Abstract: In a method for power control, a user equipment (UE) receives a path loss measurement indicator and at least one parameter sent by a base station and measures a path loss between the UE and at least one uplink serving access point of the UE according to the path loss measurement indicator. An uplink transmitting power adjustment value is calculated according to the measured path loss and the at least one parameter received from the base station. The UE adjusts uplink transmitting power according to the uplink transmitting power adjustment value.

Abstract: The present invention relates to a method for acquiring radio measurements in a mobile communication system. In accordance with one embodiment of the invention, the method comprises the steps of.—within a serving cell (A) operated by a radio access node (eNBA) and serving a particular user equipment (UEX), sending measurement control information (meas_ctrl_info) from said radio access node to said particular user equipment whereby said particular user equipment is configured to perform radio measurements,—within a further serving cell (B) operated by a further radio access node (eNBB) and subsequently serving said particular user equipment, sending a measurement report (meas_report) from said particular user equipment to said further radio access node comprising measurement data (meas_data) as configured by said serving cell and a cell identifier (PCIA) of said serving cell,—transferring said measurement data from said further radio access node back to said radio access node.

Abstract: A method and a user equipment in a network having a macro cell and at least one small cell, the method in one embodiment receiving a measurement restriction over a broadcast channel from the macro cell; and applying the restriction for a corresponding measurement at the user equipment. In one embodiment the method includes receiving a small cell list from the macro cell; and measuring at least one of a reference signal receive power and a reference signal received quality based on the received small cell list. The method includes, in one embodiment, receiving a neighboring small cell configurations from the macro cell; and utilizing the received small cell configurations to attach to a small cell. The method includes, in one embodiment, receiving an s-measure offset value over a broadcast channel from the macro cell; and applying the s-measure offset value to an s-measure for neighbor cell discovery.

Abstract: There is provided a broadcast reception mobile terminal capable of improving both electric power saving and user-friendliness includes a broadcast reception mobile terminal that is constructed to be foldable as a result of a lid body arranged to be rotated with respect to a main body, and includes a main LCD panel (202a) on an inner surface side of the lid body and a sub LCD panel (202b) on an outer surface side of the lid body. A CPU (209) detects that the lid body is opened or closed by a signal from an opening/closing detection switch. In addition, the CPU (209) obtains from an earphone connector (203) information indicating whether or not an earphone is connected. In a case that the CPU (209) detects the lid body being closed during television viewing on the main LCD panel (202a), and performing a TVOFF process if the earphone is not connected, and stopping video display but continuing output of received audio if the earphone is connected.

Abstract: A non-transitory processor-readable medium stores code to cause a processor to receive a performance indicator associated with a first mode. The code causes the processor to calculate, using the performance indicator associated with the first mode, a first metric value associated with a first metric and an objective of the first mode. The code causes the processor to calculate, using the first metric value, a second metric value associated with a second metric and an objective of a second mode. The second metric value partially compensates for a change in a performance indicator associated with the second mode when the first metric value is implemented. The code causes the processor to send a signal associated with the first metric value and a signal associated with the second metric value to an antenna module such that the antenna module implements the first metric value and the second metric value.

Abstract: The present embodiments relates to wireless adaptors. In one embodiment, a method is provided. The method may include obtaining an adaptor-device identification that identifies both a wireless adaptor and a wired device coupled with the wireless adaptor; and communicating with a network device via a wireless network using the adaptor-device identification, the wired device being distinguishable from other wired devices using the adaptor-device identification.

Abstract: Disclosed are technologies are useful in enabling a smart phone to respond to a user's environment, e.g., so it can serve as an intuitive hearing and seeing device. Some of the detailed arrangements involve using radio base station SDR equipment (e.g., at a cell tower) to perform image recognition operations for phones; forecasting service needs from remote processors delegating a remote execution task to a service provider chosen in a competitive process; using nearby processors, e.g., in an automobile, another phone, or set-top box, for remote execution tasks; phones with separable camera and/or illumination components; phone camera illumination using different colors of light; using search tree methods with image frames captured at different focuses; using a phone's microprojector to aid in object identification; correcting lens aberrations by texture mapping captured imagery onto a corrective polygon surface using a phone GPU; etc. A great variety of other features are also detailed.

