the field contribution comes from the virtual current produced by the three outer portions of each wedge.
- this configuration can provide less far field and about the same mid field and the same close-in near field as the configuration of Fig. 5 A.
- the current can be increased dramatically to produce far more mid field, without violating far field regulatory constraints.
- the outer portions of the wedges also may be moved closer together or stacked, as well as the legs of the wedges. This can produce a far field that is the same as if three times the current was flowing in one outer portion.
- the close-in near field also may be approximately three times that of the close-in near field compared to having three legs with 1/3 of the current in each. Accordingly, in contrast with the legs, the outer portions preferably are not moved close together or stacked.
- the mid field projection may be reduced since the mid field distance projection is related to the effective size of the outer portions.
- the outer portion 502 may not project as far as the outer portion 501.
- the loops preferably are not made too large because the length of the legs may become a larger proportion of the overall length, the inductance may increase and the loop length may become appreciable with respect to the wavelength. The loops also may become too large physically for efficient manufacture and/or use.
- Similar phenomenon may occur if too many loops are used in each spiral wedge.
- the overall loop length may make it difficult to reliably resonate the inductance.
- the inductance may become so large that an unreasonably small capacitance may be needed to resonate at 13.56 MHz.
- each wedge may include two or more concentric loops that are wired in parallel, as shown in Fig. 5D.
- Each loop may be driven independently, with its own resonant capacitor or driver circuit. It also will be understood that the configurations of Figs. 5A-5D may be combined, for example to provide a combined spiral and parallel loop approach.
- Fig. 6 illustrates an array of identical hexagonal-shaped in-phase current loops.
- the six-edge pairs of wires can have identical current flowing in opposite directions. Magnetic fields of each of the spirals still project outward and add.
- the virtual current loop 520 projects mid field while allowing reduced far field.
- the current loops can be other polygonal shapes such as squares, triangles, rectangles, etc. and also can be circular or elliptical.
- the array need not be symmetrical, and all the individual loops need not be identical.
- the hexagonal-shaped, in-phase current loops of Fig. 6 may allow shorter wire lengths of the individual loops. The inner segments may cancel well due to equal and opposite currents flowing adjacent to one another.
- peripheral segments do not cancel, and produce the virtual current loop as shown in Fig. 6.
- the virtual current loop may be made larger. Similar effects may be obtained with triangle-shaped current loops.
- Other polygonal shapes such as hexagons may not be nested as well to provide almost complete cancellation of inner segments, due to the configuration of other polygons.
- the arrays of in-phase current loops as illustrated in Figs. 1 A, 3A-3C, 5 and 6 may still produce some far field radiation.
- this far field radiation may be further reduced by providing multiple arrays of in-phase current loops wherein each array of in-phase current loops defines a virtual current such that virtual currents of at least some adjacent arrays of in-phase current loops are of differing phase with respect to one another. Since the far field is measured at 30 meters, per FCC Regulations Part 15, multiple arrays of in-phase current loops can produce the opposite radiation at 30 meters and thus cancel at least some more of the far field.
- Fig. 7A two arrays 500 and 500' of in-phase current loops are provided that define virtual currents 520 and 520' that are 180° out-of-phase with one another. Stated differently, they are of opposite phase. Although there may be some cancellation of the near field and mid field, there may be a larger amount of cancellation of the far field.
- Fig. 7B illustrates two rows and two columns of arrays of in-phase current loops with alternating clockwise and counter-clockwise virtual current flow. This arrangement may be able to cancel the far field in more directions better than the arrangement of Fig. 7A. It will be understood that the terms "row” and “column” are used herein to indicate two directions that are not necessarily horizontal and vertical.
- Fig. 7C illustrates yet another arrangement wherein a plurality of arrays of in- phase current loops are arranged in a circle with the virtual currents of adjacent arrays being 180° out-of-phase with one another.
- the virtual currents of adjacent arrays are 180°/n or 360°/n out-of-phase with one another, where n is the number of arrays of in-phase current loops.
- the virtual currents of a subset of the arrays are 180°/n or 360°/n out-of-phase where n is the number of arrays in a subset. Any integer number of subsets may be combined.
