Abstract: Embodiments of the disclosure pertain to an optical or optoelectronic transceiver comprising an optical or optoelectronic receiver, an optical or optoelectronic transmitter, a plurality of electrical devices, a housing, and a heat sink having a non-planar surface. The optical or optoelectronic receiver includes a receiver optical subassembly (ROSA). The optical or optoelectronic transmitter includes a transmitter optical subassembly (TOSA). The electrical devices are configured to provide or control one or more functions of the optical or optoelectronic receiver and the optical or optoelectronic transmitter. The housing is over and/or enclosing the optical or optoelectronic receiver and the optical or optoelectronic transmitter. The housing includes a first section and a second section, and is configured to (a) be removably insertable into a cage or socket of a host device and (b) position the first section of the housing outside the cage or socket when the housing is inserted in the cage or socket.

Abstract: A small form-factor pluggable (SFP) optical transceiver includes a casing configured to accommodate optical and electrical devices. During normal operation, the casing is connected to a switchboard via a connector in the switchboard, and the optical devices are outside the switchboard, thereby exposing optical devices sensitive to high temperature to the outside air, reducing the operational temperature of the optical device portion relative to the heated portion inside the switchboard. Thus, the present SFP optical transceiver advantageously improves operational performance and extends the life of the device. Also, the present SFP optical transceiver having the optical device portion outside the switchboard advantageously improves the cooling performance for the optical device portion.

Abstract: An optical module housing that may be easily seated, locked in and removed from a socket, thereby reducing or eliminating potential damage to the module and socket, and methods for making and using the housing are disclosed. The module housing generally includes a chassis, one or more pivots attached to the chassis, a latch configured to secure the housing in a corresponding slot when in a locked position, a slider configured to be in contact with and/or connected to the latch and to move the latch relative to the chassis, the latch and/or the slider being configured to move on and/or around the pivot(s) and a handle configured to be in contact with and/or connected to the slider such that when the handle moves from a first position to a second position, the slider and latch move to the locked and/or an unlocked positions.

Abstract: A small form-factor pluggable (SFP) optical transceiver includes a casing configured to accommodate optical and electrical devices. During normal operation, the casing is connected to a switchboard via a connector in the switchboard, and the optical devices are outside the switchboard, thereby exposing optical devices sensitive to high temperature to the outside air, reducing the operational temperature of the optical device portion relative to the heated portion inside the switchboard. Thus, the present SFP optical transceiver advantageously improves operational performance and extends the life of the device. Also, the present SFP optical transceiver having the optical device portion outside the switchboard advantageously improves the cooling performance for the optical device portion.

Abstract: A small form-factor pluggable (SFP) optical transceiver includes a casing configured to accommodate optical and electrical devices. During normal operation, the casing is connected to a switchboard via a connector in the switchboard, and the optical devices are outside the switchboard, thereby exposing optical devices sensitive to high temperature to the outside air, reducing the operational temperature of the optical device portion relative to the heated portion inside the switchboard. Thus, the present SFP optical transceiver advantageously improves operational performance and extends the life of the device. Also, the present SFP optical transceiver having the optical device portion outside the switchboard advantageously improves the cooling performance for the optical device portion.

Abstract: A small form-factor pluggable (SFP) optical transceiver includes a casing configured to accommodate optical and electrical devices. During normal operation, the casing is connected to a switchboard via a connector in the switchboard, and the optical devices are outside the switchboard, thereby exposing optical devices sensitive to high temperature to the outside air, reducing the operational temperature of the optical device portion relative to the heated portion inside the switchboard. Thus, the present SFP optical transceiver advantageously improves operational performance and extends the life of the device. Also, the present SFP optical transceiver having the optical device portion outside the switchboard advantageously improves the cooling performance for the optical device portion.

Abstract: An optical module housing that may be easily seated, locked in and removed from a socket, thereby reducing or eliminating potential damage to the module and socket, and methods for making and using the housing are disclosed. The module housing generally includes a chassis, one or more pivots attached to the chassis, a latch configured to secure the housing in a corresponding slot when in a locked position, a slider configured to be in contact with and/or connected to the latch and to move the latch relative to the chassis, the latch and/or the slider being configured to move on and/or around the pivot(s) and a handle configured to be in contact with and/or connected to the slider such that when the handle moves from a first position to a second position, the slider and latch move to the locked and/or an unlocked positions.

Abstract: A monitoring system, for monitoring an object, which includes a microprocessor comprising a memory to store data, and a control program executed by said microprocessor, said microprocessor having a stand-by mode and an active mode, a communications means connected to said microprocessor for transmitting data from said microprocessor to a monitoring station, a zone monitoring device on the object connected to said microprocessor in a loop with said microprocessor in said stand-by mode, a power source for supplying power to said microprocessor, communications means and zone monitoring device, wherein upon said microprocessor receiving an input signal from said zone monitoring device, said control program directs said microprocessor to switch to active mode, generate and store in said memory an alarm message corresponding to said input signal from said zone monitoring device, activate said communications means, and transmit said alarm message to a monitoring station.

Abstract: A monitoring system, for monitoring an object, which includes a microprocessor comprising a memory to store data, and a control program executed by said microprocessor, said microprocessor having a stand-by mode and an active mode, a communications means connected to said microprocessor for transmitting data from said microprocessor to a monitoring station, a zone monitoring device on the object connected to said microprocessor in a loop with said microprocessor in said stand-by mode, a power source for supplying power to said microprocessor, communications means and zone monitoring device, wherein upon said microprocessor receiving an input signal from said zone monitoring device, said control program directs said microprocessor to switch to active mode, generate and store in said memory an alarm message corresponding to said input signal from said zone monitoring device, activate said communications means, and transmit said alarm message to a monitoring station.

Abstract: A container monitoring system which includes a microprocessor comprising a memory to store data, and a control program executed by said microprocessor, said microprocessor having a stand-by mode and an active mode, a communications means connected to said microprocessor for transmitting data from said microprocessor to a monitoring station, a zone monitoring device on the container connected to said microprocessor in a loop with said microprocessor in said stand-by mode, a power source for supplying power to said microprocessor, communications means and zone monitoring device, wherein upon said microprocessor receiving an input signal from said zone monitoring device, said control program directs said microprocessor to switch to active mode, generate and store in said memory an alarm message corresponding to said input signal from said zone monitoring device, activate said communications means, and transmit said alarm message to a monitoring station.

Abstract: A container monitoring system which includes a microprocessor comprising a memory to store data, and a control program executed by said microprocessor, said microprocessor having a stand-by mode and an active mode, a communications means connected to said microprocessor for transmitting data from said microprocessor to a monitoring station, a zone monitoring device on the container connected to said microprocessor in a loop with said microprocessor in said stand-by mode, a power source for supplying power to said microprocessor, communications means and zone monitoring device, wherein upon said microprocessor receiving an input signal from said zone monitoring device, said control program directs said microprocessor to switch to active mode, generate and store in said memory an alarm message corresponding to said input signal from said zone monitoring device, activate said communications means, and transmit said alarm message to a monitoring station.