An apparatus for non-galvanic connection between two electrical circuits is described. A base-unit has an rf power source, a data link and an authentication controller. A contactless unit for communication with a base unit has an rf power receiver, a data link and an authentication controller. The base unit and contactless unit can form a non-galvanic connection to replace conventional connectors, for example in a USB wired bus connection.
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15. A base-unit for non-galvanic coupling to a contactless-unit, the base-unit comprising:
an antenna coupled to an rf power source,
at least one data-link,
an authentication controller coupled to the at least one data-link, and
a data interface for coupling at least one of a data source and data sink to the base unit, the data interface being coupled to the at least one data-link wherein
the base-unit is operable to
transmit and/or receive payload data via the data interface,
wirelessly transmit rf power from the rf power source to a contactless-unit in physical proximity to the base-unit,
transmit and/or receive authentication data via the at least one data-link to authenticate a non-galvanic connection to a contactless-unit only when the contactless-unit is in physical proximity to the base-unit, and
transmit and/or receive payload data via the at least one data link following the authentication of the non-galvanic connection to a contactless unit; and
at least one of a mechanical coupling element and a magnet and wherein in operation, the relative position of the base-unit and a contactless unit non-galvanically coupled to the base unit is fixed.
16. A contactless-unit for non-galvanic coupling to a base-unit, the contactless-unit comprising:
an antenna coupled to an rf power receiver,
at least one data-link, and
an authentication controller coupled to the at least one data-link,
a data interface for coupling at least one of a data source and data sink to the contactless unit, the data interface being coupled to the at least one data-link, wherein the contactless-unit is operable to
transmit and/or receive payload data via the data interface,
receive rf power provided from a base-unit only when the base-unit is in physical proximity to the contactless-unit,
convert the received rf power to supply power to circuits in the contactless-unit,
transmit and/or receive authentication data via the at least one data-link to authenticate a non-galvanic connection to a base-unit only when a base-unit is in physical proximity to the contactless-unit, and
transmit and/or receive payload data via the at least one data link following the authentication of the non-galvanic connection to a base unit; and
at least one of a mechanical coupling element and a magnet and wherein in operation, the relative position of the contactless-unit and a base unit non-galvanically coupled to the contactless unit is fixed.
1. A base-unit for non-galvanic coupling to a contactless-unit, the base-unit comprising:
an antenna coupled to an rf power source,
at least one data-link,
an authentication controller coupled to the at least one data-link, and
a data interface for coupling at least one of a data source and data sink to the base unit, the data interface being coupled to the at least one data-link wherein
the base-unit is operable to
transmit and/or receive payload data via the data interface,
wirelessly transmit rf power from the rf power source to a contactless-unit in physical proximity to the base-unit,
transmit and/or receive authentication data via the at least one data-link to authenticate a non-galvanic connection to a contactless-unit only when the contactless-unit is in physical proximity to the base-unit, and
transmit and/or receive payload data via the at least one data link following the authentication of the non-galvanic connection to a contactless unit; and
wherein the authentication controller further comprises a watchdog timer and wherein the base-unit is operable to periodically re-authenticate a non galvanic connection to a contactless-unit, the re-authentication period being determined by the watchdog timer, and to disable further payload data transmission and/or reception if the re-authentication of the non-galvanic connection fails.
8. A contactless-unit for non-galvanic coupling to a base-unit, the contactless-unit comprising:
an antenna coupled to an rf power receiver,
at least one data-link, and
an authentication controller coupled to the at least one data-link,
a data interface for coupling at least one of a data source and data sink to the contactless unit, the data interface being coupled to the at least one data-link, wherein the contactless-unit is operable to
transmit and/or receive payload data via the data interface,
receive rf power provided from a base-unit only when the base-unit is in physical proximity to the contactless-unit,
convert the received rf power to supply power to circuits in the contactless-unit,
transmit and/or receive authentication data via the at least one data-link to authenticate a non-galvanic connection to a base-unit only when a base-unit is in physical proximity to the contactless-unit, and
transmit and/or receive payload data via the at least one data link following the authentication of the non-galvanic connection to a base unit; and
wherein the authentication controller further comprises a watchdog timer and wherein the contactless-unit is operable to periodically re-authenticate a non galvanic connection to a base-unit, the re-authentication period being determined by the watchdog timer, and to disable further data transmission and/or reception if the re-authentication of the non-galvanic connection fails.