- the individual arrays can be rotated to any angle with respect to one another, arranged in any order and/or placed in any pattern close together.
- one or more of the arrays may only include a single current loop.
- an array of single current loops in any of the configurations and/or phase relationships described above may be used to project the mid field while reducing far field radiation.
- Using simple loops may allow less drive circuitry and may be acceptable in portable applications where projection into a relatively large volume may not be needed.
- the array also can use a shield around the outside edge to absorb spurious far field generated by the array. See Fig. 8 which shows a grounded metal shield 810 that can comprise steel or iron, surrounding the outside of an array to reduce spurious far field propagation. It will be understood that the shield may be placed around individual loops, individual arrays or a plurality of arrays.
- each spiral may be dependent on the configuration and current flowing in adjacent elements. By controlling the current to thereby match the different impedances of each current loop individually, the overall performance also can be improved.
- the current loops of the parent application may be freestanding wires. A supporting frame that supports the wires at various points also may be provided.
- the current loops may be formed on a substrate that can support the entire plurality of arrays of current loops. The substrate may be one or more printed circuit boards. Multi-layer circuit boards may be utilized to run wires with currents behind or interdigitated with existing elements. See Fig. 9A which illustrates traces on a printed circuit board that may be stacked on different levels and Fig.
- FIG. 9B which illustrates interdigitated top level and interlevel traces.
- edge of the outside spirals may be stacked to promote single line cancellation.
- Large currents or extreme phase control of the individual turns also may be implemented with concentric loops instead of spirals which may be implemented by multi-layer printed circuit boards. See Fig. 11.
- the receiving device should be electrically matched to the transmitting array.
- the more of the mid field flux lines that go through the receiving loops the more power that generally can be projected.
- tags oriented parallel to the array generally may receive a higher density of flux through them.
- a tag's orientation may be such that so little flux is received that it remains undetected.
- orientation independence can be achieved with different methods. For example, a two- or three-dimensional series of loops at the receiving device can increase the likelihood that a certain amount of flux passes through one or more of the loops regardless of orientation. See Fig.
- FIG. 13 A which illustrates three loops of wire at a tag, one in each orthogonal dimension to reduce orientation problems.
- Fig. 13B illustrates a two-dimensional version of a receiving device that can capture flux lines that are perpendicular to the planes defining the spirals.
- multiple projecting arrays may be provided. Moreover, rows and columns need not extend in the horizontal and vertical directions. Rather, oblique rows and columns may be provided as illustrated in Fig. IB. Thus, an increased likelihood that a horizontally or vertically traveling RFID tag will receive enough flux to power the RFID tag may be provided.
- changing the phase and/or magnitude of current through a portion of the projecting array can modify the shape and direction of the projected magnetic field.
- a collimated beam of flux can be moved electronically. See Fig. 14.
- a beam can be moved by changing which part of the array is on or off or by slowly changing the relevant phase and or magnitude of currents in each element.
- the phase of the plurality of arrays may be changed over time to thereby produce a similar far field while moving nulls of the mid field in space over time.
- the illustrated phase relationships may be maintained for a first time period, such as one second, and second phase relationships may be maintained for succeeding time periods.
- a 60° phase leg may be introduced into each of the plurality of arrays.
- an additional 60° phase leg may be introduced, etc.
- Yet another approach may add one or more arrays that project into the volume. Since magnetic fields add as vectors, the field at any point in the volume is a vector sum of all the contributions of the individual current segments. Thus, changing the magnetic field from any or all of the individual arrays may be used to dynamically change the direction and strength of the field at any point. Finally, multiple arrays may be included, each covering a different dimension of the volume. See Fig. 15 in which three arrays are provided wherein Array 1 can project downward, Array 2 can project to the right and Array 3 can project back in the volume to be covered. Each dimension can then be activated independently. In order to extend the magnetic field even further, additional antennas may be placed directly across from the first with the same field polarity orientation. See Fig. 16.
- one or more sensing antennas may be provided to sense communications from the devices.
