Abstract: A process is provided for aligning and connecting at least one optical fiber to at least one optoelectronic device so as to couple light between at least one optical fiber and at least one optoelectronic device. One embodiment of this process comprises the following steps: (1) holding at least one optical element close to at least one optoelectronic device, at least one optical element having at least a first end; (2) aligning at least one optical element with at least one optoelectronic device; (3) depositing a first non-opaque material on a first end of at least one optoelectronic device; and (4) bringing the first end of at least one optical element proximate to the first end of at least one optoelectronic device in such a manner that the first non-opaque material contacts the first end of at least one optoelectronic device and the first end of at least one optical element. The optical element may be an optical fiber, and the optoelectronic device may be a vertical cavity surface emitting laser.

Abstract: This invention relates to a flexible printed circuit board that is used in connection with an optical transmitter, receiver or transceiver module. In one embodiment, the flexible printed circuit board has flexible metal layers in between flexible insulating layers, and the circuit board comprises: (1) a main body region orientated in a first direction having at least one electrical or optoelectronic device; (2) a plurality of electrical contact pads integrated into the main body region, where the electrical contact pads function to connect the flexible printed circuit board to an external environment; (3) a buckle region extending from one end of the main body region; and (4) a head region extending from one end of the buckle region, and where the head region is orientated so that it is at an angle relative to the direction of the main body region. The electrical contact pads may be ball grid arrays, solder balls or land-grid arrays, and they function to connect the circuit board to an external environment.

Abstract: An optical power control system is provided that may be used in connection with an optical transmitter, receiver or transceiver module. The optical power control system comprises: (1) an array of optoelectronic devices; (2) an array of optical elements; (3) the array of optical elements optically aligned to the array of optoelectronic devices in such a manner that one or more optical elements is optically aligned to one or more optoelectronic devices; (4) a light-receiving device; and (5) a reflector proximate to the array of optical elements, the reflector optically orientated with the array of optoelectronic devices and the light-receiving device such that some emission from at least one optoelectronic device is reflected on at least a portion of the light-receiving device. The optical elements may be optical fibers and may be packaged in a ferrule. The light-receiving device may be a photo-detector or a light pipe.

Abstract: An optoelectronic mounting structure is provided that may be used in conjunction with an optical transmitter, receiver or transceiver module. The apparatus comprises: (1) a mounting structure; (2) an array of optoelectronic devices adapted to the mounting structure, the optoelectronic devices having at least a first end; (3) an array of optical elements, the array of optical elements having at least a first end; (4) the first end of the array of optical elements proximate to the first end of the array of optoelectronic devices in such a manner that one or more optical elements is optically aligned to one or more optoelectronic devices; and (5) a heat spreader passing along a surface of a head region of the mounting structure. The mounting structure may be a flexible printed circuit board. Thermal vias or heat pipes in the head region may transmit heat from the mounting structure to the heat spreader. The heat spreader may provide mechanical rigidity or stiffness to the heat region.

Abstract: This invention relates to an optical transmitter, receiver or transceiver module, and more particularly, to an optoelectronic connector. The optoelectronic connector comprises: (1) a mounting structure; (2) an array of optoelectronic devices adapted to the mounting structure, the optoelectronic devices having at least a first end; (3) an array of optical elements, the array of optical elements having at least a first end; (4) the first end of the array of optical elements proximate to the first end of the array of optoelectronic devices in such a manner that one or more optical elements is positioned relative to one or more optoelectronic devices; and (5) a heat spreader passing along a surface of a head region of the mounting structure. The mounting structure may be a flexible printed circuit board. Thermal vias or heat pipes in the head region may transmit heat from the mounting structure to the heat spreader. The heat spreader may provide mechanical rigidity or stiffness to the heat region.

Abstract: A compliance monitoring apparatus (10) includes sensors (70, 72, 74, 76) for sensing specified conditions such as temperature and impact, and a signal processor (26) for storing sensor data and concurrent time data for subsequent analysis. The invention finds utility in monitoring compliance with a prescribed mode of a person wearing an appliance such as a splint (12), and for monitoring the conditions experienced by a package (100) during shipment.

Abstract: A computer-based method for aiding a user to develop a computer-based simulation model of the kind which simulates a multiple variable system using a suite of equations. Stored, user-entered constraint knowledge defines possible conditions of variables of the multiple variable system and corresponding expected consequences on variables of the system. The possible conditions are automatically applied to the suite of equations to produce test consequences on variables of the system. Then the test consequences are automatically analyzed against the expected consequences as an indication of the validity of the simulation model.

Abstract: In a data processing system employed for simulation, a simulation program (24) produces simulation results (26), while a pre-compiler (18) used to prepare the simulation program (24) generates cause and effect lists (22). The cause and effect lists (22) and simulation results (26) are organized in data groups associated with the various variables in the model. A presentation module (28) operates a display (16) so as to display variable names (37) that represent the data groups and icons (32, 34, 36, 38, 40, 42, and 44) that represent operations that can be performed on the data groups. By using a mouse (15) to "click on" a data-group name (48) and an icon (40-55, 59), the user can cause a selected data-group operation to be performed on a selected data group.