Abstract: Mitigating a user interface display function of a modular energy system includes receiving formatted video data at a video data converter circuit, providing differential video signaling data to the display from the video data converter circuit, providing a copy of the differential video signaling data to a processor, and determining that the differential video signaling data is changing over time. Mitigating erroneous outputs from an isolated interface includes receiving a state of a first switch of a first footswitch coupled to a first comparator and a reference voltage coupled to the first comparator, receiving the state of the first switch coupled to the first duplicate comparator and the reference voltage coupled to the first duplicate comparator, comparing the output of the first comparator with the output of the first duplicate comparator, and determining activation or deactivation of a surgical instrument coupled to the controller based on the comparison.

Abstract: Several mitigation circuits are disclosed. An audio mitigation circuit includes an audio mitigation control module configured to read a unique tone identification embedded in a digital audio signal to identify a digital audio tone. A video mitigation circuit confirms video to be displayed by a user interface. Another audio mitigation circuit is configured to process super-audible tones in an audio signal to confirm an audio asset. The disclosure also describes various methods associated with the mitigation circuits.

Abstract: A surgical platform is disclosed. The surgical platform includes a component and a regional location tracking module configured to connect with an external device and receive geographic location data from the external device and implement geographic location specific functionality based on the geographic location data received from the external device.

Abstract: Aspects of the present disclosure are presented for systems and methods for identifying characteristics of a return pad in a monopolar electrosurgical system using contact quality monitoring (CQM) and near field communication (NFC) signals. In some aspects, resistance or impedance materials are sensed that may help identify what kind of return pad is being used, including what is the structure of the pad. In some aspects, NFC signals are used to identify characteristics of the return pad. In some aspects, the grounding or return pad may include two separate materials that form an interconnecting or interwoven mesh and both act as non-active electrodes when both contact the patient. A non-zero impedance may separate conductive lines connecting the two separate materials that may be analyzed to obtain a defining signature about that is linked to structural characteristics about the return pad.

Abstract: A method for constructing a modular surgical system is disclosed. The method comprises providing a header module comprising a first power backplane segment, providing a surgical module comprising a second power backplane segment, assembling the header module and the surgical module to electrically couple the first power backplane segment and the second power backplane segment to each other to form a power backplane, and applying power to the surgical module through the power backplane.

Abstract: An energy module is disclosed. The energy module includes a hand-switch circuit, a surgical instrument interface coupled to the hand-switch circuit, and a control circuit coupled to the surgical instrument interface and the hand-switch circuit. The control circuit is configured to control the hand-switch circuit to communicate with a surgical instrument coupled to the hand-switch circuit using a plurality of communication protocols over a single wire. The control circuit is configured to control the hand-switch circuit to supply power to the instrument over the single wire.

Abstract: A modular energy system including a header module and a module. The header module includes a display screen for displaying a user interface. The header module is configured to receive data, including safety critical data, from the module, control the display screen to cause the UI to display UI content based on the received data, the UI content including safety critical UI content based on the safety critical data, and transmit the displayed safety critical UI content to the module for verification thereby. The module is configured to confirm whether the transmitted safety critical data coincides with the displayed safety critical UI content. In the event that it is determined that they do not coincide, the header module and/or the module can be configured to stop the function(s) of the module, display an alert on the display screen, and take various other actions.

Abstract: A method for constructing a modular surgical system is disclosed. The method comprises providing a header module comprising a first power backplane segment, providing a surgical module comprising a second power backplane segment, assembling the header module and the surgical module to electrically couple the first power backplane segment and the second power backplane segment to each other to form a power backplane, and applying power to the surgical module through the power backplane.

Abstract: Aspects of the present disclosure are presented for providing coordinated energy outputs of separate but connected modules, in some cases using communication protocols such as the Data Distribution Service standard (DDS). In some aspects, there is provided a communication circuit between a header or main device, a first module, and a second module, each including connection to a segment of a common backplane, where the output from a first module can be adjusted by sensing a parameter from a second module. In some aspects, the signal can pass from the first module through the header to the second module, or in other cases directly from the first module to the second module. Aspects of the present disclosure also include methods for automatically activating a bipolar surgical system in one or more of the modular systems using the DDS standard.

Abstract: A method for controlling a user interface of a modular energy system. The modular energy system comprises a header module and a display screen on which the user interface is displayed. The modular energy system can detect attachment of a first module thereto, control the user interface to display one or more first user interface elements corresponding to the first module, detect attachment of a second module to the modular energy system, control the user interface to resize the one or more first user interface elements to accommodate display of one or more second user interface elements corresponding to the second module, and control the user interface to display the one or more second user interface elements. The various UI elements can correspond to the particular module type that is being connected to the modular energy system.

