U.S. patent application number 09/760193 was filed with the patent office on 2002-09-12 for long-range, full-duplex, modulated-reflector cell phone for voice/data trasmission.
Invention is credited to Briles, Scott D., Coates, Don M., Freund, Samuel M., Neagley, Daniel L..
Application Number | 20020128052 09/760193 |
Document ID | / |
Family ID | 25058384 |
Filed Date | 2002-09-12 |
United States Patent
Application |
20020128052 |
Kind Code |
A1 |
Neagley, Daniel L. ; et
al. |
September 12, 2002 |
Long-range, full-duplex, modulated-reflector cell phone for
voice/data trasmission
Abstract
A long-range communications apparatus utilizing
modulated-reflector technology is described. The apparatus includes
an energy-transmitting base station and remote units that do not
emit radiation in order to communicate with the base station since
modulated-reflector technology is used whereby information is
attached to an RF carrier wave originating from the base station
which is reflected by the remote unit back to the base station.
Since the remote unit does not emit radiation, only a low-power
power source is required for its operation. Information from the
base station is transmitted to the remote unit using a transmitter
and receiver, respectively. The range of such a communications
system is determined by the properties of a modulated-reflector
half-duplex link.
Inventors: |
Neagley, Daniel L.;
(Albuquerque, NM) ; Briles, Scott D.; (Los Alamos,
NM) ; Coates, Don M.; (Santa Fe, NM) ; Freund,
Samuel M.; (Los Alamos, NM) |
Correspondence
Address: |
Samuel M. Freund
Los Alamos National Laboratory
LC/BPL, MS D412
Los Alamos
NM
87545
US
|
Family ID: |
25058384 |
Appl. No.: |
09/760193 |
Filed: |
January 12, 2001 |
Current U.S.
Class: |
455/575.1 ;
455/129 |
Current CPC
Class: |
H01Q 3/2647 20130101;
H04B 1/38 20130101; H01Q 3/46 20130101; G01S 13/756 20130101 |
Class at
Publication: |
455/575 ;
455/129; 455/562 |
International
Class: |
H04B 001/00 |
Goverment Interests
[0001] This invention was made with government support under
Contract No. W-7405-ENG-36 awarded by the U.S. Department of Energy
to The Regents of The University of California. The government has
certain rights in the invention.
Claims
What is claimed is:
1. A radio communications system comprising in combination: (a) a
stationary system which comprises: (i) means for generating an
airborne carrier frequency; (ii) means for generating an airborne
radio communication; and (iii) means for receiving and demodulating
a modulated, reflected airborne carrier frequency; and (b) a mobile
unit which comprises: (i) data input means capable of generating
electrical signals; (ii) a passive transponder comprising: an
antenna having gain in a plurality of directions for receiving the
modulated carrier frequency; an impedance switch in electrical
connection with said antenna for varying the impedance thereof; and
means for receiving the electrical signals from said data input
means and for varying the impedance of said impedance switch in
response thereto, thereby modulating the carrier frequency by
varying the reflectivity of said antenna to the carrier frequency;
(iii) a radio receiver for receiving the airborne radio
communication from said means for generating an airborne radio
communication and generating electrical signals therefrom; and (iv)
data output means in electrical connection with said radio receiver
for receiving the electrical signals generated thereby and
generating an observable signal therefrom; whereby two-way radio
communication is established between said stationary unit and said
mobile unit.
2. The radio communications system as described in claim 1, wherein
said antenna comprises multiple facets, each facet being in
electrical connection with said impedance switch such that the
reflectivity of each of said facets is modulated thereby.
3. The radio communications system as described in claim 2, wherein
the number of facets is between four and eight disposed about an
axis of symmetry.
4. The radio communications system as described in claim 3, wherein
each of said facets comprises at least one microstrip patch.
5. The radio communications system as described in claim 3, further
comprising means for rotating said antenna about the axis of
symmetry.
6. The radio communications system as described in claim 1, wherein
said data input means comprises a microphone.
7. The radio communications system as described in claim 6, wherein
said data output means comprises a speaker.
8. The radio communications system as described in claim 2, wherein
the facets are arranged in the general form of a sphere.
9. The radio communications system as described in claim 8, wherein
each of said facets comprises at least one microstrip patch.
10. The radio communications system as described in claim 8,
further comprising means for rotating the sphere.
11. A radio communications system comprising in combination: (a) a
stationary system which comprises: (i) means for generating an
airborne carrier frequency having a first modulation thereon; and
(ii) means for receiving and demodulating a reflected airborne
carrier frequency having a first modulation and a second modulation
thereon; and (b) a mobile unit which comprises: (i) data input
means capable of generating electrical signals; (ii) a passive
transponder comprising: an antenna having gain in a plurality of
directions for receiving the carrier frequency having a first
modulation thereon; an impedance switch in electrical connection
with said antenna for varying the impedance thereof; means for
receiving the electrical signals from said data input means and for
varying the impedance of said impedance switch in response thereto,
thereby imparting a second modulation to the carrier frequency
having a first modulation thereon by varying the reflectivity of
said antenna to the carrier frequency having a first modulation
thereon; (iii) a radio receiver for receiving and demodulating the
airborne carrier frequency having the first modulation thereon and
generating electrical signals therefrom; and (iv) data output means
in electrical connection with said radio receiver for receiving the
electrical signals generated thereby and generating an observable
signal therefrom; whereby two-way radio communication is
established between said stationary unit and said mobile unit.
