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Claims  |
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What is claimed is:
1. A two-way communications system for a generally enclosed space employing
a base infrared transmitter and a base unit infrared receiver that
communicate through a variable or undefined length optical path at carrier
frequencies respectively with an up-link infrared receiver and from an
up-link infrared transmitter, and a base unit for generating transmission
signals for the base transmitter and for receiving signals from the base
receiver, comprising:
said base infrared transmitter including a plurality of base unit infrared
transmitter modules placed at distributed locations within the space to
generate infrared light signals, first cable means for coupling the
transmission signals from the base unit to the base unit transmitter
modules so as to cause the transmission of infrared light therefrom
towards the up-link infrared receiver;
said based infrared receiver including a plurality of base unit infrared
receiver modules placed at distributed locations within the space to
detect light from the up-link infrared transmitter and produce at carrier
frequencies output signals representative thereof, and second cable means
for coupling the output signals from base unit infrared receivers to the
base unit, means for combining said output signals from base infrared
receiver modules and generating a level signal representative of the
combined infrared energy detected at base unit receiver modules.
means responsive to the level signal for varying the base transmission
signals so as to establish, from the up-link infrared transmitter, an
optical output level that is at a level needed for detection by at least
one of said distributed base unit infrared receiver modules; wherein a
plurality of base unit infrared transmitter and receiver modules and a
plurality of up-link infrared transmitters and receivers operate at
different carrier frequencies for operation in different frequency
channels;
with base-unit infrared receiver modules operative in different frequency
channels being placed in proximity to each other so as to effectively have
a common optical field of view.
2. The two-way communication system as claimed in claim 1 wherein:
base unit infrared transmitter modules operative in different frequency
channels are placed in proximity to each other so as to effectively have a
common optical field of view.
3. The two-way communication system as claimed in claim 1 wherein said base
unit infrared receiver modules and transmitter modules each comprise:
a housing having an end-located infrared port and mounted so as to tilt
with the port facing downwardly from horizontal; and
infrared optical means mounted in a recessed position within the housing so
as to avoid dust contamination.
4. A two-way communications system for a generally enclosed space employing
a base infrared transmitter and a base unit infrared receiver that
communicate through a variable or undefined length optical path at carrier
frequencies respectively with an up-link infrared receiver and from an
up-link infrared transmitter, and a base unit for generating transmission
signals for the base transmitter and for receiving signals from the base
receiver, comprising:
said base infrared transmitter including a plurality of base unit infrared
transmitter modules placed at distributed locations within the space to
generate infrared light signals, first cable means for coupling the
transmission signals from the base unit to the base unit transmitter
modules so as to cause the transmission of infrared light therefrom
towards the up-link infrared receiver;
said base infrared receiver including a plurality of base unit infrared
receiver modules placed at distributed locations within the space to
detect light from the up-link infrared transmitter and produce at carrier
frequencies output signals representative thereof, and second cable means
for coupling the output signals from base unit infrared receivers to the
base unit, means for combining said output signals from base infrared
receiver modules and generating a level signal representative of the
combined infrared energy detected at base unit receiver modules,
means responsive to the level signal for varying the base transmission
signals so as to establish, from the up-link infrared transmitter, an
optical output level that is at a level needed for detection by at least
one of said distributed base unit infrared receiver modules; wherein
said base unit infrared receiver modules have sufficient bandwidth to
provide a plurality of separate frequency channels for receiving infrared
signals from up-link infrared transmitters respectively operating in said
separate frequency channels.
5. The two-way communication system as claimed in claim 4 wherein said
means for establishing the desired optical output level comprises for each
frequency channel:
means responsive to the level signal for varying the carrier frequency for
a frequency transmitter;
means in an up-link infrared receiver for detecting the deviation of the
carrier frequency from a desired portable receiver passband location and
produce an infrared transmitter power setting signal indicative thereof;
and
means responsive to the power setting signal for varying the magnitude of
the infrared optical output from the portable transmitter in a direction
so as to maintain said level needed for detection.
6. The two-way communication system as claimed in claim 5 wherein said
carrier frequency deviation sensing means is referenced with respect to a
center pass band location.
