Abstract: A method according to an aspect of the present invention includes receiving data through a wired connection from a medical device, transmitting the data to an intermediary device, formatting a message including the received data for transmission to a medical data server, and receiving a command from the medical data server. Commands from the medical data server can be used for the authentication, configuration, and control of the medical device, intermediary device or another device operating in conjunction with the present invention, as well as to achieve other purposes. This method can be practiced automatically to allow a medical device for a patient or other subject to be monitored without requiring the patient to manually enter information.

Abstract: A method according to an aspect of the present invention includes activating a first device in response to an event, receiving data through a wired connection from a medical device by the first device, transmitting the data to a second device by the first device, and transmitting the data from the second device to a medical data server. This method may be practiced automatically, either continuously or at set intervals, or may be initiated by someone utilizing the system. This method allows the first device to be activated only as necessary to communicate with the medical device in order to conserve battery life.

Abstract: A method according to an aspect of the present invention includes receiving data through a wired connection from a medical device, storing the data, transmitting the data to an intermediary device, and formatting a message including the received data for transmission to a medical data server. This method can be practiced automatically to allow a medical device for a patient or other subject to be monitored without requiring the patient to manually enter information. This method allows the data to be stored for any desired length of time, and/or until a particular event occurs.

Abstract: A method according to one aspect of the present invention includes receiving patient information, analyzing the patient information to identify a condition for the patient, formatting a report based on the patient information and the patient condition, and transmitting a command. Commands can be used for the authentication, configuration, and control of a medical device, intermediary device or another device operating in conjunction with the present invention, as well as to achieve other purposes. Embodiments of the present invention may be used to monitor any appropriate medical device from essentially any location from which a communications signal can be sent and received. This enables patients to enjoy an active lifestyle by not being tied to medical device monitoring equipment that is difficult or impossible to transport or having to routinely visit health care facilities.

Abstract: A method according to an aspect of the present invention includes receiving data through a wired connection from a medical device, transmitting the data to an intermediary device, and formatting a message including the received data for transmission to a medical data server. The intermediary device includes a software program configured to receive the data and process it into a format compatible with the medical data server. This method can be practiced automatically to allow a medical device for a patient or other subject to be monitored without requiring the patient to manually enter information.

Abstract: A method according to the present invention includes receiving data through a wired connection from a medical device by a mobile computing device, where the wired connection includes an adapter that communicates with the mobile computing device using a first communication format and the medical device using a second communication format. The method further includes formatting a message including the received data for transmission to a medical data server by the mobile computing device. This method may be practiced automatically, either continuously or at set intervals, or may be initiated by someone utilizing the system (such as the patient or health care provider. The mobile computing device can be a properly-equipped cellular telephone, PDA, or other a small, portable device that is easy for a patient to transport.

Abstract: A system according to one aspect of the present invention comprises a processor, a plurality of medical device transceivers, a data relay transceiver, and a memory coupled to the processor, and storing instructions. Each medical data transceiver is configured to receive data wirelessly from one or more medical devices. The processor executes the instructions in the memory to receive data from one or more medical devices using the plurality of medical device transceivers (which gathers data concerning the patient's condition), and transmits the data to an intermediary device using the data relay transceiver. This system can be implemented in a small, portable unit that is easy for a patient to transport.

Abstract: One method according to the present invention includes receiving data wirelessly from a medical device, transmitting the data to an intermediary device (such as a properly equipped mobile telephone or personal digital assistant), and formatting a message including the received data for transmission to a medical data server. The intermediary device includes software configured to receive the data and process the data into a format compatible with the medical data server. Once at the medical data server the information can be reviewed by a healthcare professional at a location remote to the patient. This method may be practiced automatically, either continuously or at set intervals, or may be initiated by someone utilizing the system (such as the patient or health care provider). The method preferably functions without the need for the patient to manually enter information into a device.

Abstract: A method according to one aspect of the present invention includes receiving patient information, analyzing the patient information to identify a condition for the patient, and formatting a report based on the patient information and the patient condition. Embodiments of the present invention may be used to monitor any appropriate medical device from essentially any location from which a communications signal can be sent and received. This enables patients to enjoy an active lifestyle by not being tied to medical device monitoring equipment that is difficult or impossible to transport or having to routinely visit health care facilities. Multiple reports can be formatted to include any desired amount and type of information, and can be transmitted selectively to any number of users.

Abstract: A system according to one aspect of the present invention comprises a processor, a plurality of device interfaces, a data relay transceiver, and a memory coupled to the processor and storing instructions. The processor executes the instructions in the memory to receive data from one or more medical devices through a wired connection coupled to at least one of the device interfaces, and transmits the data to an intermediary device using the data relay transceiver. This system can be implemented in a small, portable unit that is easy for a patient to transport.