12. The radio communications system as described in claim 11,
wherein said antenna comprises multiple facets, each facet being in
electrical connection with said impedance switch such that the
reflectivity of each of said facets is modulated thereby.
13. The radio communications system as described in claim 12,
wherein the number of facets is between four and eight disposed
about an axis of symmetry.
14. The radio communications system as described in claim 13,
wherein each of said facets comprises at least one microstrip
patch.
15. The radio communications system as described in claim 13,
further comprising means for rotating said antenna about the axis
of symmetry.
16. The radio communications system as described in claim 11,
wherein said data input means comprises a microphone.
17. The radio communications system as described in claim 16,
wherein said data output means comprises a speaker.
18. The radio communications system as described in claim 12,
wherein the facets are arranged in the general form of a
sphere.
19. The radio communications system as described in claim 18,
wherein each of said facets comprises at least one microstrip
patch.
20. The radio communications system as described in claim 18,
further comprising means for rotating said spherical antenna.
Description
FIELD OF THE INVENTION
[0002] The present invention relates generally to wireless
voice/data transmission and, more particularly, to the use of
modulated-reflector technology for long-range and/or short-range,
full-duplex cell phone communications.
BACKGROUND OF THE INVENTION
[0003] In "Do Cell Phones Need Warnings" by Cathy Booth et al.,
Time, Oct. 9, 2000, it is stated that cell phone levels of
radiation must be below the Federal Communications Commission's
"specific absorption rate" ceiling which is a measure of the energy
in wafts per kilogram that one gram of body tissue absorbs from a
cell phone indicating that there is a possible danger of using a
cell phone.
[0004] A bidirectional communications link generally requires both
a power transmitter and a receiver at each end of the link.
Modulated microwave backscatter systems suitable for communications
over tens of kilometers have been developed. The primary advantage
of such systems is that bidirectional and high-bandwidth operation
can be achieved with a conventional microwave transmitter and
receiver at one end of the link, and a modulated reflector and
microwave receiver at the other end of the link, there being no
microwave energy generated by this end of the link. Transmission of
standard monochrome video data requires a communications channel
bandwidth of 4 MHz. However by using state-of-the-art
video-compression techniques, it is possible to convey one image of
standard video per second over a 5 kHz channel. Information rate
capacity of modulated reflector channels depends upon antenna
sizes, transmit power levels, background noise levels, distance
between the ends of the link, desired picture quality, and other
engineering tradeoffs.
[0005] In U.S. Pat. No. 5,075,632 for "Interrogation and Detection
System" which issued to Howard A. Baldwin et al. on Feb. 21, 1978,
a telemetering apparatus is described which includes a carrier wave
generator which generates at least a single frequency RF signal, a
transponder for receiving that signal and for amplitude modulating
it in accordance with information selected for transmission, an
antenna on the transponder for reflecting the amplitude modulated
signal, and a receiver which is preferably located at the generator
for processing the signal to determine the information carried
thereby. There need be no large power source at the location of the
transponder since no carrier signal is generated. Two or more
transponder antennas may be interconnected into an array so as to
receive and reflect a larger amount of carrier power. The carrier
from the interrogator (carrier wave generator) can be beamed
selectively to one or more transponders. Additionally, it is
possible to get response from one transponder to two or more
interrogators without interference by using different carrier
frequencies where the frequency difference is outside of the
modulation signal pass band. Baldwin et al. states that the carrier
frequency Information can also be sent to the transponder unit from
the interrogator by appropriately modulating the carrier sent from
the interrogator, which could be performed in such as manner as not
to interfere with the modulation superimposed on the reflected
carrier signal at the transponder, for example, by using
sufficiently separated modulation frequencies or by using different
forms of modulation. Baldwin et al. states further that radio
frequency transmitting and receiving antennas are well known to
those skilled in the art, but no description of antennas suitable
for this purpose is provided therein.
[0006] In U.S. Pat. No. 4,360,810 for "Multichannel Homodyne
Receiver" which issued to J. A. Landt on Nov. 23, 1982, a similar
modulated backscatter radio frequency identification system to that
of Baldwin et al., supra. Both of these communication systems are
half duplex or time-division full duplex, in that the interrogator
to transponder communications using amplitude modulation are
achieved during a certain time period, while transponder to
interrogator communications are performed during another period of
time.
[0007] Full duplex modulated-reflector communications links have
been proposed for short-range applications, such as inventory
control and livestock monitoring. For example, U.S. Pat. No.
5,649,296 for "Full-Duplex Modulated Backscatter System" which
issued to John Austin MacLellan et al. on Jul. 15, 1997, describes
a full duplex apparatus that can electronically update shelf-price
labeling for use in retail sales. In such a system, both the
interrogator and the transponder (or tag as the term is used in the
'296 patent) can transmit continuously and during the same time
period. The duplex communication system includes an interrogator
which generates a first modulated signal by modulating a first
information signal onto a radio carrier signal. This first
modulated signal is transmitted to at least one remote tag of the
system. The remote tag receives and processes the first modulated
signal received at its antenna. A backscatter modulator uses a
second information signal to modulate the reflection of the first
modulated signal from the antenna, the reflected signal being a
second modulated signal. The interrogator receives and demodulates
the second modulated signal to obtain the second information
signal. The antenna described in MacLellan et al. is a loop or
patch antenna, and an inexpensive, short range, bi-directional
digital radio communications channel is implemented. MacLellan et
al. also teach the use of phase modulation of the carrier signal
which would require a more complex radio receiver in the tag
capable of detecting phase-modulated signals. This phase-modulated
signal would be modulated and backscattered by the tag. Specific
implementations of this embodiment could include binary-phase-shift
keying in the downlink and frequency-shift keying in the uplink
(the path which is reflected and modulated by a device), or
binary-phase-shift keying in the downlink and amplitude modulation
in the uplink.