Abstract: A wireless or handheld device or phone is equipped with corner sensors which control functioning of the device. The corner sensors are configured based how a user holds the handheld device while utilizing the corner sensors. The corner sensors may also be configured based on a spatial orientation of the handheld device. The corner sensors may be configured based on which hand or hands control the corner sensors, the dexterity of the fingers controlling the sensors and/or the spatial orientation of the device. The corner sensors may include a touch sensor, a trackpad and/or a pressure sensor and may detect various single sensor inputs or simultaneous gestures. The device may sense when it is held in a hand and may disable the corner sensors when it is not held.

Abstract: To enable a mobile station, when a base station carries out a measurement of a radio signal coming from an adjacent cell while suspending at least one of radio transmission to and radio reception from the mobile station when a base station's own cell is in operation, to recognize that the adjacent cell is being measured. A home base station 1 carries out a measurement of a radio signal coming from an adjacent cell while suspending at least one of radio transmission to and radio reception from a mobile station 3-1 when a base station's own cell (home cell) is in operation. Further, the home base station 1 notifies, prior to beginning the measurement, advance notice information indicating an execution of the measurement to the mobile station 3-1.

Abstract: A base station broadcasts a message saying that transmittable ranging codes are limited by antenna IDs to limit antennas and the ranging codes to be searched, thereby reducing a processing load of the search. In a cellular radio communication system in which a base station device is connected to plural antennas, and antenna IDs for identifying the antennas are transmitted from the respective antennas, the base station device broadcasts a message saying that a group of ranging codes transmittable by a terminal device is limited by the antenna IDs, the terminal device receives the message, identifies the antenna ID, selects the ranging code from the group of the ranging codes corresponding to the antenna ID, and transmits the selected ranging code.

Abstract: A method and system provides a multiple input multiple output (MIMO) antenna arrangement in a wireless communication device. A first antenna element and a second antenna element co-located within a same antenna volume are respectively coupled to first and second antenna feeds proximate to a base perimeter segment of a device chassis. The first antenna feed is at a pre-calculated distance from the second antenna feed. The second antenna element, a first MIMO antenna, is coupled to an antenna ground positioned proximate to the first antenna feed and at a pre-determined distance from the second antenna feed. A third antenna element operating as a second MIMO antenna is placed proximate to a top perimeter segment of the device chassis. The antenna arrangement achieves (a) low correlation between the MIMO antennas and (b) an acceptable or pre-determined level of antenna isolation between the first antenna element and the second antenna element.

Abstract: A portable radiotelephone can be shifted between a first condition wherein the radiotelephone does not receive or transmit voice communications by radiotelephone transmissions over radiotelephone channels and a second condition wherein the radiotelephone receives and transmits voice communications by radiotelephone transmissions over radiotelephone channels. The radiotelephone automatically calls a central voice-activated phone dialing system remote from the portable radiotelephone in response to producing the second condition in the radiotelephone. The radiotelephone includes a switch for producing the first and second conditions.

Abstract: Method for providing feedback includes detecting user input relative to a location of a display of a mobile terminal, such that the user input includes an initial region of input and an ending region of input. One operation includes generating, responsive to the user input, a first haptic feedback at a first location of a mobile terminal, such that the first location corresponds to the initial region of input. Another operation includes generating, responsive to the user input, a second haptic feedback at a second location of the mobile terminal, such that the second location corresponds to the ending region of input, and the second haptic feedback begins at a point of time that occurs after the first haptic feedback has begun.

Abstract: A mobile terminal as broadly described herein may include a first body, and a second body formed of a transparent material and attached to the first body. The second body may include a recess formed on a surface of the second body and recessed away from the first body, a transparent display provided in the recess and formed of a transparent material, and configured to display visual information thereon, and a filler material provided in the recess at a gap between the transparent display and the recess. The filler material may be formed of a transparent material.

Abstract: A mobile communication terminal and a method for operating the same are disclosed. The mobile communication terminal can be connected to first and second communication networks. The first communication network may be a legacy network and the second communication network may be a Long Term Evolution (LTE) network. The mobile communication terminal is also capable of displaying a two-dimensional (2D) image and a three-dimensional (3D) image. The mobile communication terminal reproduces a 2D image, receives a display mode switch request signal from a user, determines whether 3D image reception is available according to an environment of a current connected mobile communication network, receives a 3D image from a server, if 3D image reception is available and a 2D image from the server if 3D image reception is not available, and displays the received 3D image or 2D image.