7. A two-way communication system for a generally enclosed space employing
infrared communication at carrier frequencies between a base unit and
remote locations, comprising:
base unit means for generating signals for transmission at carrier
frequencies;
means including a plurality of up-link infrared transmitter modules placed
at distributed locations within the space to generate infrared signals,
first cable means for coupling the base unit to the up-link infrared
transmitter modules so as to reproduce infrared signals at carrier
frequencies therefrom;
means including a plurality of down-link distributed infrared detector
modules for detecting infrared communications from remote locations at
carrier frequencies and reproducing said infrared communication in the
form of electrical signals at said latter carrier frequencies; and second
cable means for coupling said latter electrical signals to said base unit
means at said carrier frequencies; and
wherein said base unit means includes means for combining said electrical
signals from infrared detector modules at carrier frequencies to produce
an output signal representative of a communication from a remote location.
8. The two-way communication system as claimed in claim 7 wherein DC power
is provided and wherein the second cable means is connected to deliver
said DC power to said detector modules.
9. The two-way communications system as claimed in claim 8 wherein said
first cable means is connected to deliver said DC power to said
transmitter modules.
10. The two-way communication system as claimed in claim 9 wherein DC power
is provided and wherein said first and second cable means comprises
coaxial cables having inner and outer conductors, said inner conductor
being effectively coupled to transfer carrier frequencies and DC power to
the infrared transmitter and detector modules.
11. The two-way communication system as claimed in claim 7 and further
comprising:
means responsive to combined electrical signals for generating a level
signal representative of the combined infrared energy detected by the
infrared detection modules.
12. The two-way communication system as claimed in claim 7 wherein said
infrared detector modules have sufficient bandwidth to provide a plurality
of separate frequency channels for receiving infrared signals from remote
locations respectively operating in said separate frequency channels.
13. A two-way communication system for a generally enclosed space employing
infrared communication at carrier frequencies between a base unit and
remote locations, comprising:
base unit means for generating signals for transmission at carrier
frequencies;
means including a plurality of up-link infrared transmitter modules placed
at distributed locations within the space to generate infrared signals,
first cable means for coupling the base unit to the up-link infrared
transmitter modules so as to reproduce infrared signals at carrier
frequencies therefrom;
means including a plurality of down-link distributed infrared detector
modules for detecting infrared communications from remote locations at
carrier frequencies and reproducing said infrared communication in the
form of electrical signals at said latter carrier frequencies; and second
cable means for coupling said latter electrical signals to said base unit
means at said carrier frequencies;
wherein the second cable means comprises a common cable connected to each
said detector module; and
wherein the base unit means further comprises means for combining said
electrical signals at carrier frequencies to produce an output signal
representative of a communication from a remote location.
14. The two-way communication system as claimed in claim 13 wherein said
second common cable means comprises a coaxial cable having inner and outer
conductors, said inner conductor being effectively coupled at both carrier
frequencies and at DC to the infrared detector modules.
15. The two-way communication system as claimed in claim 13 and further
comprising:
means for generating a level signal representative of the combined infrared
energy detected by the infrared detection modules. |
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Claims |
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Description |
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FIELD OF THE INVENTION
This invention generally relates to a two-way infrared communication system
for an enclosed space and more specifically to such a system with a
plurality of infrared channels for use within a common enclosure such as
an office, factory, or warehouse, and the like.
BACKGROUND OF THE INVENTION
A full two-way infrared telephone system exists as described in my
copending U.S. patent application Ser. No. 619,803, filed June 12, 1984,
now U.S. Pat. No. 4757553 entitled COMMUNICATION SYSTEM WITH PORTABLE
UNIT. This patent application is incorporated herein by reference. The
infrared telephone system uses a cordless handset that is portable as with
rf cordless telephones. The infrared telephone system includes a base unit
having an up-link infrared transmitter to send an audio FM modulated
infrared carrier to the handset receiver and a base unit infrared receiver
to detect an audio FM modulated infrared carrier back from a handset
located infrared transmitter. Battery power of the portable handset is
conserved by use of a power control circuit whereby the optical power from
the handset, or down-link infrared transmitter, is kept at a minimum level
needed to obtain good performance. This is achieved by sensing the level
of the infrared signals at the infrared receiver in the base-unit and then
varying the average frequency of the carrier applied in the base unit to
the up-link infrared transmitter. This carrier frequency shift is sensed
in the handset and used to vary the optical power from the handset
completing a control loop. In the process the up-link carrier frequency is
controlled at the center of the pass band of the handset infrared
receiver.