[0008] A similar technology may be found in U.S. Pat. No. 5,873,025
for "Modulated Backscatter Wireless Communication System Having An
Extended Range" which issued to James Gifford Evans et al. on Feb.
16, 1999. Evans et al. also discloses that the invention described
is relevant to any radio system utilizing modulated backscatter in
which the object is to extend the range of the uplink path.
[0009] Antennas for modulated reflectivity systems are designed for
reflecting a portion of the energy from the interrogator. Cell
phones, by contrast, use wire monopole antennas having small areas
and, therefore, poor ability to reflect incident radiation.
Moreover, the manner in which cell phones are utilized effectively
prevents alignment of the antenna with an incoming carrier wave. In
U.S. Pat. No. 6,034,639 for "Retractable Antenna For Portable
Communicator" which issued to Roger R. Rawlins et al. on Mar. 7,
2000, a retractable antenna which includes an elongated cylindrical
conductor enclosed by an elongated conductive sleeve is
described.
[0010] Other antenna designs for cell phones include U.S. Pat. No.
5,995,052 for "Flip Open Antenna For A Communication Device" which
issued to Robert A. Sadler et al. on Nov. 30, 1999, where a planar
antenna and a ground plane at a chosen angle therewith set for
optimal operation of the antenna for the frequency of the
communication device is described. The conductive element also
shields the antenna from the effects of the human body. U.S. Patent
No. 5,966,098 for "Antenna System For An RF Data Communications
Device" which issued to Yihong Qi et al. on Oct. 12, 1999 describes
a dipole antenna system which includes a first arm extending in a
first direction and a second arm extending in a second direction
that is not in the same line as the first direction. An
electromagnetic coupler provides coupling between each dipole arm
to establish a desired resonant bandwidth. Neither of these antenna
designs is suitable for a modulated-reflectivity communications
system.
[0011] U.S. Patent No. 5,903,826 for "Extremely High Frequency
Multipoint Fixed-Access Wireless Communications System" which
issued to Richard Joseph Nowak on May 11, 1999 describes a
directional antenna system for allowing access from a subscriber
location to a fixed-access wireless communications system having a
plurality of base-space stations which include a plurality of
angularly spaced directional antenna facets each capable of
receiving discriminately for a plurality of frequency sets two RF
signals having orthogonal polarization. The antenna provides an
angular coverage of 3600, one facet being focused on the
basestation. The purpose of this antenna design is to provide a
directional antenna for high frequency (approximately 30 GHz)
operation that permits the subscriber to receive the best signal
from a basestation which is not necessarily the closest base-space
station; however, the directional antenna must be able to
discriminate between which base-space station it is receiving the
signal from if the base-space stations are all transmitting at the
same frequency. The antenna is deployed in a cellular environment,
and the performances of the signals received by the antenna facets
are prioritized with the best performing facet being selected as
the default facet. This manner of operation contemplates an antenna
having a fixed, permanent spatial orientation. For bidirectional
systems, the '826 patent teaches that each antenna facet may have a
single component which functions both to receive and transmit, or
may have separate receive and transmit components. Nowak also
teaches a single antenna facet which is rotatable to a point in
various directions. The resting point of the rotatable facet would
be determined by the radio controller, and one of a finite number
of spaced angular positions would be chosen, each position assuming
the roll previously filled by one facet in the multi-facet
array.
[0012] Accordingly, it is an object of the present invention to
provide a long-range cell phone communications system which does
not emit significant radiation in order to respond to a received
signal.
[0013] Additional objects, advantages and novel features of the
invention will be set forth, in part, in the description that
follows, and, in part, will become apparent to those skilled in the
art upon examination of the following or may be learned by practice
of the invention. The objects and advantages of the invention may
be realized and attained by means of the instrumentalities and
combinations particularly pointed out in the appended claims.
SUMMARY OF THE INVENTION
[0014] To achieve the foregoing and other objects of the present
invention, and in accordance with its purposes, as embodied and
broadly described herein, the radio communications system hereof
includes: (1) a stationary system including: (i) means for
generating an airborne carrier frequency; (ii) means for generating
an airborne radio communication; and (iii) means for receiving and
demodulating a modulated, reflected airborne carrier frequency; and
(2) a mobile unit including: (a) data input means capable of
generating electrical signals; (b) a passive transponder which
includes: (i) an antenna having gain in a plurality of directions
for receiving the modulated carrier frequency; (ii) an impedance
switch in electrical connection with the antenna for varying the
impedance thereof; and (iii) means for receiving the electrical
signals from the data input means and for varying the impedance of
the impedance switch in response thereto, thereby modulating the
carrier frequency by varying the reflectivity of the antenna to the
carrier frequency; (c) a radio receiver for receiving the airborne
radio communication from the means for generating an airborne radio
communication and generating electrical signals therefrom; and (d)
data output means in electrical connection with the radio receiver
for receiving the electrical signals generated thereby and
generating an observable signal therefrom; whereby two-way radio
communication is established between the stationary unit and the
mobile unit.
