Patent Description:
It is increasingly common for electronic devices to be used in surgical or other medical procedures. Electronic devices can provide a variety of useful benefits in this setting, but can also introduce certain challenges.

For example, electronic devices that are powered by an internal battery generally require that the battery be charged prior to use. The battery can be partially or completely drained, however, while the device is sitting on the shelf waiting to be used in a procedure. Charging the battery during the medical procedure can undesirably introduce delays and disrupt the flow of the procedure. It is also difficult to charge the battery of the electronic device while maintaining sterility of the electronic device. Attempts to minimize this problem by equipping the electronic device with a higher capacity battery result in the electronic device being larger and/or heavier. Larger devices are generally undesirable, as the available space to maneuver the device during the procedure can be limited. Similarly, heavier devices are generally undesirable, as the added weight can contribute to surgeon fatigue or reduce the ability to finely control movement and positioning of the device.

By way of further example, some electronic devices require programming with patient-specific or procedure-specific data or instructions. The step of programming the device before use can lengthen the medical procedure or disrupt the flow of the procedure. The programming step can further drain the battery, exacerbating the issues described above. Also, in the case of sterile electronic devices, it is difficult to program the device while maintaining its sterility.

As another example, once an electronic device is sterilized and/or packed in a sterile container, it generally cannot be tested, calibrated, identified, etc. without opening the sterile packaging.

<CIT> discloses a surgical instrument with a programmable control unit and methods for programming the control unit while the surgical instrument is in a sterile container. The method may comprise packaging the surgical instrument in the container and then sterilizing the surgical instrument while the surgical instrument is in the container. The method may further comprise programming the surgical instrument while the surgical instrument is in the container with a programming device positioned outside of the container.

<CIT> discloses a system and method for simultaneous charging, tracking and monitoring one or more equipments, comprising actuating a coordinator using a management server for transmitting UHF radio waves; receiving the transmitted UHF radio waves by a receiver; converting the UHF radio waves into DC power by employing an energy harvesting IC for charging a battery pack of said equipment, and simultaneously activating an RFID tag for receiving one or more operational parameters related to said equipment by employing said one or more sensors and transmitting said received one or more operational parameters by using short range data communication protocol via said coordinator.

<CIT> discloses a storable implantable medical device assembly and container for an implantable device having a charging sub-assembly. The implantable medical device has therapeutic componentry and a rechargeable power source operatively coupled to the therapeutic componentry. The charging sub-assembly having an electro-chemical power source, such as a battery, and a charging circuit operatively coupled to the electro-chemical power source. The implantable medical device and the charging sub-assembly are co-located within the container. The charging circuit of the charging sub-assembly is operatively coupled to the chargeable power source within the container to charge the rechargeable power source while the implantable medical device remains in the container. The charging sub-assembly may use inductive coupling to charge the implantable device mimicking implantable device charging following implantation.

<CIT> discloses a power transmission circuit for power transmitting oscillation signals generated in an output circuit and provided in a charger. The oscillation signals are received by a power reception part provided inside disinfected clean operation tools put inside a cup mounted on the upper part of the charger, rectification or the like being performed in a rectification/control part and a secondary battery is charged. That is, the secondary battery inside the operation tools is charged free from contamination without contacting the charger.

<CIT> discloses a handheld, sterile input device to control one or more devices in an operating room. A disposable component contains no electronics while the device's removable sensing module can be autoclaved and recharged for multiple procedures. Another configuration describes a fully autoclaveable sterile input device with a detachable control assembly that enables thorough cleaning and disinfecting prior to steam sterilization in an autoclave.

According to the present invention there is provided a system according to claim <NUM>. Optional features are recited in the dependent claims.

Systems are disclosed herein that allow for wirelessly powering and/or communicating with a sterile-packed electronic device without removing the electronic device from its sterile packaging and while maintaining the sterility of the electronic device. A base station with a power transmitter wirelessly transfers power to a power receiver of the electronic device using ultrasonic coupling. The base station or another external device can also be used to wirelessly program or interrogate the electronic device. Battery charging circuits and switching circuits for use with said systems are also disclosed.

The system includes an electronic device having a wireless power receiver and a sensor configured to detect a position or orientation of the electronic device; a sterile container in which the electronic device is disposed such that the sterile device is completely surrounded by the sterile container; and a base station having a wireless power transmitter, the wireless power transmitter being configured to transfer power through the sterile container to the wireless power receiver of the electronic device.

