Satellite communication system employing a combination of time slots and orthogonal codes

Abstract

A satellite communication system is disclosed which provides multiple beams and employs a plurality of user terminals (UT) and at least one gateway connected to a PSTN which communicates with at least one UT over the system wherein each of the UTs within a given frequency band is distinguished one from the other employing a combination of time slots and orthogonal codes.

Description

I. CROSS-REFERENCE TO RELATED APPLICATIONS [0001] This is a continuation-in-part of U.S. patent application Ser. No. 11 / 325,176, filed Jan. 4, 2006, which is incorporated by reference.II. FIELD OF THE INVENTION [0002] The present invention relates to cellular telephone systems. More specifically, the present invention relates to new and improved systems and methods for communicating information in mobile cellular telephone systems or satellite mobile telephone systems employing spread spectrum communication signals. III. BACKGROUND OF THE INVENTION [0003] Historically, the telephone, which comes from the Greek word ‘tele’, meaning from afar, and ‘phone’, meaning voice or voice sound, is said to have been invented on Mar. 10, 1876 in Boston, Mass. by Alexander Graham Bell. The principle of the telephone was conceived as early as 1874 combining electricity and voice which led to Bell's actual invention of the telephone in 1876. [0004] U.S. Pat. No. 174,465 issued Mar. 3, 1876 for impr...

AI Technical Summary

Benefits of technology

[0062] A center frequency of the signal transmitted to each UT is adjusted to precompensate for Doppler between the gateway and satellite, thus minimizing the search time and window that the UT needs to lock on to the signal. This technique is currently used in the Globalstar® system. Similarly, the timing of signals in each time slot transmitted to each UT is adjusted by the gateway based on a calculated position of each UT. This calculation may be done initially either by incorporating GPS into each UT, which informs the gateway of its coordinates, or by other known means of position location such as techniques currently used in the Globalstar® system which is based on triangulation using multiple different delays from different satellites and later on adjusting based on a rate of change of the UTs relative position to the serving Globalstar® system. The reverse link as presently employed in such a system is similar to the Globalstar® reverse link non-orthogonal, non-coherent CDMA but, in addition, it also employs time slots as in the forward link described above to allow each user to send as much or as little data as needed. Specifically, the reverse link employs short time slices of signals with different phase shifts of a long PN code to identify different users. In addition, it employs Walsh orthogonal modulation to provide high levels of immunity to noise as in the current Globalstar® system. However, the higher layers of the protocol are designed to be similar to the WCDMA higher layers so that the packet data can be officially transmitted without the need to set up dedicated channels as is done in the current Globalstar® system which employs circuit switching.

[0063] Reverse link power control can be performed as in the current Globalstar® system where data rate is fixed and power is varied as needed to meet the link budget or by varying the data rate and keeping UT power fixed as was previously mentioned for the forward link above. A trade off is employed between allowing a greater number of UT data rates to improve granularity of power utilization versus hardware complexity at the gateway.

Problems solved by technology

However, at this point in time the technology was nonexistent.

Suddenly consumer demand quickly outstripped the cellular phone system's 1982 standards so that by 1987 cellular phone subscribers exceeded one million and the airwaves were crowded.

The Rayleigh fading characteristics experienced in the terrestrial signal is found to be caused by the signal being reflected from many different features of the physical environment, resulting in a signal which arrives at a mobile unit receiver from many directions with different transmission delays.

In the UHF frequency bands which are usually employed for mobile radio communications, including cellular mobile telephone systems, there is found to be significant phase differences in signals traveling on different paths which provides the possibility of destructive summation of the signals causing occasional deep fades.

Physical position of the mobile unit is a strong function of the terrestrial channel fading so that small changes in the position of the mobile unit change the physical delays of all the signal propagation paths which further result in a different phase for each path.

This level of fading is found to be extremely disruptive to signals in a terrestrial channel, resulting in poor communication quality.

The terrestrial channel is found to pose special problems to any communication system, particularly with respect to multiple path.

When narrow band modulation systems are employed, such as at analog FM modulation, by conventional telephone systems, the existence of multiple paths results in severe multipath fading.

For signals which possess path delays on this order, it is found that signals cannot be discriminated against in the demodulator, resulting in some degree of fading.

It is found, however, that the severity of multipath fading experienced in the terrestrial cellular environment with the resulting phase disruption of the channel precludes usage of coherent demodulation techniques for the mobile to cell link.

As such, signals interfere with each other much the same as if they were wide bandwidth Gaussian noise resulting in other user signals or mutual interference noise ultimately limiting the achievable capacity.

However, the '307 patent does not address the case where the beams and satellites are rapidly moving as they are in a MEO or LEO system, since it was written in an era that preceded the satellite technology that enabled large numbers of relatively smaller satellites (such as Globalstar's®) to be economically and reliably launched and controlled.

That patent also does not address packet data services, since those were not widely used in the time frame of the patent.

Other patents that address packet data services also do not address the LEO, MEO or dynamic beam GEO systems.

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