[0015] It is preferred that the data input means includes a
microphone.
[0016] Preferably, the data output means includes a speaker.
[0017] Benefits and advantages of the present invention include a
handheld cellular phone unit that: (1) operates with little power
consumption, thereby permitting lengthy airtime and reduced battery
weight; (2) operates with no active RF radiation emitted from the
cell phone antennas, thereby reducing radiation exposure to users;
(3) operates over commercially viable long distances; (4) reduces
hazardous waste generation due to smaller battery requirements; and
(5) reduces spark generation potential for use in explosive
environments.
BRIEF DESCRIPTION OF THE DRAWINGS
[0018] The accompanying drawings, which are incorporated in and
form a part of the specification, illustrate the embodiments of the
present invention and, together with the description, serve to
explain the principles of the invention. In the drawings:
[0019] FIG. 1 is a schematic representation of a mobile,
half-duplex modulation reflector remote unit.
[0020] FIG. 2 is a schematic representation of the modulated
antenna, receiver antenna and controller subsystems of a cell phone
in accordance with the teachings of the invention.
[0021] FIG. 3 is a schematic representation of one embodiment of a
transmitter/receiver base station.
[0022] FIG. 4 is a schematic representation of a six-sided
embodiment of an antenna suitable for modulated reflection of a
carrier wave.
[0023] FIG. 5 is a schematic representation of a microstrip patch
antenna embodiment of the polygonal, multi-faceted modulated
reflector antenna of the present invention shown in FIG. 4 hereof,
where each facet of the antenna includes at least one patch
antenna.
[0024] FIG. 6a is a graph of the gain-area product versus
orientation for the six-sided stack antenna shown in FIG. 4 hereof,
while FIG. 6b shows a signal improvement of 9.5 dB from the
addition of the contributions from the several sides of the antenna
approximately facing the transmitter over the gain for a single
face.
[0025] FIG. 7 is a graph of the gain and antenna diameter versus
the number of sides of the polygon antenna shown in FIG. 4
hereof.
[0026] FIG. 8 is a schematic representation of a generally
spherical embodiment of the antenna suitable for practicing the
present invention, whereby the vertical orientation of the antenna
becomes less important than that for the antenna shown in FIG. 4
hereof.
DETAILED DESCRIPTION
[0027] Briefly, the present invention includes a portable,
long-range, full-duplex cell phone for voice/data transmission that
utilizes modulated-reflector technology. The apparatus includes an
energy-transmitting base station and remote units that do not emit
radiation. Rather, the remote units use modulated-reflector
technology to convey information to the base station by attaching
information to a carrier wave originating from the base station and
having radio frequency, RF, or higher frequencies; the range from
0.9 GHz to 30 GHz is contemplated. Since information from the
remote unit to base station is transferred without the remote unit
emitting radiation, only a low-power power source is required for
cell phone operation. Information from the base station to the
remote unit is transmitted using a transmitter at the base station
and a receiver located in the remote unit. The range of such a
communications system is determined by the properties of a
modulated-reflector half-duplex link.
[0028] The range of a modulated-reflector system can be determined
from the Radar Range Equation (RRE) as follows: 1 R max [ P t G t G
r 2 TL ( S o N o ) min ] 1 / 4 , where Equ . 1
[0029] R.sub.max is the maximum detection range (meters);
[0030] P.sub.t is the transmit power (watts);
[0031] G is the transmit and the receive antenna gain compared to
an isotropic antenna (base-station antennas);
[0032] .lambda. is the wavelength of the transmitted power
(meters);
[0033] .sigma. is the radar cross section of the portable unit
(meters squared);
[0034] T is the equivalent thermal noise temperature at the input
terminals of the receiver (K);
[0035] L is the loss factor that includes system, medium, and
propagation losses; and 2 S o N o
[0036] is the signal-to-noise ratio (SNR) at the receivers
output.
[0037] Antenna gain can be calculated from 3 G = 4 A 2 , Equ .
2
[0038] where A is the aperture area (meters squared) and .eta. is
the aperture efficiency, which is typically between 0.6 and 0.8 for
a planar antenna.
[0039] Reference will now be made in detail to the present
preferred embodiments of the invention which are illustrated in the
accompanying drawings. Similar or identical structure will be
identified using identical callouts. Turning now to FIG. 1, the
basic principles associated with modulated reflection are
illustrated. An antenna adapted to having its electrical impedance
modulated in response to data input interacts with an impinging RF
carrier wave. A single antenna is shown in the diagram. The plane
of the antenna must be aligned perpendicular to the direction of
the incoming carrier wave if significant reflection in the
direction of the base station is to occur. However, for cell phone
applications, reflectivity is required in many directions in order
to render the orientation of the antenna less critical, and because
the actual single direction in which reflection is required is not
known. One way this can be achieved is by using a multi-faceted
antenna, where at any given time the facet facing the carrier wave
will be most effective in reflecting energy back to the
transmitter. Another way to perform the same function is to rotate
a single faceted or multi-faceted antenna at sufficiently high
speed of rotation that the transmitted modulated signal will not be
affected and many directions will be covered by the facets.