2. The base unit of
3. The base unit of
4. The base unit of
5. The base unit of
the first data-link comprises a near field communication circuit coupled to a second antenna and the base-unit is operable to
transmit and/or receive authentication data via the first data-link to authenticate a non-galvanic connection to a contactless-unit only when the contactless-unit is in physical proximity to the base-unit, and
transmit and/or receive payload data via the second data-link following the authentication of the non-galvanic connection to a contactless unit via the first data-link.
6. The base-unit of
7. The base-unit of
9. The contactless unit of
10. The contactless unit of
11. The contactless unit of
the first data-link comprises a second antenna coupled to a near field communication circuit and the contactless-unit is operable to
transmit and/or receive authentication data via the first data-link to authenticate a non-galvanic connection to a base-unit only when the base unit is placed in physical proximity to the contactless-unit, and
transmit and/or receive payload data via the second data link following the authentication of the non-galvanic connection to a base unit via the first data-link.
12. The contactless-unit of
a third data-link coupled to the authentication controller, the third data-link comprising a near field communication circuit coupled to a fourth antenna,
a fourth data-link coupled to the authentication controller, and
a fifth antenna coupled to an rf power source; wherein
the contactless-unit is further operable to
transmit rf power to a further contactless-unit in physical proximity to the contactless unit,
transmit and/or receive authentication data via the third data-link to authenticate a non-galvanic connection to a further contactless-unit only when the further contactless-unit is in physical proximity to the contactless-unit, and
transmit and/or receive data between the contactless-unit and the further contactless-unit via the fourth data link element following the authentication of the non-galvanic connection.
13. The contactless unit of
14. The contactless-unit of
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This application claims the priority under 35 U.S.C. §119 of European patent application no. 13156226.6, filed on Feb. 21, 2013, the contents of which are incorporated by reference herein.
This invention relates to an apparatus for non-galvanic connection between two or more electrical circuits.
Galvanic connectors are widely used in electronic systems. An example of a galvanic connection is a peripheral device connected via an USB cable to a host device. In the most general case the host provides power to the peripheral device via the USB cable, and bi-directional high-speed data communication takes place across the same cable; in USB2.0 a separate pair of wires is allocated to power and data transfer. The galvanic connection via a cable forms an ohmic contact allowing a high degree of communication reliability between the host and the peripheral device whence the connection is made by plugging the cable into the USB port.
However, galvanic connectors are prone to wear and tear leading to functional failure consequence for example in a USB connection due to repeatedly plugging and unplugging a USB cable, both in consumer electronics as well as in professional systems. In addition, connectors for high-speed links such as HDMI and high-pin count applications such as docking station for a laptop increase the cost of the system considerably.
Consumer electronics systems show reliability problems with galvanic connectors, for example SD memory cards that get damaged due to mechanical stress during socket insertion and ejection.
Professional applications include reconfigurable MRI scanners and systems with moving parts such as wafer steppers. In these examples there is a large amount of data to be transferred from the MRI sensor/digitizer and from the wafer stage towards a central processing unit or host, in addition to the power function. The connectors tend to get dirty and/or break after a limited operation time, increasing machine down-time and maintenance cost for equipment owners.
Physical connectors also may limit the operational design freedom in industrial production lines, for example in conveyor belt systems.