The electronic device can include at least one of an instrument and an implant.

The sterile container can include a graphical mark positioned with respect to the power receiver such that, when the graphical mark of the sterile container is aligned with a graphical mark of the base station, the power receiver is aligned with the power transmitter.

The base station can include a recess positioned with respect to the power transmitter such that, when the sterile container is seated in the recess, the power transmitter is aligned with the power receiver.

The sterile container can be configured to maintain the power receiver in a fixed position with respect to the sterile container.

The sterile container can include an inner blister pack in which the electronic device is disposed, an outer blister pack in which the inner blister pack is disposed, and an outer box in which the outer blister pack is disposed.

The electronic device can include a switch configured to switch between a first operating mode in which the electronic device is powered by the power receiver and a second operating mode in which the electronic device is powered by an internal battery.

The switch can be configured to switch from the first operating mode to the second operating mode automatically when the electronic device is removed from the sterile container.

The base station can include a communications interface configured to wirelessly transmit medical data to a communications interface of the electronic device, the medical data comprising at least one of patient-specific data, an operative plan, surgical correction information, and device calibration information.

The electronic device can include a communications interface configured to wirelessly transmit device data to a communications interface of the base station, the device data comprising at least one of device identification information, device diagnostic information, and device charge level information.

The power transmitter includes an ultrasonic transducer configured to generate ultrasonic waves received at an ultrasonic transducer of the power receiver to wirelessly transfer power from the base station to the electronic device.

The power transmitter can include a primary coil configured to generate a magnetic field between the primary coil and a secondary coil of the power receiver to wirelessly transfer power from the base station to the electronic device.

The power transmitter can include an electrode configured to generate an electric field between the electrode and an electrode of the power receiver to wirelessly transfer power from the base station to the electronic device.

The power receiver can include a full wave rectifier that rectifies an AC signal received at the power receiver and applies the signal to a capacitor of the electronic device wired in parallel with a battery of the electronic device to charge the battery.

The present invention further provides systems as claimed.

The system will be more fully understood from the following detailed description taken in conjunction with the accompanying drawings, in which:.

Systems and methods are disclosed herein that can allow for wirelessly powering and/or communicating with a sterile-packed electronic device without removing the electronic device from its sterile packaging and while maintaining the sterility of the electronic device. A base station with a power transmitter wirelessly transfers power to a power receiver of the electronic device, using ultrasonic coupling. The base station or another external device can also be used to wirelessly program or interrogate the electronic device. Battery charging circuits and switching circuits for use with said systems and methods are also disclosed.

Certain exemplary configurations will now be described to provide an overall understanding of the principles of the structure, function, manufacture, and use of the systems and methods disclosed herein. One or more examples of these configurations are illustrated in the accompanying drawings. Those of skilled in the art will understand that the systems and methods specifically described herein and illustrated in the accompanying drawings are nonlimiting exemplary configurations and that the scope of the present invention is defined solely by the claims. The features illustrated or described in connection with one exemplary configuration may be combined with the features of other configurations. Such modifications and variations are intended to be included within the scope of the present invention.

<FIG> illustrates an exemplary system <NUM> for wirelessly powering or communicating with an electronic device. The system <NUM> generally includes a base station <NUM> with a power transmitter configured to wirelessly transmit power to an electronic device <NUM> with a corresponding power receiver. According to a first aspect of the disclosure, an ultrasonic system is employed to wirelessly transfer power to the electronic device. As detailed below and as is useful as background information to the disclosure that can be used in addition to the claimed invention, various systems can be employed for wirelessly powering the electronic device, including inductive, capacitive, and ultrasonic systems. According to the first aspect, the base station includes a communications unit for wirelessly communicating with a corresponding communications unit of the electronic device. Accordingly, the base station can transmit programming information to the electronic device, receive diagnostic or identification information from the electronic device, or communicate in other ways with the electronic device.

