 |
Description  |
|
|
BACKGROUND
The present invention relates generally to cellular telephone systems, and more particularly, to a cellular telephone system that employs spread spectrum transmission to provide additional services without degrading the existing voice
communications service, while utilizing much of the present cellular telephone infrastructure.
The cellular telephone band was designed to carry a large number of two-way voice conversations to mobile users. In addition to two way voice communication, there is interest in using the cellular telephone band to provide vehicle location and
messaging services, emergency SOS information, and vehicle anti-theft protection services, for example. However, current systems that are confined to narrow band voice channels of the cellular band produce location accuracies that are about two orders
of magnitude lower than are required to provide these services, and these are generally not useful for most applications.
Previous nationwide vehicle location systems, disclosed in U.S. Pat. Nos. 4,359,733 and 4,740,792, for example, have not come to fruition to date because of the relatively high start up capital cost of using satellites. Other nationwide
location systems are planned (TELETRAC and GEOSTAR), but they operate in frequency bands other than the cellular band and therefore require a very expensive special purpose infrastructure. The IBM-Motorola mobile data service currently operational in
the New York, Chicago and Los Angeles areas also requires a special purpose infrastructure which results in high usage fees.
The use of spread spectrum communications in conjunction with the cellular voice channel has been investigated in recent years. One implementation proposed by Qualcomm, Inc. of San Diego, Calif., would partition the cellular band such that a 1
MHz frequency band would be dedicated to each of the transmit and receive bands for spread spectrum voice communication, while the balance of the two bands would continue to provide standard cellular service. As spread spectrum systems increased in
usage, the spread spectrum portion of the bands would increase in size to match the need. It is apparent that, since this proposed system requires its own dedicated frequency subbands, that the Qualcomm implementation of spread spectrum communication
would interfere with the operation of the standard cellular voice channels.
Accordingly, it is an objective of the present invention to employ technology that overlays the narrow band cellular telephone voice signals with wide band spread spectrum signals to provide for messaging and vehicle tracking capabilities without
adversely affecting the quality or capacity of the voice channels.
SUMMARY OF THE INVENTION
The present invention enables the incorporation of messaging and vehicle location capabilities into existing cellular services without causing objectionable interference to users of the cellular voice channels. A spread spectrum processor that
utilizes a unique signal architecture/waveform design is the key to this capability.
Through the use of wide bandwidth spread spectrum radio transmissions overlaid over the existing cellular voice signals, new services which depend on the ability to accurately locate vehicles are provided. In addition, a second class of spread
spectrum radio transmissions supports a large number of users transmitting low rate digital messages. Both areas of functionality (vehicle location and messages) are obtained without sacrificing any of the existing voice channel capacity. By employing
the concepts of the present invention, since a large fraction of the cellular telephone infrastructure may be used in common, a large savings in deployment costs results.
The system of the present invention is designed to share the existing cellular frequencies, cell site real estate, cell site antenna towers and antennas, and low noise amplifiers used in the cell site radio frequency receiver chain. The only
additional cell site equipment is a unique spread spectrum signal processor. New mobile telephone equipment for deployment in vehicles would include a spread spectrum transmitter in accordance with the present invention. Thus, this system has the
economic viability for both regional and nationwide deployment. When compared to a nationwide system using a satellite infrastructure, the vehicular electronics package requires a much lower power transmitter because the transmission distances are of
the order of 20 miles, instead of 20,000 miles for systems that use satellites. Vehicle transmitter power may be reduced from hundreds of watts to less than one watt with a consequent downward revision in cost per unit.
The present invention permits dual usage of the frequency spectrum assigned for cellular telephone service. Currently voice conversations are supported by dividing the spectral space into individual 30 KHz channels. Cellular service suppliers
are assigned blocks of channels in contiguous fashion covering bandwidths in excess of 10 MHz. Through the use of unique spread spectrum waveforms (which spread energy over the full 10 MHz bandwidth), digital signalling is supported in the same spectral
space and in the presence of the existing voice traffic. At the same time no objectionable interference is generated to affect the existing traffic since the spread spectrum transmissions are either below the normal noise levels for digital messaging,
or of such short duration that they are imperceptible in the normal burst noise background for position location applications.