Various aspects of the invention are defined in the accompanying claims. In a first aspect there is defined a base-unit for non-galvanic coupling to a contactless-unit, the base-unit comprising an antenna coupled to a radio frequency (RF) power source, at least one data-link, an authentication controller coupled to the at least one data-link, and a data interface for coupling at least one of a data source and data sink to the base unit, the data interface being coupled to the at least one data-link wherein the base-unit is operable to transmit and/or receive payload data via the data interface, wirelessly transmit RF power from the RF power source to a contactless-unit in physical proximity to the base-unit, transmit and/or receive authentication data via the at least one data-link to authenticate a non-galvanic connection to a contactless-unit only when the contactless-unit is in physical proximity to the base-unit, and transmit and/or receive payload data via the at least one data link following the authentication of the non-galvanic connection to a contactless unit.
The replacement of the galvanic connection with a non-galvanic connection provides an increased level of robustness. The authentication controller provides an equivalent level of security as provided by a wired connection using a galvanic connector and ensures that the connection is formed between the base unit and the contactless unit only when intended. To be considered to be in physical proximity, the base unit should be within a distance of one meter of a contactless unit.
The term antenna may also be considered to include an inductor, a coil or other element capable of magnetic or electromagnetic coupling. Payload data may be considered to include any data other than data used to authenticate the connection. The term RF may include frequencies above 30 KHz.
In an embodiment of the base-unit, the authentication controller is coupled to the RF power source and the authentication controller is operable to disable RF power transmission if the authentication of the non-galvanic connection fails.
Disabling the power source in the base unit if authentication fails improves the security of the connection.
In an embodiment the authentication controller further comprises a watchdog timer, wherein the base-unit is operable to periodically re-authenticate a non galvanic connection to a contactless-unit, the re-authentication period being determined by the watchdog timer, and to disable further data transmission and/or reception if the re-authentication of the non-galvanic connection fails.
Periodically re-authenticating the connection further improves the security of the connection and provides an equivalent function to a galvanic wired connection being unplugged.
In an embodiment, the base unit may comprise at least one of a mechanical coupling element and a magnet and wherein in operation, the relative position of the base-unit and a contactless unit non-galvanically coupled to the base unit is fixed.
Embodiments of a base unit may include a mechanical connector or coupling element which plugs into a mechanical connector of a contactless unit or vice versa. This may replace a conventional galvanic connector. Alternatively a ferromagnetic material may be used to magnetically secure the base unit and contactless unit in position such that the data links are physically aligned. The alignment required may be for example alignment of a photo transmitter in a base unit and a photodetector in a contactless unit. The alignment required may be the alignment of antennas or inductive coils between a base unit and contactless unit.
In an embodiment, the at least one data link comprises a first data-link element coupled to the at least one antenna and a second data-link element, the first and second data-link elements being coupled to the authentication controller, wherein the first data-link element comprises a near field communication circuit and the base-unit is operable to transmit and/or receive authentication data via the first data-link element to authenticate a non-galvanic connection to a contactless-unit in physical proximity to the base-unit, and transmit and/or receive data between the base-unit and the contactless-unit via the second data link element following the authentication of the non-galvanic connection via the first data-link element.
In embodiments using near field communication, the authentication controller may be coupled to the RF power source and wherein the authentication controller is operable to enable the RF power transmission following the authentication of the non-galvanic connection. Sufficient power to authenticate the connection may be supplied via the near field communication (NFC) data link. Following successful authentication the main power source can be enabled. This can reduce the power consumption of the base unit and also improve the security of the non galvanic connection.
In some embodiments the data-link may comprise a laser configured for optical data transmission and a photodetector for data reception, or a millimeter wave transmitter for data transmission and a millimeter wave receiver for data reception. Data transmission via optical or millimeter waves does not require a galvanic connection. A polymer waveguide can be used as an additional pipe offering high-speed data-communication, which may be at data rates up to many gigabits per second, across longer distances between the base-unit and the contactless-unit; for these embodiments, the link may not be considered as wireless in the most general sense of the word; however there is no reliance on galvanic connections to accomplish data transfer.