The electronic device <NUM> can be sterilized and is packed in a sterile container <NUM>. It will be appreciated that any of a variety of containers for maintaining a sterile barrier between the electronic device and the surrounding environment can be used. The container <NUM> can be fluid-tight, air-tight, and/or liquid-tight. The sterile container <NUM> is configured to completely surround the electronic device <NUM>. The sterile container can encase the electronic device <NUM>, for example, such that the electronic device is disposed in an enclosed, sealed volume defined by the sterile container. In some configurations, the sterile container <NUM> is not formed by living tissue. The sterile container <NUM> can be separate and distinct from an outermost housing of the electronic device <NUM>.

In the illustrated configuration, the sterile container <NUM> includes an inner blister pack <NUM>, an outer blister pack <NUM>, and an outer box <NUM>. The outer box <NUM> is generally not sterile and is used for general shipping and handling of the electronic device <NUM> leading up to its use in a medical procedure. Exemplary outer boxes are formed from cardboard or paper. The blister packs <NUM>, <NUM> each include a tray that is bonded or adhered to a lid to define a closed interior volume. The tray and the lid can be formed from any of a variety of materials, including plastic or foil. The interior of the outer blister pack <NUM> is sterile, while the exterior of the outer blister pack is generally not sterile. The inner blister pack <NUM> is sterile on the exterior such that it can be handled in a sterile field. The inner blister pack <NUM> is also sterile on the interior, as is the electronic device <NUM> contained therein. In use, the outer box <NUM> is typically removed and the electronic device <NUM> is staged for the medical procedure in the inner and outer blister packs <NUM>, <NUM>. The outer blister pack <NUM> is then opened and the sterile inner blister pack <NUM> is dropped into the sterile field. Finally, the inner blister pack <NUM> is opened in the sterile field and the sterile electronic device <NUM> contained therein is removed for use in the procedure.

In some configurations (e.g., the inductive and capacitive systems described below), it can be important to maintain precise alignment between the transmitter and receiver to maximize power transfer efficiency. To facilitate alignment, the base station <NUM> can include a perimeter rim or other surface recesses or projections <NUM>. The geometry of these alignment features can be selected to correspond to that of the sterile package <NUM> of the electronic device <NUM> with which the base station <NUM> is to be used. The sterile package <NUM> can also have internal baffles or cutouts <NUM>, e.g., as shown in <FIG>, configured to maintain the electronic device <NUM> contained therein in a fixed position relative to the sterile packaging. Accordingly, simply placing the sterile package <NUM> within the contour defined by the base station <NUM> can ensure that the transmitter and receiver are precisely aligned. Alternatively, or in addition, the electronic device <NUM> or its sterile packaging <NUM> can include a graphical marking <NUM> that can be aligned by the user with a corresponding graphical marking <NUM> on the base station <NUM> to ensure that the transmitter and receiver are aligned (e.g., as shown in <FIG>).

The electronic device can take various forms. Exemplary electronic devices include implants, surgical instruments, diagnostic instruments, durable medical equipment, and the like. The electronic device can be or can include surgical electronic modules of the type described in <CIT> and entitled "SYSTEMS AND METHODS FOR INTRAOPERATIVELY MEASURING ANATOMICAL ORIENTATION,", said modules being adapted in accordance with the teachings herein.

An exemplary electronic device <NUM> is schematically illustrated in <FIG>. As shown, the electronic device <NUM> includes a power receiver <NUM> and can include a processor <NUM>, a memory <NUM>, a power source <NUM>, and a communications interface <NUM>, any one or more of which can be in communication with each other. The electronic device <NUM> can also include other features not shown in <FIG>, such as a display, buttons or other user interface elements. The electronic device <NUM> includes a sensor for sensing a position and orientation of the electronic device. Exemplary sensors can include an accelerometer, a gyroscopic sensor, a geomagnetic sensor, and ultrasound, electromagnetic, and/or infrared transceivers for communicating with a positioning system, as well as temperature sensors, pressure sensors, strain sensors, and biosensors.

The processor <NUM> can include a microcontroller, a microcomputer, a programmable logic controller (PLC), a field-programmable gate array (FPGA), an application specific integrated circuit (ASIC), integrated circuits generally referred to in the art as a computer, and other programmable circuits, and these terms are used interchangeably herein. The processor <NUM> can be configured to control operation of the electronic device <NUM>, for example by executing instructions stored in the memory <NUM> or by performing calculations or evaluations based on data output from a sensor or received via the communications interface <NUM>.