Abstract: The present invention relates to mobile terminal technologies and describes a mobile terminal and shutdown device and a method thereof, the shutdown device comprising a power on-off key and a time delay circuit, and the shutdown device further comprising a first inductor and a first MOS tube that is connected with the main control chip; wherein the time delay circuit is used to adjust device parameters by setting a delay time. If the power on-off key is pressed for longer than the delay time, the first inductor controls the first MOS tube to cut off the connection with the main control chip, thereby shutting down.

Abstract: A wireless communication device is disclosed that is capable of reduced power consumption. Uplink and downlink sub-frames in a WiMAX, 802.16m or LTE environment often include several vacant symbols during which power-hungry hardware and software components need not operate at full power. By analyzing a physical layer beacon and control information of a received signal, the specific locations of data bursts can be determined, as well as periods of needed operation of a receiver module to effectively decode those data bursts. The receiver module can otherwise be controlled to operate in a LOW power state during remaining periods of vacant time, thereby conserving power consumption and extending battery life.

Abstract: An energy conservation module may be included in a mobile communication device that receives requests for services from application programs running in the device. For each request, the energy conservation module may determine which of different, selectable ways of performing the request is likely to be the most energy efficient. The energy conservation module may then cause the request to be performed in this most energy-efficient way. This determination may be dynamic and based on current operating conditions. Middleware between the application programs and an operating system may be included that presents various APIs to the application programs to allow them to easily invoke this functionality. The different, selectable ways of performing the services may be of any type, including different, selectable computer network interfaces (e.g., Wi-Fi and cellular) and whether a complex computation should be performed within or outside of the mobile communication device.

Abstract: The invention relates to a protective frame for a mobile communication device having a power charging port. The protective frame has a retractable frame body, including a main frame body; a sliding element for reciprocatingly sliding along a direction with respect to the main frame body between a retracted protection position where the mobile communication device is fixedly framed by the retractable frame body and a stretched auxiliary power supply position; and a fastening element for fixing the sliding element with respect to the main frame body at the retracted protection position and the stretched auxiliary power supply position. The protective frame also includes an auxiliary battery adapted for being detachably installed in the retractable frame body and electrically connected to the power charging port of the mobile communication device, when the sliding element are fixed with respect to the main frame body at the stretched auxiliary power supply position.

Abstract: A mobile terminal includes a terminal body, an antenna module coupled to the terminal body and including a radiator for transmitting and receiving radio signals, a circuit board electrically coupled to the antenna module for processing the transmitted and received radio signals, and at least one coupling member positioned proximate to and spaced from the radiator a particular distance for coupling the antenna module to the terminal body. The at least one coupling member is coupled to the radiator.

Abstract: A cell phone protector case including a front cavity to retain a cell phone. It further includes a rear recessed cavity having a recessed rear wall surrounded by a circumferential rim including a first sidewall, a second sidewall, a first width-wise wall and a second width-wise wall, the recessed rear wall having a width-wise dimension and a lengthwise dimension and extends for a depth “below the tops of the respective lengthwise sidewalls and the width-wise walls. A key unique feature is the inclusion of a sheet of drawing, sketching or artwork paper having a front surface and a rear surface dimensioned to fit within the rear recessed cavity and retained by the rear sidewalls and rear width-wise walls.

Abstract: In a terminal structure of a superconducting cable conductor, a terminal portion of the superconducting cable conductor is connected with a terminal member of a good conductor. The terminal portion includes a superconducting layer disposed on an outer periphery of a central support; and an insulating layer surrounding the superconducting layer. The insulating layer and the superconducting layer are partially removed to expose the central support and the superconducting layer in this order from an end of the superconducting cable conductor. The terminal member includes a metal sleeve which includes a first cylindrical portion whose inner surface is in close contact with an exposed portion of the central support; a second cylindrical portion which is soldered around an exposed portion of the superconducting layer; and a third cylindrical portion into which the insulating layer is inserted.

Abstract: Techniques for protecting a superconducting (SC) article are disclosed. The techniques may be realized as an apparatus for protecting a superconducting (SC) article. The apparatus may comprise a porous sleeve configured to fit around the superconducting (SC) article. The porous sleeve may be made of non-conductive, dielectric material.

Abstract: A superconducting structure (1) has a plurality of coated conductor tapes (2; 2a-2o), each with a substrate (3) which is one-sided coated with a superconducting film (4), in particular an YBCO film, wherein the superconducting structure (1) provides a superconducting current path along an extension direction (z) of the superconducting structure (1), wherein the coated conductor tapes (2; 2a-2o) provide electrically parallel partial superconducting current paths in the extension direction (z) of the superconducting structure (1), is characterized in that the coated conductor tapes (2; 2a-2o) are superconductively connected among themselves along the extension direction (z) continuously or intermittently. A more stable superconducting structure with which high electric current strengths may be transported is thereby provided.

