Low Rate Picture Transmission

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The Low Rate Picture Transmission (LRPT) is a digital transmission system, intended to deliver images and data from an orbital weather satellite directly to end users via a VHF radio signal. It is used aboard polar-orbiting, near-Earth weather satellite programs such as MetOp and NPOESS.

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[edit] Purpose

LRPT provides three image channels at full sensor resolution (10-bit, 1 km/pixel, six lines/second) in addition to data from other sensors, such as atmospheric sounders and GPS positioning information.

The system is an update and replacement of the existing analog system called Automatic Picture Transmission (APT), which has been used since the 1960s aboard NOAA's TIROS polar-orbiting satellites. The APT system provided only two image channels, which were at a reduced accuracy and resolution (8-bit, 4 km/pixel, two lines/second). Compared to the APT system, LRPT images are four times more accurate and contain twelve times the resolution. Further, the additional data from other sensors increases the applications of the satellites and the users who receive the signal.

[edit] Design

LRPT uses a packetized datastream transmitted at an approximately 62 kilobits per second (kbps) rate. Each sensor using the LRPT is considered an application and provided a percentage of the transmission bandwidth in the form of a virtual channel. For example, the Advanced Very High Resolution Radiometer (AVHRR) imaging sensor is provided approximately 40 kbps to transmit its three image channels, and the High Resolution Infrared Radiation Sounder (HIRS) is provided approximately 2900 bps. The packetized application system provides the flexibility to transmit and receive new types of data in the future using the same hardware.

The datastream is processed using a Reed-Solomon error correction, then convolution encoded, interleaved, and padded with unique synchronization words. The resulting binary stream is approximately 160 kbps.

It is transmitted as an 80 kiloBaud quadrature phase-shift keyed (QPSK) signal on an RF carrier in the 137MHz-band, with an equivalent isotropically radiated power level that varies between 3.2 dBW (2 watts) and 8.0 dBW (6.3 watts).

To ensure the low-complexity ground stations that previously received the APT signal would be able to access the LRPT signal, a design study was included with the LRPT specification. Labeled Annex A, it shows the calculations which approximate the worst-case link budget for fixed, omnidirectional antenna reception will be 4.9dB when the satellite is 13° above the horizon, and improve to 8.6dB at 30° or higher elevations.

[edit] Image data

The AVHRR image data, in its raw form, consists of three images, each composed of six lines per second, at 2048 pixels per line, using 10-bits per pixel. This yields a raw datarate of 368,640 bps; approximately ten times greater than the allocated bandwidth. Therefore, the data is compressed using the JPEG extended DCT compression, adapted to a fixed compression ratio with continuous operation (no header or trailer), to fit the virtual channel size.

The imager data is gathered into image "strips" of 2048 pixels wide and 8 rows tall before being compressed. Each packet contains three of these image strips, one for each image channel. To reconstruct a 2048x2048 image requires 256 consecutive AVHRR image packets.

[edit] Current Status

Although it is currently being flown on MetOp-A, LRPT has been permanently deactivated on that vehicle after causing interference with the High Resolution Infrared Radiation Sounder (HIRS) sensor.

"The initial investigations regarding the interference on MetOp-A HIRS have been completed, and the conclusion is that no scenario exists where LRPT on MetOp-A can be turned on without causing heavy interference on HIRS. Due to the operational importance of HIRS and the lack of an established LRPT user community, it is clear that LRPT will not be turned on again operationally on MetOp-A." - Announcement to NOAA from EUMETSAT on 5 February 2007[1]

[edit] Future

The previously mentioned MetOp program intends to launch satellites every five years and maintain service through 2020. With While APT will continue to be transmitted on existing satellites, and will be used on NOAA-N', NOAA's final TIROS-series satellite, NOAA has indicated it will move to a new system, such as LRPT, on future vehicles.

[edit] See also

  • High Resolution Picture Transmission (HRPT)

[edit] Notes and references

[edit] External links