The processor <NUM> can be coupled to the memory <NUM>, which can include a random access memory (RAM), a read-only memory (ROM), a flash memory, a non-transitory computer readable storage medium, and so forth. The memory <NUM> can store instructions for execution by the processor <NUM> to implement the functionality of the electronic device <NUM>. The memory <NUM> can also store information sensed by a sensor, the result of calculations performed by the processor <NUM>, or information received from an external device through the communications interface <NUM>.

The power source <NUM> can be configured to provide power to the various electronic components of the device <NUM>. The power source <NUM> can include an internal battery, which can be a lithium-ion battery or any other battery known in the art, or other power storage devices such as capacitor arrays and the like.

The communications interface <NUM> can be configured to receive information from an external device or to transmit information to an external device. For example, the communications interface <NUM> can permit two-way communication with the base station <NUM>, or with other external devices. The communications interface <NUM> can be wireless (e.g., near-field communication (NFC), Wi-Fi, Bluetooth, Bluetooth LE, ZigBee, and the like) or wired (e.g., USB or Ethernet). In the case of NFC, for example, the electronic device <NUM> can include a radio transceiver configured to communicate with a radio transceiver of another device, e.g., the base station <NUM> or a second electronic device, using one or more standards such as ISO/IEC <NUM>, FeliCa, ISO/IEC <NUM>, and those defined by the NFC Forum. The communication interface <NUM> can be selected to provide the desired communication range. In some configurations, Bluetooth (e.g., class <NUM> Bluetooth having a range of <NUM>-<NUM> meters) can be used for the communication interface <NUM> to allow the electronic device <NUM> to remain somewhat distant from the device with which it is communicating, e.g., the base station <NUM>, while at the same time limiting the communication range such that other electronic devices unlikely to be used in the surgery are not needlessly involved.

The communications interface <NUM> can be integrated with or coupled to the power receiver <NUM> such that information can be embedded or encoded in the wireless power signal received and/or sent by the electronic device <NUM>. For example, information can be communicated to or from the electronic device <NUM> by encoding the information in the wireless power signal using frequency modulation, frequency-domain multiplexing, frequency shift keying, amplitude modulation, phase modulation, analog or digital modulation techniques, and/or combinations thereof. The communications interface <NUM> can include filters or other circuit elements for extracting information from the power signal or embedding information in the power signal.

The power receiver <NUM> is configured to receive wireless power from the base station <NUM>.

It will be appreciated that any one or more of the above components can be omitted from the electronic device <NUM>, and the electronic device can include more components than what is shown in <FIG>. In another exemplary configuration, the electronic device <NUM> can include a motor, a power source, and a power receiver.

An exemplary base station <NUM> is also shown schematically in <FIG>. As demonstrated by the illustrated configuration, the base station <NUM> includes a power transmitter <NUM> and can include a processor <NUM>, a memory <NUM>, a power source <NUM>, and a communications interface <NUM>, any one or more of which can be in communication with each other. The base station <NUM> can also include other features not shown in <FIG>, such as a display, buttons, or other user interface elements.

The processor <NUM> can include a microcontroller, a microcomputer, a programmable logic controller (PLC), a field-programmable gate array (FPGA), an application specific integrated circuit (ASIC), integrated circuits generally referred to in the art as a computer, and other programmable circuits, and these terms are used interchangeably herein. The processor <NUM> can be configured to control operation of the base station <NUM>, for example by executing instructions stored in the memory <NUM> or by performing calculations or evaluations based on data received via the communications interface <NUM>.

The processor <NUM> can be coupled to the memory <NUM>, which can include a random access memory (RAM), a read-only memory (ROM), a flash memory, a non-transitory computer readable storage medium, and so forth. The memory <NUM> can store instructions for execution by the processor <NUM> to implement the functionality of the base station <NUM>. The memory <NUM> can also store the result of calculations performed by the processor <NUM>, or information received from an electronic device <NUM> through the communications interface <NUM>.

The power source <NUM> can be configured to provide power to the various electronic components of the base station <NUM>. The power source <NUM> can include an internal battery, which can be a lithium-ion battery or any other battery known in the art, other power storage devices such as capacitor arrays and the like, or an external power source coupled to the base station <NUM> via an adaptor, e.g., via a USB port, AC adapter/transformer, wall charger, etc..