Abstract: An object of the present invention is to provide a noninvasive constituent concentration measuring apparatus and constituent concentration measuring apparatus controlling method, in which accurate measurement can be performed by superimposing two photoacoustic signals having the same frequency and reverse phases to nullify the effect from the other constituent occupying large part of the object to be measured. The constituent concentration measuring apparatus according to the invention includes light generating means for generating two light beams having different wavelengths, modulation means for electrically intensity-modulating each of the two light beams having different wavelengths using signals having the same frequency and reverse phases, light outgoing means for outputting the two intensity-modulated light beams having different wavelengths toward a test subject, and acoustic wave detection means for detecting an acoustic wave generated in the test subject by the outputted light.

Abstract: Methods and apparatus for providing data processing and control for use in a medical communication system are provided.

Abstract: Embodiments of the invention provide analyte sensors and sensor systems such as amperometric glucose sensors used in the management of diabetes as well as optimized methods for monitoring analytes using such sensors and sensor systems.

Abstract: A microsensor and method of manufacture for a microsensor, comprising an array of filaments, wherein each filament of the array of filaments comprises a substrate and a conductive layer coupled to the substrate and configured to facilitate analyte detection. Each filament of the array of filaments can further comprise an insulating layer configured to isolate regions defined by the conductive layer for analyte detection, a sensing layer coupled to the conductive layer, configured to enable transduction of an ionic concentration to an electronic voltage, and a selective coating coupled to the sensing layer, configured to facilitate detection of specific target analytes/ions. The microsensor facilitates detection of at least one analyte present in a body fluid of a user interfacing with the microsensor.

Abstract: A catheter with a tissue property sensor provides for localization of myocardial infarction (MI) by utilizing one or more differences between properties of infarcted myocardial tissue and properties of normal myocardial tissue. The tissue property sensor is to be placed on endocardial wall or epicardial wall during catheterization to sense at least one tissue property allowing for detection of MI. In one embodiment, the tissue property sensor includes a contractility sensor and senses a tissue property in various locations on endocardial wall or epicardial wall and detects substantial changes in the tissue property that indicate a boundary between infarcted tissue and normal tissue.

Abstract: The neural interface system of one embodiment includes a cylindrical shaft, a lateral extension longitudinally coupled to at least a portion of the shaft and having a thickness less than a diameter of the shaft, and an electrode array arranged on the lateral extension and radially offset from the shaft, including electrode sites that electrically interface with their surroundings. The method of one embodiment for making the neural interface system includes forming a planar polymer substrate with at least one metallization layer, patterning on at least one metallization layer an electrode array on a first end of the substrate, patterning conductive traces on at least one metallization layer, rolling a portion of the substrate toward the first end of the substrate, and securing the rolled substrate into a shaft having the first end of the substrate laterally extending from the shaft and the electrode array radially offset from the shaft.

Abstract: A waterproof physiological signal detection device includes at least one electrode pad, a waterproof base layer, at least one water absorption unit, and a waterproof top layer. The electrode pad is positioned on a top surface of the waterproof base layer, and a first receiving compartment formed therebetween. The water absorption unit is positioned in the first receiving compartment. The water absorption unit has a top engaging the electrode pad and s a bottom engaging the waterproof base layer. The waterproof top layer overlaps the waterproof base layer and forms at least one top layer opening that corresponds to and exposes the at least one electrode pad. An undersurface of a circumference of the top layer opening overlaps a circumference of a top surface of the electrode pad with a central portion of the electrode pad projecting through the top layer opening.

Abstract: The present invention relates to an apparatus and a method for influencing and/or detecting magnetic particles in a field of view.

Abstract: In a method for determining the ventilation of a lung of an object under examination by magnetic resonance imaging, at least two first lung-representing image data sets are acquired at different intervals of the breathing phase. The density change of the lung tissue is automatically determined from the signal difference between the image signals of the first image data sets in at least one corresponding region of the first lung-representing image data set. The lung or the thorax volume is automatically determined using at least two of the first image data sets, or using at least an additional second lung-representing image data set in a breathing phase that corresponds with the breathing phase of a first image data set. The localized, quantitative ventilation of the lung is automatically calculated depending on the density change of the lung tissue and the change of the lung or thorax volume.