SUMMARY OF THE INVENTION
In a two way infrared communication system in accordance with the invention
reliable and full coverage infrared communication can be established over
variable length optical paths within an enclosed area such as an office,
factory, storage area, telephone exchange, a vehicle and the like.
This is achieved in one embodiment in accordance with the invention with a
base unit that is connected to a plurality of spatially distributed
infrared transmitter modules and infrared receiver modules so that a
portable, or down-link, infrared communicator may establish communication
with the base unit. The optical power signal from the portable unit is
controlled by detecting the level of the combined base receiver module
output which is representative of optical power incident upon them. This
detected level signal is relayed up-link by various means signals and is
used to establish just enough optical power from the portable communicator
to establish a satisfactory communication.
As further described herein, coaxial cables are used to transmit
communication carrier signals between the modules and the base unit as
well as provide electrical power to the modules. The modules may be
connected in parallel and a large number can be used in a large area that
is serviced by one base unit.
When optical power from the portable unit is controlled, its battery energy
is conserved, the signal to noise ratio at the base receiver modules is
held low at a fixed value and the base frequency of the plurality of the
up-link transmitters is kept centered on the pass-band of the portable
unit's receiver. The dynamic range of the optical power incident upon the
base receiver modules can be kept within acceptable limits so that the
most proximate up-link receiver module receives neither too little nor too
much optical power.
With a communication system in accordance with the invention a plurality of
such two-way infrared communication systems can be used within a common
enclosure without causing an overload at any one down-link receiver and
without interference between the channels. This is achieved in one
embodiment by placing distributed base infrared receiver modules
associated with the different channels in proximity to each other, with
the same optical view The same close placement is made with the up-link
base transmitter modules of different channels.
In such case, when a portable unit is close to one of its associated
infrared down-link base receiver modules, the automatic power control
causes a cut back of the optical power from the portable unit and avoids
excessevely high optical power input to the also adjacent up-link infrared
receiver module of the other channel.
If, this other channel, for example, happens to be in a high power demand
mode, because its associated portable unit is at a remote location
relative to an up-link receiver, the need to provide special skirt filters
to avoid cross-talk problems and saturation of optical detectors are
avoided. The combined received desired signal level incident on each
receiver module group is at the same level as the combined interfering
signal level As further described herin, the proximity mounting of
receivers of different channels and the power control feature enables use
of a common up-link receiver module whose bandwidth is sufficiently wide
to accomodate more than one channel. In such case the amount of cabling as
well as the number of different modules can be advantageously reduced.
Similarly, the colocation of transmitter modules which illuminate a common
field assures equal desired as well as interfering signal levels at the
portable unit's receiver. This condition can be conveniently tolerated
with simple filtering.
It is, therefore, an object of the invention to provide a two-way infrared
communication system for a variable optical path within an enclosure and
which system provides reliable communication with conserved electrical
power, a low level of complexity and is easily expandable and convenient
and flexible to install and use. It is another object of the invention to
provide multiple channel two-way infrared communication systems capable of
operating within a common enclosure without interference between the
channels while preserving battery power and the advantages of a single
channel system.
These and other objects and advantages of the invention can be understood
from the folllowing description of several embodiments described with
reference to the drawings.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a block diagram representation of one infrared communication
system in accordance with the invention;
FIG. 2 is a more detailed schematic of the system of FIG. 1;
FIG. 2A is voltage-frequency plot of response characteristics used for
optical power control of a portable or down-link infrared transmitter;
FIG. 3 is a more detailed schematic view of infrared receiver nd infrared
transmitter modules used in the system of FIG. 1;
FIG. 4 is a perspective broken away view of a multiple infrared transmitter
and receiver module system in accordance with the invention;
FIG. 5 is a perspective view of multiple infrared transmitters as used near
a window to an enclosure;
FIG. 6 is a partially perspective infrared communication system in
accordance with the invention with a plurality of different communication
channels inside the same room; and
FIG. 7 is a block diagram of an infrared telephone system of which portions
are used in an infrared communication system in accordance with the
invention.
FIG. 8 is a side section view in elevationof a base unit receiver module;
FIG. 9 is a top plan view of the base unit shown in FIG. 8;
FIG. 10 is a partial perspective view of the receiver module of FIG. 8; and
FIG. 11 is a side section view of a portable unit's infrared receiver.