Abstract: A method for controlling a user interface of a modular energy system. The modular energy system comprises a header module and a display screen on which the user interface is displayed. The modular energy system can detect attachment of a first module thereto, control the user interface to display one or more first user interface elements corresponding to the first module, detect attachment of a second module to the modular energy system, control the user interface to resize the one or more first user interface elements to accommodate display of one or more second user interface elements corresponding to the second module, and control the user interface to display the one or more second user interface elements. The various UI elements can correspond to the particular module type that is being connected to the modular energy system.

Abstract: Several mitigation circuits are disclosed. An audio mitigation circuit includes an audio mitigation control module configured to read a unique tone identification embedded in a digital audio signal to identify a digital audio tone. A video mitigation circuit confirms video to be displayed by a user interface. Another audio mitigation circuit is configured to process super-audible tones in an audio signal to confirm an audio asset. The disclosure also describes various methods associated with the mitigation circuits.

Abstract: A modular energy system for use in a surgical environment includes a plurality of functional modules including at least an initial module, a functional module, and a terminal module. Each of the plurality of modules has a module control circuit, and a local data bus. An internal data bus is composed of a serial array of the local data busses of the modules. The local data bus may includes a communication switch, a first switch data path between the communication switch and the module control circuit, a second switch data path in communication with the communication switch, and a third switch data path in communication with the communication switch. The third switch data path of a module N is in communication with a second switch data path of a module N+1. The system further includes a termination unit in communication with the third data path of the terminal module.

Abstract: A modular energy system includes modules, at least two having a transceiver timer. The modules communicate data messages over an internal bus. A first module obtains a transmission time from its transceiver timer, which it appends to the message, and transmits the appended message over the internal data bus. The second module receives the data message, obtains a receipt time from its transceiver timer, and extracts the transmission time from the message. A smart surgical system includes a plurality of surgical subsystems including a modular energy system all in mutual data communication over a system data bus. The components of the smart surgical system may each have a transceiver timer. The components of the smart surgical system transmit and receive data across the system data bus using the respective transceiver timers in a manner like the communications between the modular energy system modules.

Abstract: Mitigating a user interface display function of a modular energy system includes receiving formatted video data at a video data converter circuit, providing differential video signaling data to the display from the video data converter circuit, providing a copy of the differential video signaling data to a processor, and determining that the differential video signaling data is changing over time. Mitigating erroneous outputs from an isolated interface includes receiving a state of a first switch of a first footswitch coupled to a first comparator and a reference voltage coupled to the first comparator, receiving the state of the first switch coupled to the first duplicate comparator and the reference voltage coupled to the first duplicate comparator, comparing the output of the first comparator with the output of the first duplicate comparator, and determining activation or deactivation of a surgical instrument coupled to the controller based on the comparison.

Abstract: Systems, methods and devices for surgical procedurelization via a modular energy system are disclosed herein. In various aspects, the systems, methods and devices include an energy module, a header module communicably coupled to the energy module, and a display screen capable of rendering a graphical user interface (GUI). The GUI may be configured to display a plurality of steps that correspond with actions performed by a user while operating the modular energy system. In some aspects, the steps displayed are steps of a predetermined procedural checklist corresponding with a mental model followed by the user while performing a surgical procedure. In some aspects, the steps displayed are steps of an output verification process.

Abstract: An energy module is disclosed. The energy module includes a control circuit and a two wire interface coupled to the control circuit. The two wire interface is configured as a power source and as a communication interface between the energy module and a neutral electrode.

Abstract: An audio control system for a modular energy system. The audio control system can include a first controller and a second controller. The first controller can be configured to output an audio signal and an audio signal ID associated with the audio signal. The second controller can be coupled to the first controller and configured to receive the audio signal ID from the first controller and determine whether the audio signal ID corresponds to an expected audio signal ID.

Abstract: An audio control system for a modular energy system. The audio control system can include a first controller and a second controller. The first controller can be configured to output an audio signal and an audio signal ID associated with the audio signal. The second controller can be coupled to the first controller and configured to receive the audio signal ID from the first controller and determine whether the audio signal ID corresponds to an expected audio signal ID.

Abstract: A method for constructing a modular surgical system is disclosed. The method comprises providing a header module comprising a first power backplane segment, providing a surgical module comprising a second power backplane segment, assembling the header module and the surgical module to electrically couple the first power backplane segment and the second power backplane segment to each other to form a power backplane, and applying power to the surgical module through the power backplane.