The communications interface <NUM> can be configured to receive information from an external device or to transmit information to an external device. For example, the communications interface <NUM> can permit two-way communication with the electronic device <NUM>, or with other external devices. The communications interface <NUM> can be wireless (e.g., near-field communication (NFC), Wi-Fi, Bluetooth, Bluetooth LE, ZigBee, and the like) or wired (e.g., USB or Ethernet). In the case of NFC, for example, the base station <NUM> can include a radio transceiver configured to communicate with a radio transceiver of another device, e.g., the electronic device <NUM>, using one or more standards such as ISO/IEC <NUM>, FeliCa, ISO/IEC <NUM>, and those defined by the NFC Forum. The communication interface <NUM> can be selected to provide the desired communication range. In some configurations, Bluetooth (e.g., class <NUM> Bluetooth having a range of <NUM>-<NUM> meters) can be used for the communication interface <NUM> to allow the base station <NUM> to remain somewhat distant from the device with which it is communicating, e.g., the electronic device <NUM>, while at the same time limiting the communication range such that other electronic devices unlikely to be used in the surgery are not needlessly involved.

The communications interface <NUM> can be integrated with or coupled to the power transmitter <NUM> such that information can be embedded or encoded in the wireless power signal received and/or sent by the base station <NUM>. For example, information can be communicated to or from the base station <NUM> by encoding the information in the wireless power signal using frequency modulation, frequency-domain multiplexing, frequency shift keying, amplitude modulation, phase modulation, analog or digital modulation techniques, and/or combinations thereof. The communications interface <NUM> can include filters or other circuit elements for extracting information from the power signal or embedding information in the power signal.

The power transmitter <NUM> is configured to transmit wireless power to the electronic device <NUM>.

It will be appreciated that any one or more of the above components can be omitted from the base station <NUM>, and the base station can include more components than what is shown in <FIG>.

According to the first aspect of the disclosure, an ultrasonic system is employed to wirelessly transfer power to the electronic device, as shown in <FIG>. As detailed below and as is useful as background information to the disclosure that can be used in addition to the claimed invention, <FIG> illustrate exemplary systems that can be used to wirelessly transfer power from the base station <NUM> to the electronic device <NUM> or, in some configurations, from the electronic device to the base station. While inductive, capacitive, and ultrasound wireless power transfer schemes are described below, it will be appreciated that other schemes can be used in addition to ultrasound wireless power, such as electromagnetic radiation, resonant inductive coupling, magnetodynamic coupling, microwaves, radio waves, lasers, infrared or visible light waves, and so forth. It will further be appreciated that the system <NUM> can employ multiple of these schemes, operating in combination with one another.

<FIG> illustrates an exemplary power transfer scheme in which the power transmitter <NUM> of the base station <NUM> uses inductive coupling to provide power to the power receiver <NUM> of the electronic device <NUM>.

As shown, the base station <NUM> generally includes an inverter <NUM> that converts a DC input provided by the power source <NUM> into an AC signal which is in turn applied to a primary coil <NUM> to generate an oscillating magnetic field. The electronic device <NUM> includes a secondary coil <NUM> in which an AC signal is induced by the magnetic field generated at the primary coil <NUM>. The AC signal is converted by a rectifier <NUM> to a DC output that can be used to power the processor <NUM>, memory <NUM>, communications interface <NUM>, or other components of the electronic device <NUM>, or to charge a battery <NUM> of the electronic device. When the base station <NUM> is coupled to an AC mains current or other source of AC power, the inverter <NUM> can be omitted and the AC power can be applied directly to the primary coil <NUM>. The electronic device <NUM> and/or the base station <NUM> can include transformers for increasing or decreasing voltage, or various other circuit elements for power conditioning, voltage division, voltage regulation, etc..

<FIG> illustrates an exemplary power transfer scheme in which the power transmitter <NUM> of the base station <NUM> uses capacitive coupling to provide power to the power receiver <NUM> of the electronic device <NUM>.