In embodiments, the base-unit may include a first antenna coupled to the RF power source, a second antenna coupled to the first data link and a third antenna coupled to the second data-link and wherein the second data link element is configured for RF transmission and/or reception. The second data link may comprise a third antenna coupled to at least one of an RF transmitter and an RF receiver.
In a second aspect there is described a contactless-unit for non-galvanic coupling to a base-unit, the contactless-unit comprising an antenna coupled to an RF power receiver, at least one data-link, and an authentication controller coupled to the at least one data-link, a data interface for coupling at least one of a data source and data sink to the contactless unit, the data interface being coupled to the at least one data-link, wherein the contactless-unit is operable to transmit and/or receive payload data via the data interface, receive RF power provided from a base-unit only when the base-unit is in physical proximity to the contactless-unit, convert the received RF power to supply power to circuits in the contactless-unit, transmit and/or receive authentication data via the at least one data-link to authenticate a non-galvanic connection to a base-unit only when a base-unit is in physical proximity to the contactless-unit, and transmit and/or receive payload data via the at least one data link following the authentication of the non-galvanic connection to a base unit.
The features of the contactless unit are complementary to a base unit and allow a non-galvanic connection to transfer data and power between two or more circuits.
In an embodiment of the contactless-unit, the authentication controller further comprises a watchdog timer operable to periodically re-authenticate a non galvanic connection to a base-unit, the re-authentication period being determined by the watchdog timer, and to disable further data transmission and/or reception if the re-authentication of the non-galvanic connection fails.
In an embodiment, the contactless-unit comprises at least one of a mechanical coupling element and a magnet and wherein in operation, the relative position of the contactless-unit and a base unit non-galvanically coupled to the contactless unit is fixed.
In an embodiment of the contactless unit, the at least one data-link comprises at least one of a millimeter wave transmitter, a millimeter wave receiver, a laser, and a photodetector.
In an embodiment of the contactless-unit the at least one data link comprises a first data-link and a second data-link, the first and second data-links being coupled to the authentication controller, wherein the first data-link comprises a second antenna coupled to a near field communication circuit and the contactless-unit is operable to transmit and/or receive authentication data via the first data-link to authenticate a non-galvanic connection to a base-unit only when the base unit is placed in physical proximity to the contactless-unit, and transmit and/or receive payload data via the second data link following the authentication of the non-galvanic connection to a base unit via the first data-link.
In embodiments the contactless-unit includes a third data-link coupled to the authentication controller, the third data-link comprising a near field communication circuit coupled to a fourth antenna, a fourth data-link coupled to the authentication controller, a fifth antenna coupled to an RF power source wherein the contactless-unit is further operable to transmit RF power to a further contactless-unit in physical proximity to the contactless unit, transmit and/or receive authentication data via the third data-link to authenticate a non-galvanic connection to a further contactless-unit only when the further contactless-unit is in physical proximity to the contactless-unit, and transmit and/or receive data between the contactless-unit and the further contactless-unit via the fourth data link element following the authentication of the non-galvanic connection.
Having a third and fourth data links allows daisy chaining of a base unit and multiple contactless units
In an embodiment the contactless unit may include at least one of a sensor (and a storage element coupled to the data interface.
In an embodiment, a second data link of the contactless unit may comprise a third antenna coupled to at least one of an RF transmitter and an RF receiver.