Two new classes of functionality are created by the present invention. Class I is a digital messaging service that permits the simultaneous transmission from nominally 100 vehicles each sending data messages at the rate of 300 bits per second to
access the normal telephone network. The other class of digital signalling (Class II) provides for the accurate location of vehicles, with accuracies on the order of 100 feet. The applications of this technology are numerous. For instance, if a motion
sensor coupled to the system identifies that a vehicle theft is in progress, thus energizing the vehicular transmitter, the system permits location tracking of the vehicle for law enforcement officers. Police, ambulance and/or tow truck service may be
directed to an exact location. Customized yellow pages directory service which depends on knowledge of vehicle location may also be facilitated.
For vehicle location, a burst spread waveform pattern having a burst duration on the order of 10 milliseconds or less is employed to maximize location accuracy and to minimize interference which is naturally suppressed by the clipping action of
the existing narrowband cellular FM receivers. For vehicle location, the spread spectrum system employes rapid synchronization techniques and uses a single code for access to the system by the transmitting vehicle.
In anti-theft applications, when it is necessary to make a number of sequential location measurements in a relatively short period of time, a waveform variant may be used. In this case, the entire band of cellular frequencies could be divided
into n (say 10) narrower spread spectrum channels with center frequencies at f.sub.1 through f.sub.n. Then each burst transmission (the pulse amplitude and duration remain unchanged) would be sent at a new center frequency. The reduced bandwidth
transmissions sacrifices some location accuracy, but distributes the imperceptible voice channel blockage to a new set of voice users with each transmission. Thus, the non-objectionable interference characteristic is preserved.
For messaging, a below the noise continuous wave (CW) spread spectrum waveform is employed which is naturally suppressed by the FM limiters in the existing narrowband cellular receivers. The service request and power control architecture is
employed to minimize interference and maximize message capacity, The system could use a number of separate spread spectrum codes to facilitate load distribution within a cell site and between cell sites. The code reuse concept is analogous to the
frequency reuse technique currently in use in the existing cellular system.
In summary, the present invention provides for the following. First, it provides a means of radiating from a vehicle a signal in the transmit band of the national cellular telephone system without causing objectionable interference to the voice
telephone users of that band. Second, it provides a means for achieving vehicle location accuracies that are improved by greater than two orders of magnitude over that which is possible by the current transmissions in that band. Third, it incorporates
a means of achieving transmit power control of the vehicle transmitter to combat the extremely large variation (dynamic range) of radio signal path loss to the receiving sites. The main variables are distance and the multipath caused by intervening
obstructions to the line of site due to buildings, terrain features and other vehicles. Fourth, it incorporates a means of excising at the receiver the excessively strong conventional voice cellular signals that are not under power control which
ordinarily might interfere with the successful reception of the new broadband signals .
BRIEF DESCRIPTION OF THE DRAWINGS
The various features and advantages of the present invention may be more readily understood with reference to the following detailed description taken in conjunction with the accompanying drawings, wherein like reference numerals designate like
structural elements, and in which:
FIG. 1 illustrates a cellular system incorporating spread spectrum signal processors in accordance with the principles of the present invention;
FIG. 2 shows the details of a typical cell site incorporating the present invention;
FIG. 3 illustrates the details of the spread spectrum processor of FIG. 2;
FIGS. 4 and 5 illustrate typical vehicle transmitter configurations incorporating the principles of the present invention;
FIG. 6 illustrates a data processing station located in a regional location processing center that processes data obtained from signals produced in accordance with the principles of the present invention; and
FIG. 7 is useful in illustrating a technique for establishing power level control that employs a multi-step probe signal.