- the sensing antennas preferably are dipoles. Spatially separated, orthogonally oriented dipoles may be provided to increase the ability to detect communications while reducing the likelihood of destructive interference among the device communications to the antennas.
- the systems and methods of the parent application can create mid field magnetic energy that can be made wide and deep without excessive far field generation and without excessive field strength near the antenna structure.
- the magnetic field can be used to operate electronic devices remotely. These electronic devices may include RFID tags, remote sensors such as implanted temperature sensors, and/or remote actuators such as a relay inside a vacuum.
- other applications desiring a strong-shaped magnetic field for unlicensed operation may benefit from the parent application.
- Fig. 18 illustrates a single ten-inch diameter loop.
- the dot in Fig. 18 and in the remaining figures indicates the X-Y axis location for taking Z axis measurements at 3 meters and at 30 meters.
- the magnetic field at three meters was 0.00421 A/m with a current of 0.81761 amps.
- Fig. 19 is a log/log plot of the H field as a function of distance along the Z axis from one to 100 inches. Accordingly, the close-in near field is indicated to the left of the ten-inch mark in Fig. 19 and the mid field is indicated to the right of the ten-inch mark in Fig. 19.
- the H field at three meters was simulated to be 0.00417 A/m at a current of 0.205317 A.
- a log/log plot of the H field versus distance on the Z axis for a 20-inch loop is shown in Fig. 20.
- Fig. 21 is a log/log plot for the 40-inch diameter loop. Comparing the ten-inch loop, 20-inch loop and 40-inch loop, it can be seen that the mid field produced can be about the same using less current.
- Fig. 22 illustrates a 20-inch diameter bi-loop which may also be thought of as a pair of in-phase current loop wedges.
- a simulated mid field of 0.00932 A/m was produced at a current of 0.6077701 A.
- Fig. 23 is a log/log plot of the simulated near field and mid field. As shown by comparing Figs. 20 and 23, the 20-inch diameter bi- loop can produce a larger mid field than a 20-inch diameter loop, without violating FCC regulations.
- Fig. 24 illustrates a 20-inch diameter tri-loop.
- a mid field of 0.00933 A/m was simulated at a current of 0.610333 A.
- Fig. 25 graphically illustrates the close-in near field and mid field components.
- Fig. 26 illustrates a 20-inch square loop.
- a mid field of 0.00389 A/m was produced with a current of 0.126952 A. Accordingly, there may not be a large difference between square and circular loops, but the square loop may be easier to fabricate and support.
- Fig. 27 graphically illustrates the close-in near field and mid field for a 20-inch square loop.
- Fig. 28 illustrates a 20-inch quad wedge. Simulations show that a mid field of 0.000926 A/m may be produced at a current of 0.474899 A. Accordingly, a 20-inch quad wedge can provide a large improvement over a 20-inch diameter loop of Fig. 22.
- Fig. 29 graphically illustrates near field and mid field for the 20-inch quad wedge.
- Fig. 30 illustrates two arrays of 20-inch quad wedges. Simulations indicate that a mid field of 0.001394 A/m is produced at a current of 3.02641 A.
- Fig. 31 graphically illustrates the close-in near field and mid field components.
- Fig. 32 illustrates four 20-inch quad wedge arrays. A very high mid field of 0.02661 A m was simulated albeit at high current of 38.1075 A.
- Fig. 33 graphically illustrates the close-in near field and mid field of this configuration.
- Fig. 34 illustrates six 20-inch quad wedge arrays. Simulations indicate a magnetic field of 0.00119 A/m at a current of 3.02888 A.
- Fig. 35 illustrates six 20-inch quad wedge arrays wherein adjacent arrays are driven at 60° phase offsets from one another.
- Fig. 35 illustrates phase offsets that are different from 180°. These phase offsets can provide a more spatially uniform near field relative to arrays that have 180° phase differences. Simulations indicate that the array of Fig. 35 can provide a mid field of 0.005598 A/m at a current of 17.6789 A. Accordingly, a very high mid field at more modest current can be provided.
- Fig. 36 graphically illustrates the close- in near field and mid field.