Embodiments of the invention are now described in detail, by way of example only, illustrated by the accompanying drawings in which:
In embodiments the RF power source 14 may supply sufficient power to power a contactless unit within a range of two meters of the base unit. In further embodiments the base unit 100 may have a millimeter wave receiver instead of a millimeter wave transmitter and the contactless unit 200 may have a millimeter wave transmitter instead of a millimeter wave receiver 40. In this case the contactless unit 200 receives power from a base unit 100 in proximity to the contactless unit, and the contactless unit authentication controller 30 may transmit authentication data to the base unit 100. The base unit 100 may enable the connection between the data interface circuit 12 and the data interface 20 for transmitting any received payload data from the contactless unit 200. In some embodiments the authentication data may be periodically retransmitted either from the base unit 100 or the contactless unit 200. In some embodiments, the polymer waveguide 50 coupling the base unit 100 and contactless unit 200 may be omitted if the base unit 100 and contactless unit 200 are physically aligned such that the millimeter wave receiver can detect data transmitted by the millimeter wave transmitter. In embodiments this may be achieved by forming at least part of the base unit into a plug and forming at least part of the contactless unit into a socket or vice versa. In embodiments the base unit and contactless unit may include a magnet or ferromagnetic material and the base unit and contactless unit may be physically aligned by magnetic coupling.
In embodiments the millimeter wave transmitter may be replaced by a light emitting diode (LED) or Laser transmitter and the millimeter wave receiver may be replaced by a photo-detector. In these embodiments an optical link may be formed between a base unit and contactless unit.
In operation the base unit authentication controller 55 may enable authentication data to be sent via the base unit NFC link. When a contactless unit is in proximity to the base unit, the base unit NFC link may also provide power to the contactless unit NFC link and contactless unit authentication controller 70 in the contactless unit 400, the RF power may be disabled until after the successful authentication of the connection between the base unit 300 and the contactless unit 400. Payload data received from data interface 20 may be transmitted via the base unit data-link. Payload data received from a contactless unit 400 via the base unit data link may be transmitted to further circuitry via the data interface 20. Power may be transmitted from RF power source 14 via antenna 16. Power may be supplied to the base unit from DC power input terminal 18. Provided that the contactless unit 200 is in physical proximity with the base unit 100, the power transmitted by the RF power source may be received by the RF power receiver 34 via antenna 36. The received RF power may be used to power the circuitry in contactless unit 400.
Authentication data transmitted from the base unit NFC link may be detected and received by contactless unit NFC circuit 80. The authentication data may be received by contactless unit authentication controller 70. Contactless unit authentication controller 70 may then authenticate the connection between the base unit 300 and the contactless unit 400. Contactless unit authentication controller 70 may enable contactless unit data circuit 72 to couple further received payload data to contactless unit data interface 78. Contactless unit data interface 78 may be connected by either a galvanic or non-galvanic connection to a further circuit.
Authentication data transmitted from the contactless unit NFC link may be detected and received by base unit NFC circuit 60. The authentication data may be received by base unit authentication controller 55. Base unit authentication controller 55 may then authenticate the connection between the base unit 300 and the contactless unit 400. Base unit authentication controller 55 may enable base unit data circuit 52 to couple further received payload data to base unit data interface 20. The base unit data interface 20 may be connected by either a galvanic or non-galvanic connection to a further circuit.
Since the authentication takes place via the NFC link, the authentication process can use much lower power and frequencies than the subsequent payload data transfer.
The data link, the NFC link and the RF power link form a non-galvanic connection between the base unit 300 and the contactless unit 400. The authentication process prior to payload data transmission may be considered as equivalent to forming a galvanic connection by plugging in a connector in a conventional wired connection.
Since the NFC link only works over a short range, typically less than 50 centimeters, the connection can only be established when the base unit 300 and the contactless unit 400 are in physical proximity. In some embodiments of the base unit, the RF power circuit 54 may share an antenna or coil with NFC circuit 60. In embodiments of the contactless unit, the RF power receiver 74 may share an antenna or coil with contact-less unit NFC circuit 80. Embodiments of the base unit NFC circuit 60 may include a secure element containing the authentication data required to authenticate the connection. Embodiments of the base unit NFC circuit 60 may include a secure element containing the authentication data required to authenticate the connection.
In embodiments, the millimeter wave transceiver may be replaced by a photo-transceiver in the base unit and the contactless unit.