DETAILED DESCRIPTION
With reference to the drawings, FIG. 1 illustrates a cellular system 10 implemented using the principles of the present invention, and also illustrates the operation of the two main services provided by the present invention, namely, vehicle
location and messaging services. More specifically, the cellular system 10 includes a plurality of cell sites 13, 20-26. A first vehicle having a first vehicle transmitter 11 is located within a central cell site 20 while a second vehicle having a
second transmitter 12 is located within a local cell site 13. The first transmitter 11 is shown transmitting a vehicle location signal 28 to each of the local cell sites 20-26 adjacent thereto. The second transmitter 12 is shown transmitting a digital
message 18 or second spread spectrum signal 18 to the local cell site 13, while the local cell site 13 is shown transmitting a probe signal 29, which signals will be described in more detail below. The local cell site 13 and cell sites 20-26 (but not
shown for diagram clarity) are coupled to a mobile telephone switching office (MTSO) 14 by way of a microwave communications link 17 which in turn is coupled through a public switched telephone network 15 by way of the microwave communications link 17 to
a regional location processing center 16 using a wired connection path 30. The conventional aspects of the cellular system 10 are well known to those in the cellular communications art and the conventional aspects of its design and operation will not be
described in detail herein.
FIG. 2 shows the details of a typical cell site 21, but also includes a spread spectrum processor 40 in accordance with the principles of the present invention. The typical cell site 21 comprises an antenna 31 that is coupled to a low noise
amplifier 32. The low noise amplifier 32 is coupled by way of a 48:1 power splitter 33 to a plurality of receivers 34, typically a subset of the 333 possible receive channels assigned to a single service provider and then to a land based telephone
system. The output of the receivers 34 are voice signals that are coupled to the public switched telephone network 15. The spread spectrum processor 40 in accordance with the principles of the present invention is coupled to one output of the 48:1
power splitter 33 and is in turn coupled to the mobile telephone switching office (MTSO) 14, the public switched telephone network 15, and the regional location processing center 16, as described above.
The spread spectrum processor 40 of the present invention is designed to share the existing cellular frequencies, cell site real estate, cell site antenna towers and antennas, and cell site low noise amplifiers and cell site power splitters.
Thus, the incorporation of the processor 40 into the cellular system has the economic viability for both regional and nationwide deployment. In addition, the vehicular electronics package for use with the present invention (described with reference to
FIGS. 4 and 5 below) requires a much lower power transmitter because of the transmission distances are of the order of 20 miles, instead of 20,000 miles for systems that use satellites. Vehicular transmitter powers may be reduced from hundreds of watts
to less than one watt with a consequent downward revision in cost per transmitter 11.
The present invention permits dual usage of the frequency spectrum assigned for cellular telephone service. Currently voice conversations are supported by dividing the spectral space into individual 30 KHz channels. Cellular service suppliers
are assigned blocks of channels in contiguous fashion covering bandwidths in excess of 10 MHz. Through the use of unique spread spectrum waveforms (which spread energy over the full 10 MHz bandwidth), digital signalling is supported in the same spectral
space and in the presence of the existing voice traffic. At the same time no objectionable interference is generated to affect the existing traffic since the spread spectrum transmissions are either below the normal noise levels for digital messaging,
or of such short duration that they are imperceptible in the normal burst noise background for position location applications.
Spread spectrum processors, such as the spread spectrum processor 40 are generally well known in the art, and reference is made to U.S. Pat. No. 4,740,792, the contents of which is incorporated herein by reference. The spread spectrum
processor described therein may be readily adapted for use in the present invention. Modifications to the U.S. Pat. No. 4,740,792 processor and the characteristics of the present invention are described hereinbelow. In addition, the present invention
may employ a modified Position Location and Reporting System (PLRS) spread spectrum processor, which is manufactured by Hughes Aircraft Company, the assignee of the present invention, for the U.S. Army.
FIG. 3 illustrates the details of the spread spectrum processor 40 of FIG. 2. The spread spectrum processor 40 comprises a low noise amplifier 41 that is coupled to a hybrid coupler 42. One output of the hybrid coupler 42 is coupled to one or
more time of arrival correlators 43 that are adapted to respond to a Class I message (Code "A"), and transfer output signals therefrom through a data buffer 44 to the regional location processing center 16 by way of conventional telephone lines. The
correlator 43 is adapted to sort out signals that may overlap one another due to near-simultaneous, random transmission from different transmitters 11 so that corresponding time differences of arrival of signals received at different cell sites 20-26
transmitted by a particular transmitter 11 may be determined later at the regional location processing center 16 where the individual transmitter locations may be determined. The other output of the hybrid coupler 42 is coupled to a message preamble
correlator 45 comprising a bank of "P" correlators adapted to respond to a Class II message (Code "B"), and transfer output signals therefrom through a message correlator 46, comprising a bank of "M" correlators and a corresponding plurality of message
buffers, to the public switched telephone network 15 through the mobile switching office 14. The correlators and buffers comprising the message preamble correlator 45 and message correlator 46 are generally well known and will not be described in detail
herein. More detail of these types of devices are provided in U.S. Pat. No. 4,740,792.