[0040] Shown in FIG. 1 is antenna, 10, onto which RF carrier wave,
12, from a remote base station impinges. Antenna 10 is electrically
connected to an electronically controllable impedance switch, 14,
which permits the impedance of the antenna to be rapidly varied. As
an example, a PIN diode could be used to switch the antenna
impedance between a large value and zero, where the closed circuit
effectively grounds the antenna. Other devices, such as a ring
mixer, can be used for impedance switching. The bandwidth of the
switch determines the bandwidth of the modulation.
Voltage-controlled oscillator (VCO), 16, provides a sine-wave or a
square-wave which is responsive to digital input, 18. The source of
the digital signal can be compressed digital audio, telemetry,
etc., as examples. Both FSK modulation and analog FM modulation are
possible. The frequency range of the VCO is such that appropriate
IF frequencies are generated and such that the IF frequency can be
switched sufficiently rapidly for the input-data rate. Biasing
circuit, 20, provides the needed bias voltage and waveform shaping
to insure proper operation of the impedance switch 14 in response
to VCO 16.
[0041] When antenna 10 is illuminated with RF radiation from a
transmitter of such radiation, the quantity of RF energy reflected
in the direction of the source depends on the impedance experienced
by antenna 10. The reflective characteristics of an antenna can
thus be used to modulate the amplitude of a reflected radio
frequency (RF) wave. Amplitude modulation (AM) is achieved by
modulating the impedance of the antenna between an open circuit and
a matched impedance load. If an ideal antenna is connected to an
open-circuit, all the impinging energy is re-radiated by the
antenna. By contrast, no energy is re-radiated from an antenna that
is terminated with a load that is exactly matched to the antenna.
If the load on the antenna is maintained between the limits of an
open circuit and a matched load, then some of the impinging energy
will be re-radiated and some will be absorbed.
[0042] Another form of modulation that can be introduced onto a RF
wave is frequency modulation (FM). For FM, the modulated reflector
must have its impedance controlled such that the phase of the
reflected energy is modulated by the modulated antenna. By altering
the terminating impedance of the modulated reflector between an
open circuit and a short, the reflective carrier wave varies in
phase between 180.degree. and 0.degree.; the modulating waveform is
a square-wave and not a sinusoid. The rate of this variation
between these two phases determines the modulating frequency. If
frequency shift keying (FSK) is used to transmit a "m-ary", where m
is any integer, sequence, each state is assigned a frequency, and m
frequencies are used to transmit the sequence of symbols. At any
given instance, the frequency of modulation corresponds to the
m-ary symbol in the data sequence. Modulation and demodulation for
this FM imposed on the carrier wave by the modulated reflector
requires that the modulation frequencies of the FSK signal are
above any frequency that could be produced by Doppler effects.
Energy contained in the harmonics of the modulating frequency could
be used to improve signal range by using harmonics in the frequency
discrimination process. However, this addition of harmonics
generally increases the bandwidth and decreases the signal-to-noise
ratio. By using digital radio technology which employs frequency
selective digital filters, several harmonics can be included in
signal demodulation without including the noise in portions of the
band where a harmonic is not present. For each frequency of the FSK
modulation, a set of digital filters would be used to determine
whether that frequency was being imposed on the carrier.
[0043] It should be mentioned that for modulation to be applied to
a propagating electromagnetic wave only a change in relative
wave-path potentials is required. Thus, the wave-path impedance is
modulated, and a true earth ground is unnecessary since absolute
potentials are not involved.
[0044] As stated hereinabove, the long-range cell phone
communication system of the present invention includes two major
subsystems in addition to the circuitry generally found in cell
phones and other similar communication devices. First, a mobile
handheld unit having a first antenna designed as a reflector for
long-range modulated reflection, and a second antenna for receiving
signals sent to the mobile unit. Voice compression and
error-correcting hardware and software, a detector, processor,
display, battery, keypad, speaker, microphone and a modulator
control unit are also anticipated to be included in the cell
phone.
[0045] A base station, or cell phone tower which in one embodiment
has a first antenna for transmitting a carrier signal, a second
antenna for receiving the weak reflected signal from the mobile
unit, and a third antenna for transmitting a voice conversation
signal to the mobile unit. The use of digital beam-forming (phased
array), high temperature superconducting receiver circuits, digital
radio reception, and digital-signal processing (DSP) are also
contemplated, as are use of a transmitter, analog-to-digital
converters, RF power splitters, amplifiers, and filters.
[0046] FIG. 2 shows a preferred embodiment of a cell phone handset
in accordance with the teachings of the present invention. Three
subsystems are illustrated: modulated antenna subsystem, 22, which
is similar to that shown in FIG. 1, hereof; incoming signal
receiving subsystem, 24; and control subsystem, 26. Modulated
antenna subsystem 22 includes impedance switch 14, VCO 16, and
biasing electronics 20. In the cell phone of FIG. 2, digital input
18 of FIG. 1 includes microphone, 28, analog-to-digital converter,
30, and speech compression electronics, 32, and error control
coding, 34, to reduce the bandwidth of the voice transmission.
Receiver system 24 includes receiver antenna, 36, RF receiver, 38,
demodulator, 40, digital-to-analog (DIA) converter, 42, and
speaker, 44. Controller subsystem 26 includes controller processor,
46, keypad, 48, display, 50, phone identification (ID) circuitry,
52, and an optional global positioning system locator, 54. A
low-power battery, 56, powers all of the low current electronic
circuits for the three subsystems. It should be mentioned that
battery 56 is not required for transmitting voice or other data
from the cell phone to the base station. This permits lengthy cell
phone use time since transmission generally consumes between 80%
and 90% of the battery power in a conventional cell phone.