- Fig. 37 illustrates six 20-inch quad wedge spirals at 60° offsets.
- each current loop is a two loop spiral current loop.
- Simulation shows the same mid field as the embodiment of Fig. 35, i.e., 0.0559 A/m, at a reduced current of 9.87382 A.
- Fig. 38 graphically illustrates the close-in near field and mid field for this configuration. Accordingly, the configuration of Fig. 37 may be most preferred, based on simulations.
- an order-of-magnitude more mid field may be produced at 3 meters without violating FCC regulations at 30 meters.
- This order-of-magnitude increase in mid field can provide wireless powering of microelectronic devices.
- Fig. 39A illustrates a single in-phase current loop 120 that may be produced using any of the systems or methods of the parent application.
- the peak magnitude of the far field occurs in the plane of the loop and is radially symmetric about it.
- the radiation pattern at 30 meters is relatively independent of the shape and size of the current loop if the phase change of the current around the loop is small.
- the magnitude of the far and the near field is linear with respect to the loop current and is highly dependent on the size and the shape of the loop.
- Fig. 39D shows the H (magnetic) field 3 meters from the plane of the current loop 120. As shown, the magnetic near field is greatest axially in front of the loop.
- the simulation results of Figs. 39B-D are for a 40 inch square antenna comprised of four adjacent 20-inch squares as was described in the parent application. The current was set so that the far field radiation at 30 meters just passed FCC regulations, which occurs at about 0.1196A.
- Fig. 40A shows two in-phase current loops 120a and 120b that are spaced apart from one another to at least partially overlap in the axial direction according to the present invention. In Fig. 40A the two current loops 120a and 120b are illustrated as being planar. However, either or both need not be planar.
- the at least partial overlap between the first current loop 120a and second current loop 120b may be defined by a first surface that is defined by the first current loop 120a, and a center C for the first surface, wherein two points PI and P2 on the periphery of the first surface and the center C define a plane and an axial direction A that is normal to the plane.
- the second current loop 120b uses a same second direction current that is opposite the same first direction current of the first virtual current loop 120a, wherein the first surface is spaced apart from and at least partially overlaps the second surface in the axial direction A.
- either or both of the loops 120a and 120b may be formed using any of the systems or methods described in the parent application including an actual current loop, an array of in-phase virtual current loops and/or an array of arrays of in-phase virtual current loops. Radiation at 30 meters due to both current loops 120a and 120b can be considered to be the vector sum of the radiation due to each of the actual or virtual current loops.
- the case of two current loops placed as in Fig. 40 A yields a resultant radiation pattern that is the vector sum of the two opposite electromagnetic fields. The closer two identical and opposite phase current loops are physically placed, the lower the resultant electromagnetic fields, near and far alike.
- two current loops separated by relatively short distances appear to be almost coincident at wavelength distances. Indeed, at points equidistant from both loops, i.e. in the plane that splits the loops, much of the far field cancels.
- the magnitude of the near field is a stronger function of the closer loop. Indeed, from the axis A in front of one of the two loops, the cancelled effect of the more distant loop generally is lowest.
- two loops arranged as shown in Fig. 40A can simultaneously create a far field pattern with the two loops effectively canceling where the individual loop radiation is the greatest and, a magnetic near field that can reduce and preferably minimize the canceling effect of the second loop where the individual loop field is at maximum.
- Figs. 40B, 40C and 40D graphically illustrate simulation results for two identical loops as described in Fig. 40A, separated by twelve inches. Again, the current was set so that the far field radiation at 30 meters just passed FCC regulations at the maximum points. This yields a current of approximately 2.728A in each loop.
- the near magnetic field of Fig. 40D was measured at a distance of 3 meters from the plane of the closer loop. This field will be the same on either side since the field is symmetric but opposite in phase from one side to another. As shown, a much stronger magnetic field may be produced at 3 meters compared to a single current loop of Figs. 39A-39D.