FIG. 4 illustrates a typical vehicle transmitter 11 incorporating the principles of the present invention that may be employed for the purposes of transmitting emergency information, and the like. The transmitter 11 incorporates a reference
oscillator or clock 51, a sequencer or operation timer 52, a memory 53 comprising a PROM 54 and a buffer 55, a logic controller 56, a low pass filter 57 an exciter 58, a power amplifier 59, a pulse forming network 61, and an antenna 60. The exciter 58
comprises an UHF oscillator 63, a phase lock loop 64, and a summer 65. Also included are optional devices, including a motion sensor 66, a crash sensor 67, a vehicle anti-theft system 68 and a manual message selector 69.
The motion sensor 66 and crash sensor 67 preferably comprise conventional accelerometers which may be set or selected for different levels of acceleration. The anti-theft system 68 is any commercially available anti-theft apparatus that provides
an electric signal in response to vehicle intrusion, tampering or unauthorized movement. In turn, the message selector 69 may comprise a conventional keyboard or switch (not shown) by means of which several prestored message codes may be selected for
encoding in the transmission of the transmitter 11.
In operation, the sequencer 52 controls RF signal repetition rate and formating of a transmitted RF signal. The memory 53, which may comprise the PROM 54, and the data buffer 55, for example, contain signal formatting information, including a
transmitter identification code and specific message codes. Codes for a predetermined number of messages, and "accident" or "need assistance" codes may be stored in the PROM 54 and automatically selected by signals from the crash sensor 67 or anti-theft
system 68, or manually selected by the manual message selector 69, and which are transmitted under control of the logic controller 56.
Regarding the data transmitted by the transmitter 11, for vehicle location, a burst spread waveform pattern having a burst duration on the order of 10 milliseconds or less is employed to maximize location accuracy and to minimize interference
which is naturally suppressed by the clipping action of the existing narrowband cellular FM receivers. For vehicle location, the spread spectrum system employes rapid synchronization techniques and uses a single code for access to the system by the
transmitting vehicle.
In anti-theft applications, when it is necessary to make a number of sequential location measurements in a relatively short period of time, a waveform variant may be used. In this case, the entire band of cellular frequencies may be divided into
n (say 10) narrower spread spectrum channels with center frequencies at f.sub.1 through f.sub.n. Then each burst transmission (the pulse amplitude and duration remain unchanged) is sent at a new center frequency. The reduced bandwidth transmissions
sacrifices some location accuracy, but distributes the imperceptible voice channel blockage to a new set of voice users with each transmission. Thus, the non-objectionable interference characteristic is preserved.
FIG. 5 illustrates a typical vehicle transmitter 12 incorporating the principles of the present invention that may be employed for the purposes of transmitting messages. It is to be understood that the transmitters 11, 12 shown in FIGS. 4 and 5
may be integrated into one single transmitter, and are not limited to use as stand alone units. The transmitter 12 incorporates many of the components described with reference to FIG. 4, including the reference oscillator 51, the memory 53, the logic
controller 56, the low pass filter 57, the exciter 58, the power amplifier 59, and the antenna 60. Replacing the remainder of the components is a keyboard 66 that is coupled through a data buffer 67 to the logic controller 56. In operation, the logic
controller 56 selects respective inputs from either the keyboard 66 or the memory 53 for transmission from the transmitter 12 in a conventional manner.
Regarding the data transmitted by the transmitter 12, for messaging, a below the noise continuous wave (CW) spread spectrum waveform is employed which is naturally suppressed by the FM limiters in the existing narrowband cellular receivers 34
(FIG. 2). A service request and power control architecture is employed to minimize interference and maximize message capacity. For example, the system may employ a number of separate spread spectrum codes to facilitate load distribution within a cell
site and between cell sites. The code reuse concept is substantially analogous to the frequency reuse technique currently in use in the existing cellular system.