[0047] With decreased electrical power requirements for electronic
devices, a cell phone that could operate using solar cells and/or
power extraction from the surrounding RF environment could be
built.
[0048] A bidirectional communications link that has a nonradiating
mobile end can be implemented using modulated reflectors and an
appropriately configured base station. FIG. 3 is a schematic
representation of a base station configuration for the cell phone
system of the present invention. Shown in FIG. 3 is a carrier wave
transmitting antenna, 58, a receiving antenna, 60, for the
modulated carrier wave generated by the remote unit, and a data
transmitting antenna, 62, with transmitter, 64, for sending
information to the remote unit which information is received by
receiver antenna 36 thereof. Because only an small portion of the
transmitted carrier wave power is ultimately returned to receiving
antenna 60 at the active end of the link, coherent detection
techniques are employed. For example, the output from local
oscillator, 66, is divided using splitter, 68, and used with both
amplifier, 70, as the transmitter oscillator to drive transmitter
antenna, 58, and to mix with the modulated signal received by
receiver antenna 60 which is used to detect and extract information
sent from the passive end using mixer, 72.
[0049] There is a division between the tasks of transmitting a
carrier wave and receiving the modulated reflected wave from the
cell phone. However, local oscillator 66 generates a signal common
to the two functions, assuming separate antennas. This is what
enables the modulated reflector signal to be detected and
demodulated using well known mixing procedures. Carrier
transmitting antenna 58 emits a single carrier frequency. However,
multiple carrier signals may be emitted at the same time to
communicate with multiple cell units. Such a transmitting antenna
must generate large amounts of RF power; electronically controlled
gain is not needed. Local oscillator 66 provides the carrier
frequency, or frequencies, for multiple modulated reflectors.
Receiver antenna 60, by contrast, must process the low-energy
signals that have been reflected from the modulated reflector. By
dividing the generated carrier frequency (using splitter 62) such
that the bulk of the energy is directed to the transmitting
antenna, the receiver will be able to mix (using mixer 72) the
received reflected, modulated carrier signal with the transmitted
carrier frequency, the result being a baseband which allows for
better reception of the reflected modulated energy and eliminates
distortion upon down conversion. Electronically controlled gain and
low-noise electronics are also employed to extract the low-energy
signals. Before down-spectra conversion, the signal is filtered,
74, and amplified, 76, to allow the mixer to perform efficiently.
Once the signal received from the modulated reflector is
down-converted to base band in mixer 72, standard demodulation
techniques are applied to the signal depending on the
characteristics of the waveform. If square wave (FSK) modulation is
used, the bandwidth should allow for multiple odd harmonics to be
included in the demodulation process. This is achieved using
filters, 78, and 80, and the amplified signal, 82, is analyzed
using frequency discriminator/demodulator, 84.
[0050] For multiple remote cell phones to communicate with a single
base station, additional complexity is involved. Each remote unit
is assigned a different frequency that is close to their
fundamental frequency. For example, for a 900 MHz system, several
carrier frequencies may be radiated from the base station which
differ by 100's of kHz. Another approach would be to use
time-division multiplexing, where each remote unit would be
assigned a portion of a period of time to communicate with the base
station. Still another approach is where each cell phone tags data
in a unique fashion or modulates the carrier at a unique rate.
[0051] It is desirable that the transmitter antenna direct a
carrier wave at a remote unit. Clearly, the more directional this
antenna is, the greater the range of communications. Several
transmit antennas may be associated with a single base station in
order to produce this gain (i.e., directionality). Although the
receive antenna of the modulated-reflector link can use advanced
digital signal processing (DSP) to increase its gain, adaptive beam
forming technology can simulate an antenna of higher gain. Thus,
real-time DSP can be used to direct a high-gain antenna pattern at
the remote unit. A parameter of the RRE (Equ. 1) that is not
associated with the transmitter/receiver is the radar cross section
(RCS). This is conceptually the area of a flat-plate reflective
surface that could replace the target and still reflect an
equivalent amount of energy. In the case of the target being a
modulated reflector, the RCS term can be replaced with an equation
representing the appropriate amount of reflected energy. First, the
modulated reflector is an antenna with an antenna-aperture cross
section that accounts for energy captured. This is the RCS
equivalent to a true flat-plate reflector. Since not all the
captured energy will be available for modulation, the antenna
efficiency must be included to account for this loss. The energy
that is available for modulation is not totally modulated. There is
a modulation efficiency associated with the modulated reflector
that is typically 0.60. The modulated energy is then radiated by
the antenna and thus the antennas gain must be taken into account.
This leads to the following equation for the RCS of a modulated
reflector:
.UPSILON.=A.eta.G.sub.mod reflector.eta..sub.m. Equ. 3
[0052] where .eta..sub.m is modulation efficiency.
[0053] Substitution of Equ. 2 and Equ. 3 into Equ. 1 yields a
formula that can be used to determine the maximum distance that a
modulated-reflector communications system can operate. The
bandwidth of the communication system is taken into account in the
B term of the original RRE. From Equ. 1, it is seen that the
smaller the bandwidth, the greater the range.