- Physically identical current loops 120a and 120b may be used to produce virtual or actual current of the same magnitude but of opposite phase due to symmetry. If the loops are physically identical, then any influence that the current distribution on one loop may have over the other also generally exists in reverse. Moreover, identical drivers may be used with both loops or a single driver may be used to drive the loops together. In the latter case, the 180° phase difference between the loops may be accomplished by wiring the loops in parallel, but with the wires reversed on one of the loops, as was described in the parent application.
- the spacing of the loops 120a and 120b may affect the magnitude of the resultant radiation. As the loops are moved closer together, they can cancel better. Accordingly, in order to keep the far field radiation at a particular value, for example, just below FCC guidelines, the current in each of the virtual current loops 120a and 120b may need to be increased. It might be assumed that these larger currents would also increase the composite near magnetic field in front of the loops. However, the closer spacing also can cancel the near field more efficiently as well. There may be a slight gain, particularly at axial distances comparable to the spacing between the , loops, but the problems associated with much higher currents may offset this advantage.
- the current loops 120a and 120b need not be physically identical to have similar performance.
- the in-phase current loops of the parent application can provide for a relatively uniform "disc" of far field radiation in the plane of the current loop.
- the magnitude of the pattern can be adjusted by changing the magnitude of the current.
- the near field may be canceled less, thereby providing improved wireless power projection without violating far field regulations.
- the lower the ratio of far to near field radiation due to the closer loop the better may be the performance.
- Physical parameters including but not limited to loop shape, loop size, wire diameter and/or dielectric around the wires may be used to optimize these ratios.
- One possible drawback to nonidentical loops is the potential need for different currents in the loops. Thus, the currents may need to be adjusted for proper balance.
- Fig. 41 illustrates other embodiments of the present invention wherein a receive antenna 410 is placed between overlapping portions of the first and second surfaces of the first and second current loops 120a and 120b, preferably midway between the overlapping portions of the first and second surfaces and more preferably parallel to the overlapping portion of the first and/or second surfaces.
- a receive antenna 410 is placed between overlapping portions of the first and second surfaces of the first and second current loops 120a and 120b, preferably midway between the overlapping portions of the first and second surfaces and more preferably parallel to the overlapping portion of the first and/or second surfaces.
- Solutions to this problem include physically separating the transmit and receive antennas and circuitry and/or completely powering down the transmitter when tag data is expected to return.
- physically separating the transmit and receive antennas and circuitry may need a larger, less versatile reader and may not necessarily alleviate the problem.
- completely powering down the transmitter when tag data is expected may require a more complex tag design that can operate without power and synchronization.
- the present invention that uses two spaced apart, opposite phase, axially overlapping current loops 120a and 120b can provide a surface between the loops that can have no magnetic flux crossing it.
- this surface is a plane midway between the two.
- a receive loop antenna 410 that is placed on this plane will have very little of the carrier frequency imparted upon it from the current loops 120a and 120b.
- a relatively large loop or loops may be employed as the reader receive antenna without the need to filter an excessive component of the carrier frequency.
- an extremely sensitive circuit can be designed utilizing a low noise amplifier with far less concern about carrier frequency saturation.
- multiple separate receive loops on the surface may be used to increase sensitivity and/or reliability and/or to ascertain the direction of the tag moving with respect to the reader or a reader moving with respect to a tag or series of tags.
- Figs. 42A-42D illustrate other embodiments of the invention wherein three current loops 120a-120c are spaced apart and at least partially overlap in the axial direction.
- the loops may be identical and may totally overlap.
- the loops may be formed using any of the techniques of the parent application, including an actual current loop, an array of in- phase current loops and/or arrays of arrays of in-phase current loops.
- each of the three virtual current loops 120a-120c is formed by four adjacent 20 inch squares. Spacing between the loops was set at 12 inches.
- the middle loop 120b is used as the canceling loop, carries approximately twice the current as the other two loops 120a and 120c, and is 180° out-of-phase with respect to the other two loops 120a and 120c.
- the currents were set so that the FCC regulation of O.OlV/m was not violated anywhere on the 30 meter sphere surrounding the loop.
- These currents are 128.3A in the middle loop 120b and 64.22A in the other two loops 120a and 120c. See Figs. 42B and 42C.