In operation the base unit authentication controller 55 may enable authentication data to be sent via the base unit NFC link. When a contactless unit is in proximity to the base unit, the base unit NFC link may also provide power to the contactless unit NFC link and contactless unit authentication controller 70 in the contactless unit 600, the RF power may be disabled until after the successful authentication of the connection between the base unit 500 and the contactless unit 600. Payload data received from data interface 20 may be transmitted via the base unit data link. Payload data received from a contactless unit 600 via the base unit data link may be transmitted to further circuitry via the data interface 20. Power may be transmitted from RF power source 14 via antenna 16. Power may be supplied to the base unit from DC power input terminal 18. Provided that the contactless unit 600 is in physical proximity with the base unit 500, the power transmitted by the RF power source may be received by the RF power receiver 74 via antenna 76. The received RF power may be used to power the circuitry in contactless unit 600.
Authentication data transmitted from the base unit NFC link may be detected and received by contactless unit NFC circuit 80. The authentication data may be received by contactless unit authentication controller 70. Contactless unit authentication controller 70 may then authenticate the connection between the base unit 500 and the contactless unit 600. Contactless unit authentication controller 70 may enable contactless unit data circuit 94 to couple further received payload data to contactless unit data interface 78. Contactless unit data interface 78 may be connected by either a galvanic or non-galvanic connection to a further circuit.
Authentication data transmitted from the contactless unit NFC link may be detected and received by base unit NFC circuit 60. The authentication data may be received by base unit authentication controller 55. Base unit authentication controller 55 may then authenticate the connection between the base unit 500 and the contactless unit 600. Base unit authentication controller 55 may enable base unit data circuit 92 to couple further received payload data to base unit data interface 20. The base unit data interface 20 may be connected by either a galvanic or non-galvanic connection to a further circuit.
Since the authentication takes place via the NFC link, the authentication process can use much lower power and frequencies than the subsequent payload data transfer. The data transfer speed of the NFC link may typically be 400 Kbits per second.
The data transfer speed of the base unit data link and the contactless unit data link may be up to 40 Gigabits per second. The typical data transfer speed of the base unit data link and the contactless unit data link may be in the region of 5 gigabits per second for a USB transfer. For some applications the transfer speed may be in the region of a few hundred Megabits per second.
The contactless unit 700 illustrated in
First RF transponder circuit 94 may be connected to a second RF transponder circuit 710 by flexible wiring 722. A terminal of the second RF transponder circuit 710 may be connected to a second RF transponder antenna 712. The second RF transponder circuit 710 and RF transponder antenna 712 may form a contactless unit data link. Contactless unit authentication controller 70 may be connected to second RF transponder circuit 710 by flexible wiring 722′. Contactless unit authentication controller 70 is connected to second near field communication circuit 714 by a flexible wiring 722′. The second near field communication circuit 714 may be connected to second NFC antenna 716. Second near field communication circuit 714 and antenna 716 may form a second NFC link. Contactless unit authentication controller 70 may be connected to RF power transmitter 718 by flexible wiring 722′. The RF power receiver 74 may be connected to a RF power transmitter 718 by flexible wiring 722″. RF power transmitter 718 may be connected to RF power antenna 720. In operation the contactless unit may receive power and data from a base unit 500 following successful authentication. The contactless unit 700 may then retransmit data via the second data link and may transmit power via the power transmitter following successful authentication of a further contactless unit via the second NFC link. The contactless unit may receive data via the second data link and transmit data to base unit 500. This allows potentially daisy chaining of contactless units. The contactless unit 700 may be split along the axis A into a left hand portion 700′ and a right hand portion 700″. Left hand portion 700′ and right hand portion 700″ may be able to move with respect to each other. In embodiments, contactless unit 700 may be mounted either side of a joint of a robot arm such that each portion of contactless unit can move independently. In other embodiments base unit 500 may be a PC docking station, left hand portion of contactless unit 700′ may be included in a PC and right hand portion of contactless unit 700″ may be included in a peripheral device such as a printer.
