Abstract: A system and method for growing and maintaining biological material including producing a protein associated with the tissue, selecting cells associated with the tissue, expanding the cells, creating at least one tissue bio-ink including the expanded cells, printing the at least one tissue bio-ink in at least one tissue growth medium mixture, growing the tissue from the printed at least one tissue bio-ink, and maintaining viability of the tissue.

Abstract: An autonomous vehicle having sensors advantageously varied in capabilities, advantageously positioned, and advantageously impervious to environmental conditions. A system executing on the autonomous vehicle that can receive a map including, for example, substantially discontinuous surface features along with data from the sensors, create an occupancy grid based upon the map and the data, and change the configuration of the autonomous vehicle based upon the type of surface on which the autonomous vehicle navigates. The device can safely navigate surfaces and surface features, including traversing discontinuous surfaces and other obstacles.

Abstract: An integrated circuit having Radio Frequency Identification components and circuitry used for authentication is discussed. The RFID components and circuitry include two or more coils and corresponding electrical circuits that are tuned to use two or more different resonant frequencies including: a first resonant RF used for power generation and a second resonant RF used for data communication. The integrated circuit contains a unique signature that is used for the authentication with two or more aspects including i) a first aspect that is a programmed password in a memory embedded on the integrated circuit, and ii) a second aspect that is a unique, randomly generated code based upon a physical characteristic of the integrated circuit.

Abstract: A device includes a substrate, an array of metal pads on a first surface of the substrate, a carbon polymer composite covering the array of metal pads, the composite having variations that result in random resistance values between the metal pads usable as a random code. A method of manufacturing a secure device, including forming an array of metal pads on a dielet substrate, the dielet substrate containing at least one memory in which is stored an encryption key, and an RF communication section, covering the array of metal pads with a carbon polymer composite such that variations in the carbon concentration in the polymer forms a unique pattern of resistance, attaching the dielet substrate to a host component, receiving a request from a security server for a unique code determined by the unique pattern of resistance, and using the encryption key, encrypting and providing the unique code to the security server.

Abstract: Manufacturing integrated circuits is discussed with steps as follows. Creating a wafer with a plurality of dies, where each die contains its own integrated circuit. Fabricating multiple instances of TAP circuitry located in a margin between dies of the wafer. Fabricating on the wafer one row of test pads and power pads per group of dies on the wafer, where the row of test pads and power pads is electrically connected and shared among all of the dies in the group. The test and power pads connect to a chain of TAP circuitry in order to supply operating power as well as testing data to verify the integrity of each die in that group of dies. Singulating the dies to create each instance of the integrated circuit, and during the singulation process, the TAP circuitry located in the margin between the dies is destroyed.

Abstract: An integrated circuit having Radio Frequency Identification components and circuitry used for authentication is discussed. The RFID components and circuitry include two or more coils and corresponding electrical circuits that are tuned to use two or more different resonant frequencies including: a first resonant RF used for power generation and a second resonant RF used for data communication. The integrated circuit contains a unique signature that is used for the authentication with two or more aspects including i) a first aspect that is a programmed password in a memory embedded on the integrated circuit, and ii) a second aspect that is a unique, randomly generated code based upon a physical characteristic of the integrated circuit.

Abstract: A device includes a substrate, an array of metal pads on a first surface of the substrate, a carbon polymer composite covering the array of metal pads, the composite having variations that result in random resistance values between the metal pads usable as a random code. A method of manufacturing a secure device, including forming an array of metal pads on a dielet substrate, the dielet substrate containing at least one memory in which is stored an encryption key, and an RF communication section, covering the array of metal pads with a carbon polymer composite such that variations in the carbon concentration in the polymer forms a unique pattern of resistance, attaching the dielet substrate to a host component, receiving a request from a security server for a unique code determined by the unique pattern of resistance, and using the encryption key, encrypting and providing the unique code to the security server.

Abstract: A device includes a substrate, an array of metal pads on a first surface of the substrate, a carbon polymer composite covering the array of metal pads, the composite having variations that result in random resistance values between the metal pads usable as a random code. A method of manufacturing a secure device, including forming an array of metal pads on a dielet substrate, the dielet substrate containing at least one memory in which is stored an encryption key, and an RF communication section, covering the array of metal pads with a carbon polymer composite such that variations in the carbon concentration in the polymer forms a unique pattern of resistance, attaching the dielet substrate to a host component, receiving a request from a security server for a unique code determined by the unique pattern of resistance, and using the encryption key, encrypting and providing the unique code to the security server.

Abstract: Manufacturing integrated circuits is discussed with steps as follows. Creating a wafer with a plurality of dies, where each die contains its own integrated circuit. Fabricating multiple instances of TAP circuitry located in a margin between dies of the wafer. Fabricating on the wafer one row of test pads and power pads per group of dies on the wafer, where the row of test pads and power pads is electrically connected and shared among all of the dies in the group. The test and power pads connect to a chain of TAP circuitry in order to supply operating power as well as testing data to verify the integrity of each die in that group of dies. Singulating the dies to create each instance of the integrated circuit, and during the singulation process, the TAP circuitry located in the margin between the dies is destroyed.