As shown, the base station <NUM> generally includes one or more electrodes <NUM> that can be positioned in proximity to and in alignment with one or more corresponding electrodes <NUM> of the electronic device <NUM>. A DC input provided by the power source <NUM> can be converted by an inverter <NUM> into an AC signal which is in turn applied to the electrodes <NUM> of the base station <NUM>. When the AC signal is applied to each electrode <NUM>, an electric field forms between the electrode and its counterpart electrode <NUM> in the electronic device <NUM>, effectively forming a capacitor. An AC signal is formed at the electrode <NUM> of the electronic device <NUM> by electrostatic induction, which is then converted by a rectifier <NUM> to a DC output that can be used to power the processor <NUM>, memory <NUM>, communications interface <NUM>, or other components of the electronic device <NUM>, or to charge a battery <NUM> of the electronic device. When the base station <NUM> is coupled to an AC mains current or other source of AC power, the inverter <NUM> can be omitted and the AC power can be applied directly to the electrodes <NUM>. The electronic device <NUM> and/or the base station <NUM> can include transformers for increasing or decreasing voltage, or various other circuit elements for power conditioning, voltage division, voltage regulation, etc..

<FIG> illustrates an exemplary power transfer scheme in which the power transmitter <NUM> of the base station <NUM> uses ultrasound to provide power to the power receiver <NUM> of the electronic device <NUM>.

As shown, the base station <NUM> generally includes a transducer configured to emit mechanical waves in response to an electric potential applied thereto by the power source <NUM>. The transducer includes a piezoelectric element or crystal <NUM>. The piezoelectric element <NUM> can be a single element or a phased array of elements. The piezoelectric element <NUM> can be coupled to an exterior wall of the base station chassis by a matching layer <NUM>. The matching layer <NUM> can be configured to improve ultrasound transmission by reducing or eliminating the impedance mismatch between the piezoelectric element <NUM> and the sterile packaging <NUM>, the air gap between the base station <NUM> and the electronic device <NUM>, and the exterior walls of the base station and electronic device. The piezoelectric element <NUM> can also be mounted to a backing layer <NUM> to support and dampen the piezoelectric element.

The electronic device <NUM> can include a transducer configured to produce an electric potential when excited by ultrasound waves generated by the transducer of the base station <NUM>. The transducer of the electronic device <NUM> can include any of the features of the transducer of the base station <NUM>, including a matching layer <NUM>, a piezoelectric element <NUM>, and a backing layer <NUM>. The output voltage generated at the transducer of the electronic device <NUM> can be rectified by a rectifier <NUM> and used to power the processor <NUM>, memory <NUM>, communications interface <NUM>, or other components of the electronic device, or to charge a battery <NUM> of the electronic device. The electronic device <NUM> and/or the base station <NUM> can include transformers for increasing or decreasing voltage, or various other circuit elements for power conditioning, voltage division, voltage regulation, etc..

Ultrasonic power transfer can advantageously allow the electronic device to be wirelessly powered at greater distances and can be more tolerant of misalignment between the transmitter and receiver. Ultrasound can also be used to transfer power to a plurality of electronic devices simultaneously using a single base station.

In some configurations, wireless power can be transferred to the power receiver <NUM> of the electronic device <NUM> from a source other than the base station <NUM>.

In some configurations, the power receiver <NUM> can include a solar or light-based charging unit, such as a photovoltaic cell, configured to convert photonic energy from the sun or other sources into electrical current for powering the electronic device <NUM>. At least a portion of the sterile container <NUM> can be transparent, translucent, or otherwise configured to allow passage of light through the sterile container to the power receiver <NUM> of the electronic device <NUM>. For example, the sterile container <NUM> can include a transparent or translucent window aligned with the power receiver <NUM> of an electronic device <NUM> contained within the sterile container. The base station <NUM> can include a light source configured to deliver photonic energy through the sterile container <NUM> to the power receiver <NUM> of the electronic device <NUM>.

<FIG> illustrates an exemplary configuration of a battery charging circuit that can be included in the electronic device <NUM>. As shown, the AC output of the power receiver <NUM> (e.g. a coil, an electrode, and/or a transducer) can be applied to a full-wave rectifier <NUM> to convert the AC output to a constant polarity signal which is then applied to one or more capacitors <NUM> configured to store electrical energy and slowly dissipate power into the battery <NUM> of the electronic device <NUM> to charge the battery. The illustrated circuit can advantageously yield a higher average output voltage and provide more consistent and efficient battery charging. The illustrated circuit can be used with any of the power transfer schemes discussed above.