FIG. 6 illustrates a data processor 75 located in the regional location processing center 15 that processes vehicle location signals 29 produced in accordance with the principles of the present invention and transmitted from the cell sites 20-26
to the regional location processing center 16. The data processor 75 comprises a time of arrival (TOA) accumulator 77, a time difference of arrival (TDOA) processor 78, a data processor 79, an operator display and controller 80 and a subscriber
interface 81. The subscriber interface 81 comprises a plurality of modems 82 that are adapted to transmit computed location information to subscribers over conventional phone lines.
Time of arrival measurements made at the cell sites 20-26 are fed to the accumulator 77 where they are sorted by ID. The individual transmitter locations may be determined in a manner described in U.S. Pat. No. 4,740,792. More detailed
information regarding the design and operation of the transmitter 11 and data processing station may be had from a reading of U.S. Pat. No. 4,740,792.
With reference to FIG. 7, the technique for establishing power level control over the vehicle transmitters 11, 12 is as follows. One standard administrative cellular telephone channel (30 KHz wide) is set aside to communicate from cell sites 13,
20-26 to vehicles using the probe signal 29. Because of the greater transmit power available at cell sites, a high rate transmission, TDMA (time division multiple access) digital communications signal is employed. The probe signal 29 is transmitted
from cell sites 13, 20-26 to achieve an initial power level setting on the transmitters 11, 12 in vehicles that wish to communicate. On the assumption that most radio frequency transmission paths are bilateral, the probe signal 29 having the form shown
in FIG. 7 is employed. The probe signal 29 comprising a short duration pulse (approximately 8 msec) is transmitted every second from each cell site 13, 20-26 with a staircase power level that changes in intensity by 15 dB per step, for example. If the
step # signal is too weak to be heard by a particular vehicle transmitter 11, 12, the vehicle transmitter 11, 12 waits until reception is possible at one of the higher power levels. The transmission at each level contains information bits defining the
transmitted power levels, the cell site identification number, and the noise levels of signals at that cell site receiver. In this manner, the vehicle transmitter 11, 12 derives information enabling it to set its own power level for successful reception
at that site 13, 20-26. The signals transmitted from other cell sites 13, 20-26 are synchronized in time to assure that they do not overlap at a vehicle transmitter 11, 12. In this manner the optimum cell site receiver is selected. This minimizes the
transmit power thus maximizing the overall system capacity.
Referring again to FIG. 1, the overall operation of the system of the present invention will now be described. For vehicle location, the first vehicle transmitter 11 radiates a short (approximately 1 millisecond) burst of spread spectrum coded
location signal 28 utilizing a 5 megachip per second (for example) code rate. The short burst duration does not cause objectionable interference even at full power. Full power is used to help ensure reception at the more distant cell cites 21-26. In
this case the signal power is spread over a wide bandwidth (100 times the normal voice transmission bandwidth) and therefore its energy density is in the noise of the standard voice signal. The location signal 28 is received at cell sites 20-26, for
example. For proper location the location signal 28 need only be heard at three of seven adjacent sites 20-26. The spread spectrum signal processor 40 at each cell site 20-26 decodes the signal to determine the exact time of arrival of the signal, an
identification number of the vehicle transmitting the signal, and unique data bits that identify the class of service requested.
This decoded data is "packetized" and sent to the regional location processing center 16. The function of the regional location processing center 16 is to collect and sort all of the information packets concerning a single vehicle transmitter 11
and calculate the difference in the time of arrival of a single transmission burst at respective pairs of cell sites 20-26 that heard the signal 28. Each such pair creates a hyperbolic line of position. At the intersection of at least two of these
lines of position, a vehicle location is declared in two dimensional space.
For messaging service, for example, a transmitted message signal comprising the digital message 18 (second spread spectrum signal 18), need only be heard at a single cell site 15. Therefore the signal transmit level of the digital message 18 may
be reduced in amplitude from that of the vehicle location signal 28 when messages at 300 bits per second are sent, for example. The messages are typical data messages that are handled in the same manner as voice messages, except that the digital
messages are encoded by spread spectrum techniques. The digital message 18 is transmitted to the cell site 13 where its class is decoded. It is then transferred to the public switched telephone network 15 for transmission to the destination contained
in the digital message 18.