The system host 810 interacts with high data RF transponder 814, NFC circuit 828 and RF power circuit 822. High data rate RF transponder 814 may be capable of multi-gigabits per second data transfer capability. Additional features of the high data rate RF transponder 814 may be low latency, full duplex operation, and multiple channel operation. The high data rate RF transponder 814 may communicate with the system host 810 via a high-speed bidirectional digital bus. The high data rate RF transponder 814 may be configurable by parameters set in the control register 818. The control register may be controlled from the initialisation watchdog circuit 816. Initialisation watchdog circuit 816 may in turn be controlled either by system host 810 for by NFC circuit 828. Control register 818 and initialisation watchdog circuit 816 may form an authentication controller. Initialisation watchdog circuit 816 may periodically trigger a repeat of the authentication cycle. If the separation between the base unit 800 and contactless unit 900 increases beyond the range of the NFC link after the original authentication, the data transfer is disabled. This gives an equivalent functionality to unplugging a conventional wired connection with galvanic or ohmic connections.
In the contactless unit 900, the higher rate RF transponder 910 may be capable of multi-Gigabits per second data transfer capability, matching the properties of the RF transponder circuit of the base unit 800. The high data rate RF transponder 910 may be configurable by parameters set in the control register 918. The high data rate RF transponder 910 may interact with local storage elements which provide a data sink 912 and/or data source 916 function. The high data rate RF transponder 910 may further communicate with a sensor 914 and transfer the data from the sensor 914 to the base unit 800. The NFC circuit 912 may communicate with initialisation watchdog circuit 920 via a data bus. Initialisation watchdog circuit 920 may communicate with DC supply 930 to provide the DC output parameters. RF power receiver 928, RF power antenna 96, and DC supply 930 may form a wireless RF power receiver section. RF power receiver 928 may convert energy from an RF carrier into an approximate DC voltage. DC supply 930 may provide further stabilisation and conditioning of the DC signal determined by the programmable output parameters obtained from the initialisation watchdog circuit 920. The authentication protocol between base unit 800 and contactless unit 900 may be similar to that described for other embodiments.
Embodiments of base unit 800 and contactless unit 900 may be included in an MRI scanner where sensor data may be captured by the sensor digitizer 914 and transferred to a base unit 800 via the high speed RF data link.
Embodiments may include a replacement connection for a PC docking station including wireless charging pods and a multi-GBPS bidirectional data transfer function. Embodiments may include contactless USB connectors whereby at least part of the base unit is formed as part of a USB socket and at least part of a contactless unit is formed as part of a USB plug. In embodiments a contactless unit may be included on an SD memory card, which may be inserted into a slot having a base unit. Base units and contactless units may be used to simplify backplane connections for example in Internet data centres. One or more base units and contactless units may also be used in MRI scanners to replace conventional connections. In embodiments, one or more base units and contactless units may be included in a wafer stepper. In embodiments at least part of a base unit may be incorporated into an Ethernet socket. At least part of a contactless unit may be incorporated into an Ethernet plug. Embodiments of the base unit and contactless unit may be incorporated into low voltage differential signaling (LVDS) connectors, replacing the conventional galvanic or ohmic connection.
Although the appended claims are directed to particular combinations of features, it should be understood that the scope of the disclosure of the present invention also includes any novel feature or any novel combination of features disclosed herein either explicitly or implicitly or any generalisation thereof, whether or not it relates to the same invention as presently claimed in any claim and whether or not it mitigates any or all of the same technical problems as does the present invention.
Features which are described in the context of separate embodiments may also be provided in combination in a single embodiment. Conversely, various features which are, for brevity, described in the context of a single embodiment, may also be provided separately or in any suitable sub combination.
The applicant hereby gives notice that new claims may be formulated to such features and/or combinations of such features during the prosecution of the present application or of any further application derived therefrom.
For the sake of completeness it is also stated that the term “comprising” does not exclude other elements or steps, the term “a” or “an” does not exclude a plurality, a single processor or other unit may fulfill the functions of several means recited in the claims and reference signs in the claims shall not be construed as limiting the scope of the claims.