- Fig. 42D a near magnetic field plot is shown at a distance of 3m from the plane of the closest loop. As shown, even larger magnetic fields than were available with two loop designs of Fig. 41, may be available.
- this near magnetic field plot applies to either sides of the loops. Since all the configurations described produce two equally viable near fields, one such unit may be placed between two doorways to simultaneously cover both. Note that, as was the case for the two loops of Fig. 40A, all the loops 120a, 120b and 120c may have different physical parameters to optimize the near field. If a particular application is such that the near magnetic field that is desired is only half that supplied by one of the described configurations, then the currents may be reduced by a factor of 2. This would also reduce the maximum far field radiation on the 30 meter sphere by a factor of 2. The relatively large currents that are shown to generate the fields of the triple loop of Fig. 42A can be reduced using the techniques described in the parent application. It also will be understood that four or more alternating phase, spaced apart and axially overlapping loops also may be provided.
- the near magnetic field strength of 3 meters greatly increases as one progresses from one loop to two loops to three as shown in Figs. 39D, 40D and 42D, but much less than the generating currents increase. This phenomenon appears to indicate that by canceling the far field, much of the near field also is canceled. However, by controlling the uniformity and directionality of the field generation, one can cancel the near field less than the far field.
- the hot spots, actually hot "rings," created with three loops cover more area on the 30 meter sphere of Fig. 42B than do the spots created with the two loop structure of Fig. 40B. This suggests that by creating a more spherically uniform radiation pattern the near field may be increased even further.
- the desired effect may be achieved.
- Another approach may involve placing the similar phase virtual current generators in a spiral pattern on a complex three dimensional, nonplanar surface.
- the spokes or feed lines of these virtual current structures need not be in the same plane as the loop itself.
- the virtual current loops need not be planar. For example, a pair of zigzag edged loops may produce a more distributed band of far field radiation than a pair of straight edges. This may allow an increase in current such that the near field may be stronger.
- a tag's orientation with respect to the magnetic flux lines may be an important factor for proper operation. For a flat tag, only those flux lines that are perpendicular to the tag surface generally contribute to the tag's power supply.
- different embodiments were described to increase the likelihood that a moving or stationary tag would receive enough flux to operate properly.
- two or more sets of spaced apart, axially overlapping loops may be used, with different axial orientations, to enhance the likelihood that a tag will receive enough magnetic flux lines notwithstanding the tag's orientation.
- a first set of spaced apart current loops 120a and 120b that at least partially axially overlap, and a second set of spaced apart current loops 120a' and 120b' that at least partially axially overlap are provided.
- the first and second sets of current loops have different axial orientations as shown by the different axes Al and A2 that are defined by the respective points Cl, PI and P2 and C2, PI' and P2'.
- Figs. 39A, 40A and 42A all have a null spot, generally along the axis A, when flat tags are presented perpendicular to the plane of the transmitting antennas.
- Fig. 43 With two complete sets of loops mounted together but at a slight angle with respect to each other, as shown in Fig. 43, all spots may be covered as each set can cover the other set's nulls.
- the two sets of loops preferably are not powered at the same instant because this may create multiple 30 meter far field variations. However, by alternating operation between the two sets, a large coverage volume without nulls may be provided. The same effect may be obtained by physically turning one set of loops. In order to efficiently cover a larger area with two sets of loops, one set may be oriented slightly to the left and upward while the other set may be oriented slightly to the right and downward. This can provide minimal or no overlapping of the nulls of the two sets.
- a first virtual current loop 120a and at least two second current loops 120b' and 120b" are provided, each of which is spaced apart from the first current loop 120a and each of which at least partially laterally overlaps the first virtual current loop 120a while being axially offset from each other.
- each of the two outer loops 120b' and 120b" is skewed with respect to each other and preferably is also slightly skewed with respect to the first or canceling loop 120a. This may move and increase the magnitude of the far field radiation so that the overall current may need to be reduced slightly to compensate.