<FIG> illustrate an exemplary configuration of a switching circuit that can be included in the electronic device <NUM>. The switching circuit can include a switch <NUM> configured to change the circuit between first and second operating modes.

As shown in <FIG>, the switch <NUM> can be disposed in a first position to place the circuit in a first operating mode. In the first operating mode, power from the power receiver <NUM> is supplied through the switch <NUM> to the processor <NUM> of the electronic device <NUM> to allow for operation or programming of the electronic device. Power from the power receiver <NUM> is also supplied through the switch <NUM> to a relay, transistor, or other switch <NUM> that can be selectively actuated by the processor <NUM> via a control line <NUM>. The processor <NUM> can actuate the relay <NUM> to allow power from the power receiver <NUM> to pass through the relay to the battery <NUM> such that the battery can be charged. The processor <NUM> can also actuate the relay <NUM> to disconnect the battery <NUM> from the power receiver (e.g., when the battery is fully charged). The electronic device <NUM> can include a sense circuit for detecting the charge level of the battery <NUM>, and the processor <NUM> can be configured to automatically switch the relay <NUM> to allow the battery to be charged from the power receiver <NUM> when the sense circuit determines that the battery charge is below a predetermined threshold level. For example, the electronic device <NUM> can include a voltage divider <NUM> that allows the processor <NUM> to take readings of the battery voltage and thereby detect the charge level of the battery <NUM>.

As shown in <FIG>, the switch <NUM> can be disposed in a second position to place the circuit in a second operating mode. In the second operating mode, the power receiver <NUM> is disconnected from the processor <NUM>, the battery <NUM>, and the other components of the electronic device <NUM>. In addition, power from the battery <NUM> is supplied through the switch <NUM> to the processor <NUM> to allow for operation or programming of the electronic device <NUM>. The processor <NUM> can continue to monitor the battery charge, e.g., via the voltage divider <NUM>, and trigger a notification to the user when the battery charge drops below a predetermined threshold.

The switch <NUM> can be a manual switch actuated by a user (e.g., when the electronic device <NUM> is first removed from its sterile packaging <NUM> or when the electronic device is ready to be used). The switch <NUM> can also be an automatic switch configured to automatically toggle upon occurrence of a triggering event (e.g., removal of the electronic device <NUM> from its sterile packaging <NUM>). Exemplary switches include toggle switches, pushbutton switches, pressure switches, proximity switches, temperature switches, and so forth. The electronic device <NUM> can be shipped from the manufacturer or other source with the switch <NUM> toggled to the first operating mode, such that the electronic device can be wirelessly powered and/or charged without removing the electronic device from its sterile package <NUM> or otherwise toggling the switch. Once the electronic device <NUM> is removed from its sterile package <NUM> and ready to be used in a procedure, or at any other desired time, the switch <NUM> can be toggled to the second operating mode to allow the device to be powered by its internal battery <NUM>.

The systems described herein can be used in various ways to facilitate a medical, surgical, or other procedure.

In some configurations, a sterile packed electronic device can be positioned on or near the base station and power can be transferred wirelessly from the base station to the electronic device. When wireless power is applied to the electronic device, the power can be used to charge an on-board battery of the electronic device. Accordingly, the battery of the electronic device can be fully charged in anticipation of a procedure, without opening the sterile packaging of the electronic device.

In some configurations, a sterile packed electronic device can be positioned on or near the base station and power can be transferred wirelessly from the base station to the electronic device. When wireless power is applied to the electronic device, the processor of the electronic device can automatically wake and selectively couple a battery of the electronic device to the power receiver to charge the battery (e.g., based on a detected charge level of the battery).

In some configurations, a sterile packed electronic device can be positioned on or near the base station and power can be transferred wirelessly from the base station to the electronic device. When wireless power is applied to the electronic device, the processor of the electronic device can automatically wake and activate the communications interface of the electronic device. The electronic device can then communicate with the base station or some other external device.

The communication can include transferring patient data to the electronic device to pre-program the device for a procedure.

The communication can include transferring procedure-specific data (e.g., a preoperative plan or surgical correction information) to the electronic device to pre-program the device for a procedure.

The communication can include transferring operating software or firmware to the electronic device (e.g., for field upgrades of the electronic device's programming).

The communication can include executing a diagnostic routine by the processor of the electronic device and transferring the result of the diagnostic routine to the base station or another external device.