Abstract: A method of producing volume renderings from magnetic resonance image data in real time with user interactivity. The method comprises collecting raw magnetic resonance image (MRI) data representative of shapes within an image volume; transferring the raw MRI data to a computer; and continuously producing volume renderings from the raw MRI data in real time with respect to the act of collecting raw MRI data representative of shapes within the image volume.

Abstract: A contrast agent can be infused into a subject and a determination can be made of a VOD and/or a concentration gradient of the contrast agent in the VOD. The contrast agent can be infused in the subject using selected parameters. A correlation to a selected material can be made to determine parameters for infusion the selected material.

Abstract: The present invention is directed to a method for use in conducting cardiac MR imaging which allows for reconstruction of T1 maps, cine images and IR-prepared images from one raw data set, wherein the method comprises the following steps: a) acquisition of raw data by use of an ECG-triggered, segmented, inversion recovery (IR) -prepared Look-Locker type pulse sequence for data acquisition, wherein the pulse sequence encompasses more than one shot, wherein each shot comprises: i) an ECG-triggered inversion pulse; ii) SSFP cine data acquisition of radial segmented profiles over more than one RR-interval for a predefined acquisition duration AD; and iii) a relaxation duration RD, during which no data is acquired; b) retrospective gating of raw data by sorting acquired raw data for each RR-interval into a pre-determined number of heart phases by definition of specific time windows within the RR-intervals and sampling of raw data acquired during the time windows respectively; c) image reconstruction, wherein the r

Abstract: Apparatus and methods are described including generating a road map of a blood vessel. Subsequent to the generation of the road map, a tool is inserted into the blood vessel. While the tool is inside the blood vessel, the position of the tool is determined. The road map is modified to account for the determined position of the tool. Other embodiments are also described.

Abstract: An inventive medical imaging marker includes a base (2) composed of a non-imageable material, three spherical members (10, 11, 12) provided in a predetermined positional relationship in the base (2) and each composed of an imageable material, and auxiliary marker members (20, 21, 22) provided in the base (2) and composed of the imageable material. The auxiliary marker members (20, 21, 22) respectively have linear portions (20L, 21L, 22L) which are disposed parallel to straight lines extending through center points of the three spherical members (10, 11, 12) and each have a predetermined length sufficient to serve as a mark. The center points of the three spherical members (10, 11, 12) can be correctly identified in a captured image with reference to the linear portions (20L, 21L, 22L) of the auxiliary marker members (20, 21, 22) of the inventive medical imaging marker. Thus, reference axes can be correctly defined in the image.

Abstract: A mapping system (200) including: (a) at least one external marker (210,212,214,216) adapted for positioning outside a target (520) to define a target context; (b) at least one target marker (230) adapted for positioning with the target; (c) a data acquisition tool (221) configured to provide position coordinates for at least one data point (220) at the target (520); and (d) a registration module (300) adapted to output position coordinates of said at least one data point relative to at least a portion of the target context.

Abstract: Systems and methods that utilize optical sensors and non-optical sensors to determine the position and/or orientation of objects. A navigation system includes an optical sensor for receiving optical signals from markers and a non-optical sensor, such as a gyroscope, for generating non-optical data. A navigation computer determines positions and/or orientations of objects based on optical and non-optical data.

Abstract: The invention described herein provides systems and methods for multi-modal imaging with light and a second form of imaging. Light imaging involves the capture of low intensity light from a light-emitting object. A camera obtains a two-dimensional spatial distribution of the light emitted from the surface of the subject. Software operated by a computer in communication with the camera may then convert two-dimensional spatial distribution data from one or more images into a three-dimensional spatial representation. The second imaging mode may include any imaging technique that compliments light imaging. Examples include magnetic resonance imaging (MRI) and computer topography (CT). An object handling system moves the object to be imaged between the light imaging system and the second imaging system, and is configured to interface with each system.

Abstract: A system enables determination of at least one parameter for an injection procedure to be performed on a patient in connection with a diagnostic imaging procedure. The system includes a processor and one or more algorithms. Embodied within the algorithm(s) is a model descriptive of the propagation of a fluid within the patient from a site of injection thereof to each of at least two regions of interest thereof. The algorithm(s) permits one discrete data point from each of at least two time enhancement curves, derived via a test bolus, to be input into the model to determine values of physiological parameters associated with the patient, preferably those related to cardiopulmonary function. The algorithm(s) also allows the values of the physiological parameters to be input into the model wherein the parameter(s) of the injection procedure that will be performed on the patient at issue are determined.

