Patent application number | Description | Published |
20090028574 | SELF-TESTING OPTICAL TRANSCEIVER - Systems and methods for an optical transceiver module to perform one or more diagnostic self-tests without the assistance of a host computing system. The optical transceiver module includes at least one processor, a persistent memory and a system memory. The persistent memory, which is coupled to the at least one processor, contains microcode. The microcode is loaded from the persistent memory to the system memory and executed by the at least one processor. The executed microcode causes the optical transceiver module to perform one or more diagnostic self-tests. The diagnostic result data of the one or more diagnostic self-tests is then stored in the persistent memory and is formatted for analysis. The formatted data may then be analyzed to ascertain the response of the optical transceiver to changes in its test environment. | 01-29-2009 |
20090067848 | LIMITED LIFE TRANSCEIVER - Systems and methods for an optical transceiver module to limit the amount of time the optical transceiver module is allowed to operate. The optical transceiver module includes at least one processor, a persistent memory and a system memory. The persistent memory, which is coupled to the at least one processor, contains microcode. The microcode is loaded from the persistent memory to the system memory and executed by the at least one processor. The executed microcode causes the optical transceiver module to detect the amount of time that the optical transceiver has been operating. The optical transceiver module then determines if the detected amount of operating time is in excess of a predetermined amount of operating time. If the detected operating time is in excess of the predetermined amount of operating time, the optical transceiver module causes itself to become non-operational. The optical transceiver module may then report its operational status. | 03-12-2009 |
20090138709 | OPTICAL TRANSCEIVER WITH VENDOR AUTHENTICATION - An optical receiver comprising at least one processor and a memory including at least one of an encryption key or a decryption key and at least one of encryption microcode or decryption microcode that includes processor-executable instructions that, when executed by the at least one processor, cause the optical transceiver to perform the following: an act of performing an encryption or decryption operation on data received from a host computing system to thereby authenticate the optical transceiver. | 05-28-2009 |
20100254710 | EARLY SELF-VALIDATION OF PERSISTENT MEMORY DURING BOOT IN AN OPTICAL TRANSCEIVER - An operational optical transceiver configured to self-validate a boot image loaded from the persistent memory early in the boot process. The optical transceiver includes a persistent memory, a controller, and a system memory. The controller initializes the boot process and begins to load information from the persistent memory to the system memory. Next, the controller detects early in the boot process boot image verification data in the information being sent to the system memory. The controller then determines if the boot image verification data has an expected value. If the verification data includes the expected value, the controller continues the boot process. If the verification data does not include the expected value, the controller will retry the boot process a predetermined number of times and will enter a default operational state if the expected value is not detected while retrying the boot process the predetermined number of times. | 10-07-2010 |
20110010576 | MICROCODE CONFIGURABLE FREQUENCY CLOCK - A microcode configurable frequency clock that may be used to control the speed of high speed comparison in an operational optical transceiver. The frequency clock includes a memory and a logic circuit. The memory receives microcode generated data relating to the desired speed of comparison. The logic circuit is configured to receive an input clock signal and to produce an output clock signal by frequency dividing the input signal based on the microcode generated data. The output clock is used to control the speed of comparison in the optical transceiver. | 01-13-2011 |
20110020007 | INTER-TRANSCEIVER MODULE COMMUNICATION FOR OPTIMIZATION OF LINK BETWEEN TRANSCEIVERS - Two or more optical transceivers coupled to each other by an optical link to optimize communication over the optical link. A first transceiver generates electrical data that represents an operational parameter for optimization. The transceiver then converts the electrical data into an optical signal and transmits the optical signal over the optical link to a second transceiver. The second transceiver recovers the electrical data from the optical signal and uses the recovered electrical data to change characteristics of the optical signal transmitted by the second transceiver. | 01-27-2011 |
20120134680 | INTER-TRANSCEIVER MODULE COMMUNICATION FOR FIRMWARE UPGRADE - An operational optical transceiver configured to update operational firmware using an optical link of the transceiver. The optical transceiver includes at least one processor and a system memory capable of receiving firmware. The optical transceiver receives an optical signal over the optical link containing the update firmware. The optical transceiver then recovers the firmware from the optical signal. Finally, the optical transceiver provides to the system memory the recovered firmware, which when executed by the at least one processor alters the operation of the transceiver. | 05-31-2012 |
20130148978 | CHIP IDENTIFICATION PADS FOR IDENTIFICATION OF INTEGRATED CIRCUITS IN AN ASSEMBLY - Chip identification pads for identification of integrated circuits in an assembly. In one example embodiment, an integrated circuit (IC) assembly includes a controller, a plurality of ICs, a shared communication bus connecting the controller to the plurality of ICs and configured to enable communication between the controller and each of the plurality of ICs, and a set of one or more chip identification pads formed on each IC. Each set of chip identification pads has an electrical connection pattern. The electrical connection pattern of each set is distinct from the electrical connection pattern on every other set. Each distinct electrical connection pattern represents a unique identifier of the corresponding IC thereby enabling the controller to distinguish between the ICs. | 06-13-2013 |