Roovers, Raf Lodewijk Jan, Vaucher, Cicero Silveira
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Feb 13 2014 | NXP B.V. | (assignment on the face of the patent) | / | |||
Feb 14 2014 | VAUCHER, CICERO SILVEIRA | NXP B V | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 032223 | /0179 | |
Feb 14 2014 | ROOVERS, RAF LODEWIJK JAN | NXP B V | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 032223 | /0179 | |
Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | CORRECTIVE ASSIGNMENT TO CORRECT THE REMOVE APPLICATION 12298143 PREVIOUSLY RECORDED ON REEL 039361 FRAME 0212 ASSIGNOR S HEREBY CONFIRMS THE SECURITY AGREEMENT SUPPLEMENT | 051029 | /0387 | |
Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | CORRECTIVE ASSIGNMENT TO CORRECT THE REMOVE APPLICATION 12298143 PREVIOUSLY RECORDED ON REEL 042985 FRAME 0001 ASSIGNOR S HEREBY CONFIRMS THE SECURITY AGREEMENT SUPPLEMENT | 051029 | /0001 | |
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Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | CORRECTIVE ASSIGNMENT TO CORRECT THE REMOVE APPLICATION 12298143 PREVIOUSLY RECORDED ON REEL 038017 FRAME 0058 ASSIGNOR S HEREBY CONFIRMS THE SECURITY AGREEMENT SUPPLEMENT | 051030 | /0001 | |
Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | CORRECTIVE ASSIGNMENT TO CORRECT THE REMOVE APPLICATION 12298143 PREVIOUSLY RECORDED ON REEL 039361 FRAME 0212 ASSIGNOR S HEREBY CONFIRMS THE SECURITY AGREEMENT SUPPLEMENT | 051029 | /0387 | |
Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | CORRECTIVE ASSIGNMENT TO CORRECT THE REMOVE APPLICATION 12298143 PREVIOUSLY RECORDED ON REEL 042985 FRAME 0001 ASSIGNOR S HEREBY CONFIRMS THE SECURITY AGREEMENT SUPPLEMENT | 051029 | /0001 | |
Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | CORRECTIVE ASSIGNMENT TO CORRECT THE REMOVE APPLICATION 12298143 PREVIOUSLY RECORDED ON REEL 042762 FRAME 0145 ASSIGNOR S HEREBY CONFIRMS THE SECURITY AGREEMENT SUPPLEMENT | 051145 | /0184 | |
Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | CORRECTIVE ASSIGNMENT TO CORRECT THE REMOVE APPLICATION 12681366 PREVIOUSLY RECORDED ON REEL 038017 FRAME 0058 ASSIGNOR S HEREBY CONFIRMS THE SECURITY AGREEMENT SUPPLEMENT | 042985 | /0001 | |
Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | CORRECTIVE ASSIGNMENT TO CORRECT THE REMOVE APPLICATION 12681366 PREVIOUSLY RECORDED ON REEL 039361 FRAME 0212 ASSIGNOR S HEREBY CONFIRMS THE SECURITY AGREEMENT SUPPLEMENT | 042762 | /0145 | |
Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | CORRECTIVE ASSIGNMENT TO CORRECT THE REMOVE APPLICATION 12092129 PREVIOUSLY RECORDED ON REEL 038017 FRAME 0058 ASSIGNOR S HEREBY CONFIRMS THE SECURITY AGREEMENT SUPPLEMENT | 039361 | /0212 | |
Feb 18 2016 | NXP B V | MORGAN STANLEY SENIOR FUNDING, INC | SECURITY AGREEMENT SUPPLEMENT | 038017 | /0058 | |
Sep 03 2019 | MORGAN STANLEY SENIOR FUNDING, INC | NXP B V | RELEASE BY SECURED PARTY SEE DOCUMENT FOR DETAILS | 050745 | /0001 |
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