The communication can include transferring identification information of the electronic device to the base station or another external device.

The base station can be used to communicate with an electronic device after the electronic device is removed from a sterile container. For example, the base station can communicate with the electronic device after a medical procedure is performed. The base station can download measurements taken during the procedure, system diagnostic reports, and/or other information from the electronic device. Power for the communication can be provided wirelessly, which can allow the communication to occur with or without a battery of the electronic device being installed.

Before any of the above methods are performed, or at any other desired time, the electronic device can be sterilized and/or sealed in a sterile container. After any of the above methods are performed, or at any other desired time, the electronic device can be used in medical procedure, a surgical procedure, or some other procedure.

The systems and methods disclosed herein can, in at least some configurations, provide for a number of advantages. For example, by providing a way to wireless charge an electronic device, the device's battery can be made smaller and the size and/or weight of the electronic device can be reduced. As another example which is useful as background information to the disclosure, surgeons can use preoperative planning software and then download information into a sterile packed electronic device that is then brought to the operating room, opened using standard precautions, and delivered into the sterile field fully charged and containing data to perform the desired procedure.

Systems and methods disclosed herein can provide the ability for transfer of data (patient, product, or otherwise) to an electronic device while the device is still sterile packed without violating the sterile package or draining the packaged battery. This can reduce the need for operating room programming of devices which can improve both speed and flow in the operating room. This can also allow for patient specific data to be entered into "universal" electronic devices without compromising the package integrity.

Systems and methods disclosed herein can ensure that the charge/power of pre-packaged sterile electronic devices are ready for use. Battery transfer and battery life can be a frequent challenge for any electronic device utilized within the sterile field. Having a means to ensure that the device is fully charged prior to use in the operating room can prevent frustration and improve speed and ease of use.

In some instances, it can be desirable that the electronic device be powered outside the sterile field for identification and calibration. Systems and methods disclosed herein can maintain sterility while still allowing device setup well in advance of a procedure. Having a means to ensure that the device is set up and calibrated prior to use in the operating room can reduce wound exposure time, reduce number of steps, reduce setup errors, reduce frustrations, and improves speed and ease of use.

Systems and methods disclosed herein can allow power charging of sterile devices on the back-table of the operating room after being turned on for connection and calibration. Such systems can, in some configurations, be switched through a relay or other device to battery power only when the device is brought into the sterile field. This can improve device use time, battery life, and power-management for long or unusual surgical cases.

Systems and methods disclosed herein can be used for incoming inspection of sterile finished packages from OEMs before the packages are accepted as inventory. In other words, systems and methods can allow for quick testing of devices inside the sterile pack for any malfunctions before the devices are distributed to users, which can improve out-of-the-box failure rate.

While use in medical and surgical procedures is generally contemplated herein, it will be appreciated that the systems and methods herein can be used for any of a variety of non-medical and/or non-surgical procedures.

Claim 1:
A system, comprising:
a surgical electronic device (<NUM>) having a wireless power receiver (<NUM>) and a sensor configured to detect a position or orientation of the electronic device (<NUM>);
a sterile container (<NUM>) in which the electronic device (<NUM>) is disposed such that the electronic device (<NUM>) is completely surrounded by the sterile container (<NUM>); and
a base station (<NUM>) having a wireless power transmitter (<NUM>), the wireless power transmitter (<NUM>) being configured to transfer power through the sterile container (<NUM>) to the wireless power receiver (<NUM>) of the electronic device (<NUM>),
wherein the base station (<NUM>) and the electronic device (<NUM>) each include a communications unit, and wherein the communications unit of the base station (<NUM>) is configured to wirelessly communicate with the communications unit of the electronic device (<NUM>),
characterised in that the electronic device (<NUM>) is configured to, upon alignment of the power receiver (<NUM>) with the power transmitter (<NUM>) and upon receiving wireless power from the base station (<NUM>), automatically initiate wireless communications with the base station (<NUM>) for receiving medical data from the base station (<NUM>), and
wherein the power transmitter (<NUM>) comprises an ultrasonic transducer configured to generate ultrasonic waves received at an ultrasonic transducer of the power receiver (<NUM>) to wirelessly transfer power from the base station (<NUM>) to the electronic device (<NUM>).