Landscapes
- Engineering & Computer Science (AREA)
- Computer Hardware Design (AREA)
- Microelectronics & Electronic Packaging (AREA)
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Theoretical Computer Science (AREA)
- Computer Networks & Wireless Communication (AREA)
- Artificial Intelligence (AREA)
- Computer Vision & Pattern Recognition (AREA)
- Health & Medical Sciences (AREA)
- Toxicology (AREA)
- Electromagnetism (AREA)
- General Health & Medical Sciences (AREA)
- Variable-Direction Aerials And Aerial Arrays (AREA)
Abstract
Description
Claims
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP00982523A EP1238362A1 (en) | 1999-12-08 | 2000-12-08 | Systems and methods for wirelessly projecting power using multiple in-phase current loops |
AU19545/01A AU1954501A (en) | 1999-12-08 | 2000-12-08 | Systems and methods for wirelessly projecting power using multiple in-phase current loops |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US16972699P | 1999-12-08 | 1999-12-08 | |
US60/169,726 | 1999-12-08 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2001043056A1 true WO2001043056A1 (en) | 2001-06-14 |
Family
ID=22616936
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/US2000/033307 WO2001043056A1 (en) | 1999-12-08 | 2000-12-08 | Systems and methods for wirelessly projecting power using multiple in-phase current loops |
Country Status (3)
Country | Link |
---|---|
EP (1) | EP1238362A1 (en) |
AU (1) | AU1954501A (en) |
WO (1) | WO2001043056A1 (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2006097760A1 (en) * | 2005-03-18 | 2006-09-21 | Innovision Research & Technology Plc | Communications device, apparatus and system |
GB2455909A (en) * | 2007-12-19 | 2009-07-01 | Mark Rhodes | Loop antenna composed of individually-driven sub-loops |
WO2014006417A1 (en) * | 2012-07-05 | 2014-01-09 | Cryogatt Systems Ltd | Rfid reader having an array of antennas |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4373163A (en) * | 1980-07-14 | 1983-02-08 | I.D. Engineering, Inc. | Loop antenna for security systems |
EP0645840A1 (en) * | 1993-09-24 | 1995-03-29 | N.V. Nederlandsche Apparatenfabriek NEDAP | Antenna configuration of an electromagnetic detection system and an electromagnetic detection system comprising such antenna configuration |
EP0693733A1 (en) * | 1994-06-28 | 1996-01-24 | Sony Chemicals Corporation | Short-distance communication antennas and methods of manufacture and use of same |
WO1997038404A1 (en) * | 1996-04-10 | 1997-10-16 | Sentry Technology Corporation | Electronic article surveillance system |
-
2000
- 2000-12-08 AU AU19545/01A patent/AU1954501A/en not_active Abandoned
- 2000-12-08 WO PCT/US2000/033307 patent/WO2001043056A1/en not_active Application Discontinuation
- 2000-12-08 EP EP00982523A patent/EP1238362A1/en not_active Withdrawn
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4373163A (en) * | 1980-07-14 | 1983-02-08 | I.D. Engineering, Inc. | Loop antenna for security systems |
EP0645840A1 (en) * | 1993-09-24 | 1995-03-29 | N.V. Nederlandsche Apparatenfabriek NEDAP | Antenna configuration of an electromagnetic detection system and an electromagnetic detection system comprising such antenna configuration |
EP0693733A1 (en) * | 1994-06-28 | 1996-01-24 | Sony Chemicals Corporation | Short-distance communication antennas and methods of manufacture and use of same |
WO1997038404A1 (en) * | 1996-04-10 | 1997-10-16 | Sentry Technology Corporation | Electronic article surveillance system |
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2006097760A1 (en) * | 2005-03-18 | 2006-09-21 | Innovision Research & Technology Plc | Communications device, apparatus and system |
GB2455909A (en) * | 2007-12-19 | 2009-07-01 | Mark Rhodes | Loop antenna composed of individually-driven sub-loops |
GB2455909B (en) * | 2007-12-19 | 2010-03-03 | Mark Rhodes | Antenna formed of multiple planar arrayed loops |