DETAILED DESCRIPTION OF THE DRAWINGS
With reference to FIG. 1 an infrared communication system 20 in accordance
with the invention is shown inside a room 21 and is formed of a base unit
22 that is coupled through coaxial cables 24, 26 to respective spatially
distributed base unit infrared receiver modules 28 and up-link infrared
transmitter modules 30. The system 20 enables infrared communication with
a portable unit 32 held by a person as shown. Portable unit 32 is powered
by a battery pack contained in a transceiver 34 and is formed with at
least one up-link infrared receiver 36 and a down-link infrared
transmitter 38. These infrared devices are mounted on a waist belt 40 that
is conveniently worn as shown. In order to provide maximum spatial
coverage a second receiver 36 and second transmitter 38 are placed (not
shown) on the belt, preferably at diametrically opposite belt locations.
These second down-link infrared devices are not always needed and may be
deleted particularly when battery power is to be conserved. A microphone
42 is shown for providing audio signals for transmission via transceiver
34 and infrared transmitter 38 to any one of the infrared receiver modules
28 and thence via coaxial cable 24 to base unit 22. In the other
direction, audio signals can be sent from base unit 22 via coaxial 26 to
infrared modules 30, all of which simultaneously transmit so that portable
unit infrared receiver 36 can provide appropriate audio to ear phone 44
via transceiver 34. The transceiver 34 includes circuitry as illustrated
in FIG. 7 for the handset portion. This includes the FM receiver dual
slope gain circuit (optional), filter and earpiece driver networks
generally indicated at 45 for the receiver section and the amplifier,
filter, dual slope gain (optional), VCO and infrared diode driver for the
transmitter section 46. Instead of audio data can be transmitted between
base unit 22 and portable unit 32.
In the system 20 many infrared receiver modules 28 and transmitter modules
30 can be added over very long coaxial cable lengths, which can be of the
order of a thousand feet long. The modules 28, 30 are all connected in
parallel and electrical power is supplied through the same coaxial cables
24, 26 through which the information signals flow.
FIG. 2 illustrates the system 20 with greater detail. At base unit 22
appropriate FM modulated sinewave carrier signals are generated on a line
50 by a VCO (voltage controlled oscillator) 52 that is modulated by the
output of a summing network 54. The latter has an audio or data input 56,
such as from a telephone line as well as a power level control signal on
line 58. A sinewave carrier is used to make synchronization of the
transmitter modules 30 relatively immune to reflections in the coaxial
cables 26.
The carrier signal is supplied through a DC blocking capacitor 60 to the
central conductor 62 of coaxial cable 26 whose shield 64 is connected to
ground. A dc voltage power source 66 is applied through an rf high
impedance network such as a coil 68 to center conductor 62 of cable 26 to
supply electrical power to up-link infrared transmitter modules 30.1 and
30.2. The coaxial cable 26 is shown connecting the modules 30 in parallel
and a cable terminator 70 is used to reduce cable end reflections. The
transmitter modules 30 act as high impedance loads to the carrier sinewave
signal, yet can draw DC power from the same cable.
The receiver modules 28 associated with base unit 22 are so designed that
electrical power is received from the center conductor 72 of coaxial cable
24. The receiver modules 28, however, act as constant current sources at
carrier frequencies. Each receiver module 28 responds to incident infrared
optical power by drawing a corresponding amount of current from an emitter
80 of a transistor 82. The emitter collector junctions are in series with
the common central conductor 72. The total carrier current drawn through
the emitter 80 thus in effect combines, by summing, the various signals
indicative of the optical power incident on the individual modules 28.
A tank circuit 84 is used on the collector 86 and the carrier is ac coupled
to an FM receiver 88. A signal is derived from receiver 88, such as from
its rf stage, by a level detector 90 whose output is a DC level signal
used to control the output power of the portable or down-link infrared
transmitters 38.
DC power is supplied by power supply 66 through emitter 80 and the center
conductor 72 to the modules 28. A DC blocked matching terminator 92 is
used at the end of cable 24 to reduce reflections.
