System and method for inmarsat capacity expansion and control
First Claim
1. A means for enabling a standard Inmarsat-B mobile earth station control unit (MCU) and an external satellite modem with an L-band interface to transmit using a single standard Inmarsat-B RF terminal on a mutually exclusive basis by the use of a diplexing means and by switches controlled by an embedded computer on a DSP board interfaced with the external satellite modem and the MCU, whereby the transmit source feeding the RF terminal is switched between the MCU and the external satellite modem by the embedded computer'"'"'s setting of two switches, and wherein the MCU and external satellite modem can receive from the RF terminal regardless of which transmit source is connected to the RF terminal.
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Accused Products
Abstract
The Inmarsat Capacity Expansion invention, in an embodiment to retrofit a standard Inmarsat-B mobile earth station (MES), combines standard MES equipment and functionality with an assembly containing a diplexer/switch and a digital signal processor, a second SCPC modem that has configurable modulation and error correction capabilities, control signals and paths, and related management and control software and hardware to enable the transmission and reception of standard service types and higher data rate services.
33 Citations
32 Claims
- 1. A means for enabling a standard Inmarsat-B mobile earth station control unit (MCU) and an external satellite modem with an L-band interface to transmit using a single standard Inmarsat-B RF terminal on a mutually exclusive basis by the use of a diplexing means and by switches controlled by an embedded computer on a DSP board interfaced with the external satellite modem and the MCU, whereby the transmit source feeding the RF terminal is switched between the MCU and the external satellite modem by the embedded computer'"'"'s setting of two switches, and wherein the MCU and external satellite modem can receive from the RF terminal regardless of which transmit source is connected to the RF terminal.
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5. The apparatus of 1 in which the external satellite modem is an EFData 300L.
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8. A diplexer/switch-based means for using an external satellite modem with a standard Inmarsat-B mobile earth station to provide transmission and reception at approximately 32 kbps of throughput per 25 kHz of bandwidth, further comprising a second identical diplexer/switch-based means, a means for coupling the second diplexer/switch-based means with the first diplexer/switch-based means, a means for determining which diplexer/switch-based means of the coupled pair has better received signal quality at any given time, and a means for permitting only the diplexer/switch-based means with better signal quality to transmit at such time.
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9. An earth station for Inmarsat-B service, comprising:
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a standard Inmarsat-B mobile earth station control unit (MCU) having a first satellite modem, a microcontroller executing an mobile earth station (MES) management program, a first EIA-232 port in communication with the MES management program, a diplexed L-band transmit/receive interface, and a software application programming interface (API) in the management program accessible through the EIA-232 interface, which API enables external control of a high power amplifier in an RF terminal by use of the API; a standard Inmarsat-B RF terminal with L-band transmit/receive interface and a high power amplifier (HPA) that the MCU can control using management and control (M&
C) messages multiplexed over an RF path connecting the MCU with the RF terminal;a second satellite modem capable of providing higher data rate operation than the first satellite modem and equipped with L-band transmit and receive interfaces, a keypad and display, a microcontroller running a modem management program that controls the operation of the second satellite modem, keypad, and display, a baseband I/O port, a remote control EIA-232 port in communication with the modem management program; and a switching assembly associated with the second satellite modem and that contains a plurality of EIA-232 ports provided by a UART in communication with a switching management program running on a computer embedded in the switching assembly, an entry switch and an exit switch controlled by the embedded computer, a first M&
C path between a first port on the UART and the EIA-232 port on the MCU, a second M&
C path between a second port on the UART and the remote control EIA-232 port on the second satellite modem, two L-band diplexers, an entry connector connected to the diplexed L-band transmit/receive interface of the first satellite modem, an exit connector connected to the L-band transmit/receive interface of the RF terminal, NVRAM associated with the embedded computer as a data storage device, which switching management program interoperates with the MES management program through data exchange over the first M&
C path and with the modem management program through data exchange on the second M&
C path, provides a local user interface through the keypad and display on the second satellite modem, and based on data received and stored in NVRAM the switching management program controls the entry and exit switches to switch between;a first path (“
Bypass Path”
) on the switching assembly from the entry connector through entry and exit switches to the exit connector that passes signals from DC power to L-band with negligible attenuation, anda second RF path (“
ICE path”
) on the switching assembly from the entry connector through the entry switch that connects with a first diplexer that terminates an entering transmitter L-band signal in a dummy load, and substitutes for the entering transmitter L-band signal the L-band transmitter output of the second satellite modem by connecting the L-band transmitter output of the second satellite modem with the transmit port of the second diplexer, which diplexes the second satellite modem transmit output into an RF path that passes through the exit switch to the exit connector, wherein the receive L-band path from the exit connector passes through the exit switch to the diplexed port of the second diplexer, out of the receive port of the second diplexer to the receive port of the first diplexer, out of the diplexed port of the first diplexer through the entry switch to the entry connector, and wherein the receive path is amplified and filtered so that it is virtually lossless compared with the receive signal strength at the entry connector when the first path is selected by the embedded computer, and wherein a directional coupler inserted in the RF path between the entry connector and the entry switch to provide a branch receive path that is filtered, amplified, and connected to the receive interface of the second satellite modem, and wherein DC power and an M&
C frequency band pass through a first low pass filter connected to the entry connectors and a second low pass filter connected to the exit connector, thereby providing a DC power path and M&
C path through the switching assembly when the second RF path is selected by the switching management program;wherein the switching management program through communications with the modem management program and based on a configuration stored in NVRAM configures the second satellite modem to transmit and receive at data rates higher and lower than the data rate supported by the first satellite modem, controls the HPA power level through communications with the MES management program to set the HPA at the power level required by the configured data rate, and sets the entry and exit switches to insert the ICE Path so that the second satellite modem transmits and receives over the RF terminal. - View Dependent Claims (10, 11, 12, 13, 14, 15, 16)
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17. A satellite station, comprising:
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a first modem capable of processing data at a first data rate; a second modem capable of processing data at a second data rate and subjecting the data to first and second error correction schemes; and a microprocessor coupled to the first and second modems and configured to operate management and control programming to direct data processing of the first and second modems; wherein the first and second error correction schemes are manipulated so that the second data rate is faster than the first data rate. - View Dependent Claims (18, 19, 20, 21, 22, 23, 24, 25, 27, 28, 29)
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26. A method of operating a satellite station, comprising:
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processing data through a first modem at a first data rate; processing data through a second modem at a second data rate and subjecting the data to first and second error correction schemes; and executing a microprocessor coupled to the first and second modems and configured to operate management and control programming to direct data processing of the first and second modems; wherein the first and second error correction schemes are manipulated so that the second data rate is faster than the first data rate. - View Dependent Claims (30, 31, 32)
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Specification