Abstract: A system and method for performing off-line analysis of cardiac electrogram data, comprising: retrieving an electrogram from a memory location; identifying a first-channel group of candidate beats from at least a first channel of the electrogram; and identifying a second-channel group of candidate beats from at least a second channel of an electrogram. For each first-channel beat candidate near a second-channel beat candidate, the amplitude of the first-channel beat candidate is compared with the amplitude of a previous beat and the amplitude of a next beat on the first electrogram channel, and first-channel beat candidates that are outside of a first pre-determined range from either the previous or next beat are removed. Then first-channel beat candidates that are outside of a second pre-determined range from either the previous or next beat candidate are removed.

Abstract: Sensing is carried out from locations considerably removed from the stomach. Cooperating sensor electronics are placed at each of two wrists of the patient. The potential discomfort and inconvenience of an abdominal patch are reduced or eliminated, and alternative power sources become available.

Abstract: A cardiac-based metric is computed based upon characteristics of a subject's cardiac function. In accordance with one or more embodiments, the end of a mechanical systole is identified for each of a plurality of cardiac cycles of a subject, based upon an acoustical vibration associated with closure of an aortic valve during the cardiac cycle. The end of an electrical systole of an electrocardiogram (ECG) signal for each cardiac cycle is also identified. A cardiac-based metric is computed, based upon a time difference between the end of the electrical systole and the end of the mechanical systole, for the respective cardiac cycles.

Abstract: Disclosed is an arrhythmia-diagnosing method and device for diagnosing arrhythmias, such as fibrillation or tachycardia. The arrhythmia-diagnosing method includes the following steps: measuring (a) the heart characteristic length, and the (b) frequency and (c) conduction velocity of the cardiac electrical wave; and (d) determining the occurrence or absence of an arrhythmia by using the three parameters measured in steps (a) to (c). With this invention, it is possible to predict and diagnose an electrical wave tornado, one of the causes of arrhythmia, by using a non-dimensional parameter, to identify patients at risk of death or brain death due to an arrhythmia and to reduce the mortality of patients suffering from arrhythmias significantly.

Abstract: The present invention relates to a method for detecting contact between an injection needle of a medication delivery device and a body of a patient. The method comprises the step of generating a contact signal in response to closure of an electrical signal path comprising an exterior surface part of the injection needle, an exterior surface part of a handle of the medication delivery device and at least part of the body of the patient. The present invention further relates to a method for determining the position of insertion of the injection needle, and to the insertion depth of the injection needle.

Abstract: Embodiments of the invention provide methods for the transdermal delivery of therapeutic agents for the treatment of addictive cravings e.g., nicotine compounds for the treatment of nicotine cravings from tobacco use. An embodiment of a method for such delivery comprises positioning at least one electrode assembly in electrical communication with a patient's skin. The assembly includes a solution comprising a therapeutic agent which passively diffuses into the skin. A dose of agent is delivered from the assembly into the skin during a first period using a first current having a characteristic e.g., polarity and magnitude, to repel the agent out of the assembly. During a second period, a second current having a characteristic to attract the agent is used to retain the agent in the assembly such that delivery of agent into skin is minimized. A dose of agent may be delivered on demand by an input from the patient.

Abstract: Embodiments are directed to a medical device, such as a defibrillator, for use with an accessory capable of collecting a parameter of a patient. The medical device is capable of at least performing a basic functionality, an advanced functionality, and of defibrillating the patient. The medical device includes an energy storage module within a housing for storing an electrical charge that is to be delivered to the patient for the defibrillating. The medical device includes a processor structured to determine whether a data set received from the accessory confirms or not a preset authentication criterion about the accessory. Although when the accessory is coupled to the housing the medical device is capable of the defibrillating and the basic functionality, the medical device is capable of the advanced functionality only when the accessory is coupled to the housing and it is determined that the preset authentication criterion is confirmed. Embodiments also include methods of operation and a programmed solution.

Abstract: An automatic external defibrillator with an intelligent self-test system that ensures device readiness. The self-test system conditionally runs functional tests based on knowledge of device use, time of day, pre-programmed information, operational features and previous events. The condition of the defibrillator is indicated visually, audibly or both based on the results of the self-test performed.