Abstract: A method according to the present invention includes receiving data wirelessly from a medical device, transmitting the data to an intermediary device, formatting a message including the received data for transmission to a medical data server, and receiving a command from the medical data server. Commands from the medical data server can be used for the authentication, configuration, and control of the medical device, intermediary device or another device operating in conjunction with the present invention, as well as to achieve other purposes. This method can be practiced automatically to allow a medical device for a patient or other subject to be monitored without requiring the patient to manually enter information.

Abstract: A system according to one aspect of the present invention comprises a processor, a device interface, a data relay transceiver, and a memory coupled to the processor and storing instructions. The processor executes the instructions in the memory to receive data from a medical device through a wired connection using the device interface, where the data is received through an adapter coupled to the device interface and that communicates with the medical data interchange device using a first communication format and with the medical device using a second communication format. The processor further executes the instructions in the memory to transmit the data to an intermediary device using the data relay transceiver. This system can be implemented in a small, portable unit that is easy for a patient to transport.

Abstract: One method according to the present invention includes receiving data wirelessly from a plurality of medical devices, transmitting the data to an intermediary device (such as a properly equipped mobile telephone or personal digital assistant), and formatting a message including the received data for transmission to a medical data server. This method can be practiced automatically to allow a medical device for a patient or other subject to be monitored without requiring the patient to manually enter information. This method also allows for multiple different medical devices to be monitored, even where such devices each communicate on different frequencies and/or using different communication protocols.

Abstract: A method according to an aspect of the present invention includes receiving data from a plurality of medical devices through a wired connection, transmitting the data to an intermediary device, and formatting a message including the received data for transmission to a medical data server. This method can be practiced automatically to allow a medical device for a patient or other subject to be monitored without requiring the patient to manually enter information. This method also allows any number of different medical devices to be monitored, even where such devices each communicate using different wired connections and/or using different communication protocols.

Abstract: In one embodiment, a laser module comprising an optical element, a frequency converter, a selective reflector, and one or more surface-emitters, each coupled to a common substrate, wherein the emitters, the optical element, the frequency converter, and the selective reflector are positioned with respect to each other such that at least a portion of the coherent light emitted from the surface-emitters travels through the optical element, through the frequency converter and through the selective reflector. In a method embodiment, a method for frequency converting light generated by a surface-emitter, wherein the light passes through an optical element, a frequency converter, and a selective reflector, each coupled to a common substrate.

Abstract: In one embodiment, a laser module comprising an optical element, a frequency converter, a selective reflector, and one or more surface-emitters, each coupled to a common substrate, wherein the emitters, the optical element, the frequency converter, and the selective reflector are positioned with respect to each other such that at least a portion of the coherent light emitted from the surface-emitters travels through the optical element, through the frequency converter and through the selective reflector. In a method embodiment, a method for frequency converting light generated by a surface-emitter, wherein the light passes through an optical element, a frequency converter, and a selective reflector, each coupled to a common substrate.

Abstract: Described embodiments provide for an optical communications assembly or other optical assembly in which the post-dispersion optical signals are controlled in dispersive and non-dispersive directions. In one embodiment, the assembly includes an optical signal collimator configured to emit an optical signal based on an input communication signal. In addition, the assembly includes a dispersive device that receives the optical signal and disperses multiple wavelength channels of the optical signal in a dispersive direction. The assembly further includes a first light-directing device configured to control the dispersion of the multiple wavelength channels in the non-dispersive direction. A second light-directing device is provided to control dispersion in the dispersive direction.

Abstract: An imaging system 10 includes an image source providing an image having a resolution of X by Y pixels. The system also includes a digital mirror device 16 that includes an array of mirror elements. Each mirror element includes an edge that is not parallel to an edge of a neighboring mirror element. The array 16 includes fewer than X*Y mirror elements.

Abstract: Device and method for an antireflective coating to improve image quality in an image display system. A preferred embodiment comprises a first high refractive index layer overlying a reflective surface of an integrated circuit, a first low refractive index layer overlying the first high refractive index layer, a second high refractive index layer overlying the first low refractive index layer, and a second low refractive index layer overlying the second high refractive index layer. The alternating layers of high refractive index material and low refractive index material form an optical trap, allowing light to readily pass through in one direction, but not so easily in a reverse direction. The dual alternating layer topology improves the antireflective properties of the antireflective layer and permits a wide range of adjustments for manipulating reflectivity and color point.

Abstract: A method to improve an extinction ratio of an optical device, the method includes positioning at least a majority of a plurality of micro-mirrors in an off-state position. A mirror assembly includes the plurality of micro-mirrors. The method also includes selectively positioning at least one of the plurality of micro-mirrors in an on-state position. In one particular embodiment, the at least one of the plurality of micro-mirrors positioned in the on-state position operates to improve an extinction ratio of an optical device.