The portable unit 32 is designed so that it transmits no more than the
optical power needed for a pre-set signal level at the base receiver
module inputs. This is achieved by combining the portable receiver module
outputs 94.1 and 94 2 at an FM receiver 96. The latter has a discriminator
output 98 that is applied to one input 100 of a pseudo integrator
differential amplifier 102. The other input 104 of amplifier 102 is
connected to a DC reference level 106 that is set at the voltage level 108
(see FIG. 2A) that is generally at the center 110 (FIG. 2A) of the pass
band B of the discriminator 109 in receiver 96. The output of amplifier
102 is applied to a driver for the portable unit transmitters 38.1 and
38.2 to cause a change in infrared output power in the direction required
to compensate for the change in the level signal on line 58 in base unit
22 while keeping the carrier frequency centered on the pass band of the
portable receiver modules.
With such optical output power control, battery drain can be held to a
minimum level consistent with good performance. The gain of the loop is
sufficiently high to restrict carrier excursions to a range equal to about
ten percent of the receiver bandwidth. Automatic tracking to the remote's
band center is obtained.
The audio part of the output from discriminator 109 is applied through
appropriate networks and amplifier 112 to an earphone 114.
Audio signals from microphone 42 (see FIG. 1) are applied in FIG. 2 on line
116 &:o an FM carrier modulator 118 which has its output in turn applied
to down-link infrared transmitter 38.
A particularly advantageous feature of the control loop for the infrared
optical power is that it establishes in effect a generally constant signal
to noise ratio at the down-link or base unit receivers 28.
This is desirable for voice recognition systems and other systems which are
sensitive to noise and require removal of its effect for activities such
as voice analysis or voice controlled switching.
FIG. 3 illustrates the base unit receiver module 28 and transmitter module
30 with greater detail. The receiver module 28 includes a plurality of
infrared sensitive diodes 120 in parallel and in series with a tank
circuit 122. The drain 124 of an FET 126 acts as a constant current signal
source to center conductor 72 but at carrier frequencies. Electrical DC
bias for the photodiodes is supplied through resistor 128.
The transmitter module 30 has a limiter 130 and a logic amplifier 132 to
drive infrared output diodes 134. Electrical DC power is supplied through
a high rf impedance coil 136.
FIGS. 4 and 5 illustrate various configurations and placements of base unit
transmitter modules 30 and receiver modules 28 in an enclosed space to
assure adequate infrared communication with a portable unit 32.
With reference to FIG. 6 an infrared two-way communication system 150 is
shown including two separate channels A and B operating at different
carrier frequencies. Each channel includes a base unit 22 and a plurality
of infrared receiver modules 28 and infrared transmitter modules 30,
connected in parallel to coaxial cables 24 and 26 respectively.
In system 150, however, the base unit receivers 28a and 28b are mounted in
proximity to each other so as to effectively have the same field of view.
The same pairing is done with infrared transmitters 30a and 30b. In system
150 the infrared power control loop is essential. Since each channel
controls its respective portable unit's output optical power, the received
infrared signal is constant at a predetermined level. As a result spurious
responses, interfering crosstalk, and intermodulation effects are reduced
to a negligible level with only a moderate amount of selectivity required
to be incorporated that can be implemented with simple circuits.
Hence, interfering signal levels that could be up to 80db higher than the
desired signal level, as might occur in certain locations and orientations
of the portable units, are avoided. Such 80db disparity is well beyond the
infrared power/current linearity characteristics of silicon photodiodes
and would introduce intermodulation effects that would not be removable
with filtering.
The same problems exist for the portable units 32. Hence, the paired
location of the base unit transmitter modules at each site forces the
desired and interfering signals at each portable receiver to be equal and,
therefore, reduces interference and intermodulations.
Since the receiver modules from all systems are closely spaced at each
site, it is possible to use a single receiver module for all the systems
provided it has a sufficiently broad pass band. By reducing R2 to a value
of R2/n (See FIG. 3.), where n is the number of systems or channels, the
bandwidth car: be made sufficiently wide to accomodate signals from all
the portable transceivers. The resulting effect on sensitivity is as
follows:
For systems located in environments where the effect of in-band ambient
optical noise is substantially greater than the electronic thermal noise
of R2, then reduction of R2 will have no effect on system sensitivity (in
effect the signal to noise ratio).
When the effect of ambient optical noise is less than the electronic noise
of R2, then reducing R2 to R2/n will degrade the signal voltage to noise
voltage density ratio (E/(V/<H.sub.z), by a factor 1/<n. To retain the
same system sensitivity, the photodiode area (or number) must increase by
a factor of n (the equivalent of n receiver module).