WO2014006417A1 (en) * | 2012-07-05 | 2014-01-09 | Cryogatt Systems Ltd | Rfid reader having an array of antennas |
US9418265B2 (en) | 2012-07-05 | 2016-08-16 | Cryogatt Systems Limited | RFID reader having an array of antennas |
Also Published As
Publication number | Publication date |
---|---|
AU1954501A (en) | 2001-06-18 |
EP1238362A1 (en) | 2002-09-11 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US6570541B2 (en) | Systems and methods for wirelessly projecting power using multiple in-phase current loops | |
EP1078329B1 (en) | Systems and methods for wirelessly projecting power using in-phase current loops and for identifying radio frequency identification tags that are simultaneously interrogated | |
KR102542787B1 (en) | Large-area expandable high-resonant wireless power coil | |
US9991583B2 (en) | Antenna apparatus and communication terminal instrument | |
ES2776023T3 (en) | Multi-loop signal cancellation transmit / receive antenna for a radio frequency identification reader | |
US8436780B2 (en) | Planar loop antenna system | |
JP4717830B2 (en) | Tag device | |
JP2003110338A (en) | Inductive radio antenna and data communication method and noncontact data communication equipment using the same | |
US20050057422A1 (en) | Gate antenna device | |
EP2973847B1 (en) | Method to drive an antenna coil maintaining limited power source output | |
JP4069377B2 (en) | Reader / writer antenna and RFID system including the antenna | |
US11733281B2 (en) | Alternative near-field gradient probe for the suppression of radio frequency interference | |
JP2008035219A (en) | Plane antenna | |
JP2011125016A (en) | Device for locating object by rfid communication | |
JP4874120B2 (en) | Planar antenna with rotating magnetic field comprising a central loop and an eccentric loop, and a system for radio frequency identification | |
EP1238362A1 (en) | Systems and methods for wirelessly projecting power using multiple in-phase current loops | |
US9847576B2 (en) | UHF-RFID antenna for point of sales application | |
JP2006340246A (en) | Antenna device | |
JP2007043245A (en) | Antenna, and reader-writer | |
JP2010081334A (en) | Planar array antenna, and communication terminal and wireless module using the same | |
JP7154651B2 (en) | Cable antennas, gate antennas, antenna units, automated transport racks, and unmanned cash registers | |
JP4952439B2 (en) | ANTENNA DEVICE AND WIRELESS COMMUNICATION SYSTEM | |
JP2015103898A (en) | Reader writer antenna | |
JP2011061356A (en) | Loop antenna of reader/writer |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
AK | Designated states |
Kind code of ref document: A1 Designated state(s): AE AG AL AM AT AU AZ BA BB BG BR BY BZ CA CH CN CR CU CZ DE DK DM DZ EE ES FI GB GD GE GH GM HR HU ID IL IN IS JP KE KG KP KR KZ LC LK LR LS LT LU LV MA MD MG MK MN MW MX MZ NO NZ PL PT RO RU SD SE SG SI SK SL TJ TM TR TT TZ UA UG US UZ VN YU ZA ZW |
|
AL | Designated countries for regional patents |
Kind code of ref document: A1 Designated state(s): GH GM KE LS MW MZ SD SL SZ TZ UG ZW AM AZ BY KG KZ MD RU TJ TM AT BE CH CY DE DK ES FI FR GB GR IE IT LU MC NL PT SE TR BF BJ CF CG CI CM GA GN GW ML MR NE SN TD TG |
|
121 | Ep: the epo has been informed by wipo that ep was designated in this application | ||
DFPE | Request for preliminary examination filed prior to expiration of 19th month from priority date (pct application filed before 20040101) | ||
WWE | Wipo information: entry into national phase |
Ref document number: 2000982523 Country of ref document: EP |
|
WWP | Wipo information: published in national office |
Ref document number: 2000982523 Country of ref document: EP |
|
REG | Reference to national code |
Ref country code: DE Ref legal event code: 8642 |
|
WWW | Wipo information: withdrawn in national office |
Ref document number: 2000982523 Country of ref document: EP |
|
NENP | Non-entry into the national phase |
Ref country code: JP |