Two new classes of functionality are created by the present invention. Class I is digital messaging service that permits simultaneous transmission from nominally 100 vehicles each sending data messages at the rate of 300 bits per second to
access the public switched telephone network 15. The other class of digital signalling (Class II) provides for the accurate location of vehicles, with accuracies on the order of 100 feet. The applications of this technology are numerous. For instance,
if the motion sensor 66 or anti-theft system 69 (FIG. 4) identifies that a vehicle theft is in progress, the system permits location tracking of the vehicle which is reported to law enforcement officers in real time. Police, ambulance and/or tow truck
service may be directed to an exact location determined by the present system. Customized yellow pages directory service which depends on knowledge of vehicle location may also be provided.
In summary, the present invention achieves for the following. It provides for additional communication capability using the national cellular telephone system without causing objectionable interference to the voice telephone users. It provides
a means for determining vehicle location accuracies that are improved by greater than two orders of magnitude over that which is possible by the current transmissions in the cellular band. It provides for transmit power control of a vehicle transmitter
12 to combat the extremely large variation (dynamic range) of radio signal path loss to the cell sites 20-26. It employs an excisor which removes excessively strong conventional voice cellular signals that are not under power control which ordinarily
might interfere with the successful reception of the broadband spread spectrum signals 18, 28.
Presented below is analysis that illustrates the number of simultaneous spread spectrum transmissions that the system 10 supports without causing undue interference on the voice channels if the full 24 MHz of the cellular transmission frequency
band is used. The effect of the spread spectrum signals on a narrow band cellular channel is as follows. Given a 3 KHz voice information rate require a a 3 watt power level, a 300 Hz data information rate requires a a 0.3 watt power level. Therefore,
a+10 dB advantage exists for the voice signal. Given a 30 KHz voice transmission bandwidth, and a 24 MHz data transmission bandwidth, a+29 dB spreading factor exists. Therefore, a+39 dB voice signal advantage per spread spectrum signal exists. Given
a-20 dB loss for 100 simultaneous spread spectrum signals, the signal to noise ratio for the narrow band voice signal is+19 dB for 100 simultaneous spread spectrum channels, which is accepted as good quality by the cellular industry.
The effect of all the voice channel transmissions and the spread spectrum transmissions on the successful reception of a single object spread spectrum transmission is as follows. Given a 24 MHz data transmission bandwidth and a 300 Hz data
information rate, a 49 dB processing gain is achieved. If the cellular voice channels are fully loaded, there are 666 narrow band users using 3 watts of power, and this yields 2000 watts of noise (interference) power. If the spread spectrum channel is
fully loaded, there are 100 wide band users using 0.3 watts of power, which yields 30 watts of noise (interference) power. This results in a total noise (interference) power of 2030 watts. One spread spectrum user times 0.3 watts yields a 0.3 watt
signal power. Therefore, the input signal to noise ratio for the spread spectrum channel is-38 dB. If the processing gain is 49 dB, the output signal to noise ratio is then+11 dB. If there is a+9 dB threshold for adequate bit error rate performance, a
margin of 2 dB is provided. However, a communications network is rarely if ever fully loaded, so that additional margin is indicated.
The present invention also provides for flexibility in resource allocation that is achievable by the system 10 using spread spectrum modulation techniques. The present invention provides for matching the channel resource allocation to functional
needs, and permits simultaneous mix of different data rate users. For example, the present system permits 100 users to transmit at a 300 bit per second data rate using a 0.3 watt power level, or 10 users to transmit at a 3000 bit per second data rate
using a 3.0 watt power level, or 1 user to transmit at a 30,000 bit per second data rate using a 30.0 watt power level.
Thus there has been described a new addition to the existing cellular telephone system that employs spread spectrum transmission to provide additional services without imposing changes on existing system components and without degrading voice
communication. It is to be understood that the above-described embodiment is merely illustrative of some of the many specific embodiments which represent applications of the principles of the present invention. Clearly, numerous and other arrangements
can be readily devised by those skilled in the art without departing from the scope of the invention.
* * * * *
|
|
 |
|
 |
Description |
|