[0054] Another factor to consider is receive-input noise
temperature, T. This factor depends on the wavelength used, but a
conservative estimate of its value would be 290 Kelvin. By using
high-temperature superconducting technology, this noise temperature
can be reduced to yield a greater communications range. The noise
figure and total loss, which have the same impact as temperature,
can be conservatively estimated as having a value of 8 dB and 6 dB,
respectively.
[0055] Acceptable values to use for SNR which appears in the
denominator of Equ. 1 will be different between a radar ranging
application and a communications link application. In radar range a
value of 0 dB for SNR is acceptable. However, for a communications
system where a signal must be demodulated, an acceptable value is 3
dB. This 3-dB value relies on a digital communications link and
error-correcting coding being included in the digital stream.
[0056] The numerator of Equ. 1 shows that the gain of the
transmit/receive (T/R) antenna is highly influential, as is the
carrier wavelength, .lambda.. Currently, cellular communications
operate at 900 MHz frequency (.about.333 mm wavelength) and 2.4
GHz. Examining Equ. 1 in combination with Equ. 2, shows that the
range increases as the wavelength decreases (i.e., as frequency
increases). However, above 10 GHz, losses increase due to
atmospheric effects. For a given operating frequency, the maximum
range of the communications link is dependent on the transmit
power, and the area of the T/R antenna and the modulated reflector
antenna. Assuming a small-modulated reflector antenna, a suitable
value would be 6 in.sup.2. Assuming the T/R antenna would be
mounted on a tower, a 6-ft-by-6-ft square antenna area would be
feasible. The relationship between transmit power and maximum
communication range can be evaluated graphically using the values
given above to completely evaluate Equ. 1. If the intended
communication is voice, then a realistic bandwidth would be 2400 Hz
for compressed telephony.
[0057] Each of the two half-duplex communications links in
accordance with the present invention has a different range
limitation. The half-duplex information link from the base station
to a remote unit is a standard transmitter/receiver link and as
such is governed by familiar power/range requirements. The
half-duplex information link from a remote unit to the base station
is a modulated-reflector link. As a modulated-reflector link,
energy must perform a round-trip journey (base station to remote
unit to base station) to relay information. This
modulated-reflector link will most likely require greater
origination power than the other half-duplex link. However, the
modulated reflector link is capable of achieving useable ranges
with common transmit-power levels. For example, 1/2 kW of transmit
power for 900-MHz voice communications would have a maximum range
of approximately 6 km. Such a range could support a communications
cell.
[0058] The communication link between the remote unit and the base
station is established under two operational scenarios depending on
the initiator of the link. If the base station (that is, another
user connecting to the base station) is to establish the
communications link, the conventional radio receiver (callout 26 of
FIG. 2) of the remote unit would first be contacted. The remote
unit would then modulate its reflectors in order to exchange
information with the base station. The base station would
continuously perform a search by altering its antenna beams to
maximize the signal from the remote unit requesting service.
Information exchange between the base station and the remote unit
would then complete the communications link. If the remote unit is
to establish the communications link, the remote unit would first
modulate its reflectors in a narrowband manner. The base station,
which would always be scanning for access-requesting remote units,
would detect and demodulate energy reflected from the remote unit
to begin the process of establishing a more efficient
communications link. The conventional transmit/receiver radio link
between the base station and the remote unit would again be used to
complete the communications link.
[0059] As shown in FIG. 3, the base-station has two antennas for
the modulated-reflector link, a transmit antenna 62 and a receive
antenna 60. The transmit antenna directs a carrier wave at a remote
unit. The more directional this antenna is, the greater the range
of communications. Antenna gain can be adjusted directionally
(i.e., steering of the antenna's beam or main lobe) without
physically moving the antenna. This beam steering technology is
known as phased-array antenna technology or in a more general sense
beam forming technology. Phased-array antenna technology allows for
the greatest gain of transmit and receive antennas, which are
located at the base-station, to be electronically steered at the
remote unit. This steering of the gain for both antennas greatly
increases the maximum operational range of the modulated-reflector
communications link. By adjusting the phase path of individual
antenna elements, the transmitted signal can be electronically
scanned or directed without the involvement of mechanical motion.
The reception of the modulated-reflected energy is greatly enhanced
by allowing the phase difference from individual antenna elements
to be altered using digital signal processing. This, in effect,
creates antenna gain that can be adaptive and controlled for
several different remote units.
[0060] The maximum antenna gain for the modulated reflector
communications link occurs when one of the antennas of the link is
oriented normal to the carrier wave transmitting antenna.
Similarly, performance will be below this maximum when no antenna
of the structure is normal to the transmitting antenna. The design
of the modulated-reflector antenna must provide for directionality
when the direction to the base station is unknown. In order to
achieve this directionality, a multi-faceted antenna system has
been designed which has gain in all directions. Since no energy is
being transmitted by the modulated reflector and the impedance of
several individual antennas can be controlled by a single diode,
the modulation of several individual antennas does not degrade of
the system in comparison to a single antenna design. A multifaceted
antenna then, provides the remote modulated-reflector with gain
over 360.degree..
[0061] FIG. 4 shows a schematic representation of multifaceted
antenna design suitable for cell phone use. Facets, 86a-86c, and
88a-88c, are three of six facets in each of the two stages of the
antenna illustrated in FIG. 4. Each of the facets is placed in
parallel electrical connection with the other facets and is
modulated using the impedance switch 14 shown in FIG. 2 hereof. The
combination of two six-sided structures, one stacked upon the other
and rotated with respect to each other by 30.degree., reduces
decreases in the gain of a single, six-sided antenna structure.