Abstract: A device includes a substrate, an array of metal pads on a first surface of the substrate, a carbon polymer composite covering the array of metal pads, the composite having variations that result in random resistance values between the metal pads usable as a random code. A method of manufacturing a secure device, including forming an array of metal pads on a dielet substrate, the dielet substrate containing at least one memory in which is stored an encryption key, and an RF communication section, covering the array of metal pads with a carbon polymer composite such that variations in the carbon concentration in the polymer forms a unique pattern of resistance, attaching the dielet substrate to a host component, receiving a request from a security server for a unique code determined by the unique pattern of resistance, and using the encryption key, encrypting and providing the unique code to the security server.

Abstract: A luminescent solar concentrator (LSC) for receiving electromagnetic radiation of at least a first wavelength is disclosed. The LSC includes a core layer. A lower clad layer substantially underlies the core layer. At least one photovoltaic (PV) cell is partially embedded in at least one of the core layer and the lower clad layer. At least one dye layer substantially overlies the core layer. The at least one dye layer has embedded therein at least one absorption dipole and at least one emission dipole, the at least one emission dipole being coupled to the at least one absorption dipole.

Abstract: A unit pixel of a display includes a driver circuit, a memory circuit and a current controller. The driver circuit is configured to drive a light emitting device. The memory circuit is coupled to the driver circuit, and is configured to store image data for the unit pixel. The current controller circuit is coupled to the driver circuit, and configured to control a current flowing through at least a portion of the driver circuit such that the driver circuit drives the light emitting device with a constant or substantially constant current.

Abstract: Provided is an active matrix light emitting diode (AMOLED) display. A driver circuit of the AMOLED display can be easily manufactured in a simple structure in a current programming method. The AMOLED display programs a voltage corresponding to a current necessary for the operation of an OLED in a memory capacitor, and induces and stores a voltage corresponding to a driving voltage in the memory capacitor while making a preset current flowing between a source and a drain of a driving transistor.

Abstract: A unit pixel of an organic light emitting diode (AMOLED) display includes an organic light emitting diode, a driving transistor, a programming transistor, a switching transistor, and a memory capacitor. An active matrix organic light emitting diode (AMOLED) display includes a plurality of the unit pixels. The unit pixels and AMOLED displays are more easily manufactured in a simpler structure and capable of displaying higher quality images by effectively suppressing changes in pixel brightness according to a threshold voltage shift of a driving transistor.

Abstract: Provided is an active matrix light emitting diode (AMOLED) display. A driver circuit of the AMOLED display can be easily manufactured in a simple structure in a current programming method. The AMOLED display programs a voltage corresponding to a current necessary for the operation of an OLED in a memory capacitor, and induces and stores a voltage corresponding to a driving voltage in the memory capacitor while making a preset current flowing between a source and a drain of a driving transistor.

Abstract: A unit pixel of a display includes a driver circuit, a memory circuit and a current controller. The driver circuit is configured to drive a light emitting device. The memory circuit is coupled to the driver circuit, and is configured to store image data for the unit pixel. The current controller circuit is coupled to the driver circuit, and configured to control a current flowing through at least a portion of the driver circuit such that the driver circuit drives the light emitting device with a constant or substantially constant current.

Abstract: A read-only memory (ROM) is disclosed that uses the presence or absence of linear passive electrical elements, such as resistors or capacitors, to encode zeros and ones, permitting a large-area ROM to be fabricated, possibly on a flexible substrate. The ROM includes a substrate, a plurality of row conductors insulated from each other and at least partially layered on a portion of the substrate; a plurality of column conductors insulated from each other and from the row conductors and at least partially layered above or below a portion of the plurality of row conductors, a plurality of amplifiers electrically connected to the column conductors, and at least one linear passive element attached between the row conductors and the column conductors.

Abstract: A read-only memory (ROM) is disclosed that uses the presence or absence of linear passive electrical elements, such as resistors or capacitors, to encode zeros and ones, permitting a large-area ROM to be fabricated, possibly on a flexible substrate. The ROM includes a substrate, a plurality of row conductors insulated from each other and at least partially layered on a portion of the substrate; a plurality of column conductors insulated from each other and from the row conductors and at least partially layered above or below a portion of the plurality of row conductors, a plurality of amplifiers electrically connected to the column conductors, and at least one linear passive element attached between the row conductors and the column conductors.

Abstract: A radio frequency (RF) pulse power amplifier biased with a relatively low supply voltage generates one or more RF pulses having a relatively large output power. The RF pulse power amplifier may be configured as a push-pull power amplifier operating in class D mode including first and second sections, balanced-to-unbalanced (balun) transformer, and a load resistor coupled across the output winding of the balun transformer. Each section has a current source providing bias current, a MOS transistor, and a pair of bipolar transistors. Each section receives its input digital signal at the MOS transistor, which acts as a current switch for a bias current from a current source. With a relatively small voltage change in response to the input digital signal, the MOS transistor switches the bias current between itself and a transistor pair used to drive the corresponding half (input winding) of the balun transformer.

Abstract: A pixel structure having at least one organic thin film transistor (OTFT) that minimizes gate-to-pixel capacitance. In one embodiment, a pixel structure provides a new transistor structure where an OTFT electrode on the data-line side of the transistor is extended or wrapped around three sides of the transistor relative to a pixel-side electrode. Thus, the pixel-side electrode can be made very small without reducing the effective width (and therefore on-current) of the transistor.