Thus, the normal face of one structure is located between two
closely aligned faces of the structure above or below it and, as
will be shown hereinbelow, a more uniform antenna gain is presented
to the transmitting antenna. It should be mentioned at this point
that since the stages are shown to have different dimensions, one
stage can be rotated with respect to the other and the pair of
stages collapsed for storage, forming thereby a compact, nested
structure. Additionally, the entire structure can be rotated about
its axis in order to reduce the dependence of antenna gain on
antenna orientation. Also shown in FIG. 4 is means, 90, for
rotating antenna 10 about its axis, 92.
[0062] FIG. 5 is a schematic representation of a microstrip
resonant-cavity patch antenna embodiment of the multi-faceted
modulated reflector antenna of the present invention. Shown are
patch conductors, 94a-94c, which are located on a dielectric slab,
96, in contact with ground-plane conductor, 98, which extends
beyond the patch. The patch surface and the ground plane surface
are generally fabricated from gold alloy or copper alloy, and each
microstrip represents a face (86 or 88) of the multi-faceted
antenna shown in FIG. 4 hereof. Depending on the frequency of
interest and the material's dielectric constant at that frequency,
the dielectric layer's thickness determines the size of the etched
patches and the gain of the antenna. Materials with a dielectric
constant of .gtoreq.2 for the frequencies of interest are common.
For example, Polystyrene has an approximate dielectric constant of
2.5 for a frequencies between 2 and 4 GHz. By contrast, the ceramic
material, Coors Al-200 has an approximate dielectric constant of
8.8 at a frequency of 2.4 GHz. The dielectric material can also be
used to determine the thickness of the microstrip patch antenna or
the size of the antenna. Frequencies of operation between 900 MHz
and 2.4 GHz require a patch size of approximately 2.5 cm. From
this, the size of the antenna can be determined.
[0063] FIG. 6a is a graph of the gain-area product versus
orientation for the six-sided stack antenna shown in FIG. 4. The
figure compares the four sides that are adjacent to the
normal-facing side in terms of both energy captured and energy
redirected. Energy from all five sides, the normal-facing side and
its four adjacent sides, is directed back to the carrier-transmit
tower. The energy from all five sides combine in a constructive
manner to increase the power of the signal observed at the tower.
FIG. 6b shows a signal-power improvement of 9.5 dB from the
addition of the contributions from the five sides of the antenna
approximately facing the transmitter compared to just the
signal-power for a single face. This includes the contribution from
both stages of the antenna; that is, since the modulation is
anticipated to include frequency-shift keying (FSK), it is possible
to add the signals from all of the facets. The important factor in
the reception of the data stream (binary or greater) is the
frequency recovered over the bit-time interval and not the absolute
phase of the signal. Assuming that the size of each modulated
reflector facet is proportional to the wavelength in use, the phase
shift among the five return reflections of greatest amplitude will
be less than a quarter wavelength. Thus, the five signals will sum
constructively in time because the phase difference between any
pair of signals is less than 45.degree.. Even though the four
adjacent sides to the normal-facing sides collect less energy than
the normal-facing side and their redirection of captured energy is
biased away from the normal direction, the four sides still produce
a positive contribution of significance.
[0064] FIG. 7 is a plot of the power gain for multi-faceted
polygonal antennas and the size of such antennas as a function of
the number of sides of the antenna, assuming a patch size of 2.5
cm. As can be seen from the graph, the antenna diameter grows
approximately linearly as the number of sides of the polygon
increases, while the power gain grows rapidly initially and then
experiences a more level rate of growth. Therefore, it appears that
6 to 8 sides is a reasonable compromise.
[0065] FIG. 8 is a schematic representation of a generally
spherical embodiment of the antenna suitable for practicing the
present invention, whereby the vertical orientation of the antenna
becomes less important than that for the antenna shown in FIG. 4
hereof. Icosahedral configuration, 100, has at least one patch
antenna 94 on each face 86, thereby permitting gain in a plurality
of directions including gain away from a generally horizontal
direction. Means 90 for rotating the approximately spherical
antenna 10 are also shown in FIG. 4. Clearly, spherical
configurations having fewer or greater than 20 faces are
contemplated by the present invention.
[0066] The foregoing description of the invention has been
presented for purposes of illustration and description and is not
intended to be exhaustive or to limit the invention to the precise
form disclosed, and obviously many modifications and variations are
possible in light of the above teaching. For example,
hi-temperature super conductors might be used in the base station
receiving antenna for improving the signal-to-noise ratio of the
received signal from the modulated signal of the cell-phone,
thereby increasing the effective range of the cell-phone. Moreover,
the use of voice compression and error-correcting coding in the
cell-phone handset would provide for a lower bandwidth modulated
signal (more range) with less error (distortion) over a greater
distance. Since the current cell-phone market seems to be migrating
to a CDMA (Code Division Multiple Access) based system, it is
envisioned that the cell-phone system of the present invention
would also utilized CDMA.
[0067] The embodiments were chosen and described in order to best
explain the principles of the invention and its practical
application to thereby enable others skilled in the art to best
utilize the invention in various embodiments and with various
modifications as are suited to the particular use contemplated. It
is intended that the scope of the invention be defined by the
claims appended hereto.
* * * * *