By using a common receiver module 28, n-1 coaxial cable runs are eliminated
and a common field of view is assured. In addition n-1 receiver modules
are eliminated. In the latter case the modules are replaced by a larger
receiver module, having n times the original receiver module diode area.
Since transmitter (T) modules 30 from all systems are located at each T
module site, it is also advantageous to employ a single transmitter module
for all systems provided intermodulation of transmitter carriers is held
to acceptable levels.
The down-link or base unit receiver modules 28 have an appearance as
illustrated in FIGS. 8-10. A generally open ended channel casing 150 made
of a reflective metal is closed at one end 152 by a metal cap. A base unit
infrared receiver circuit is mounted on a circuit board 154, the top of
which also has a ground plane 156 that is electrically connected to casing
150.
The array 120 of silicon photodiodes that are sensitive to infrared are
surrounded by a plastic ring 158. The diodes face upwardly to receive and
detect infrared light. The ring 158 is adhesively mounted to board 154 and
a clear, infrared transparent epoxy material 160 is placed inside the ring
158. An infrared transparent ball 162, made of an acrylic material, is
placed in the epoxy, which bonds to it. Since the refractive indices of
the epoxy 160 and ball 162 are almost the same, the infrared light
capturing capability of the diodes is enhanced without air/surface
interfaces.
The optical structure 164 is covered by an infrared transparent plastic
plate 166 made of a plastic known as Lexan a polycarbonate plastic , the
inside of which is provided with a fine grid 168 of conductive material
that forms a faraday shield. Conducting stand-offs 170 provide electrical
conduction between the grid 168 and ground plane 156. Hence, the high
output impedance photodiodes are mounted within a faraday shield to
protect them from stray electrical fields while allowing infrared light to
pass through.
The recessed mounting of the optical structure 164 within casing 159 forms
a "dead-air" pocket enabling an essentially dust free mounting when
tilting the receiver module relative to the vertical in a manner as
illustrated in FIGS. 4 and 5.
The up-link transmitter modules also are mounted in a casing such as 150.
However, the complex optical structure 164 is not used and its cover plate
166 is more deeply recessed. A wide effective field of view is still
obtained by virtue of the multiple reflections by the inside of casing
150.
The portable unit 32 infrared receiver 36 has a construction as shown in
FIG. 11. A flanged metal cup 180 and 182, externally threaded,enclosed the
infrared receiver circuit. The circuit includes a plurality of infrared
sensitive photodiodes 186, as illustrated in the schematic block diagram
of FIG. 7. A hemispherically shaped lens 188 is placed above the diodes
186 and directly bonded thereto with an epoxy or another suitable clear
adhesive that eliminates air interfaces.
An infrared transparent hemispherical enclosure 190, having a lower metal
rim 192, is used to cover the lens 186 and circuitry as shown. A faraday
shield is obtained by placing a wire mesh 194 along the inside of the
cover 190. The mesh 194 is selected to cause as little light blockage as
possible while still protecting against electrical interference. A mesh of
one mil wires at ten mil spacings was found effective and blocked only 20
percent of the light. The lower rim of the mesh 194 is connected to an
annular metal tape with a conductive adhesive 198 which makes electrical
contact with the upper edge of metal ring 182 when rim 192 of cover 190 is
screwed onto the ring 182.
An infrared transmitter 38 on portable unit 32 has a similar construction
as FIG. 11 except it has only photodiodes such as at 200 in FIG. 7 and no
faraday shield. In one embodiment two infrared transmitters 38 are used,
one with five infrared generating photo diodes, the other with four. The
diodes 200 of both transmitters 38 are connected in series by use of
suitable wires embedded in the belt 40 (See FIG. 1) and emanating from and
returning to transceiver 34.
Having thus described several embodiments of the invention, its advantages
can be appreciated. Variations can be made without departing from the
scope of the following claims. For example, other techniques can be used
to establish control over the power of the portable unit's infrared output
power. For example, inaudible control tones could be used.
The embodiments described herein illustrate a portable unit 32 that is
battery powered and moveable depending upon where the person carrying it
moves. It should be understood, however, that other configuration are
contemplated by the invention. Hence, the term portable as used herein
means an infrared transmitter and receiver device which may be powered by
line power, and may be movable, rotatable or with undefined orientations
at a fixed location. As such, the optical path loss is variable or
otherwise undefined so as to be unpredictable.
The embodiment described depicts base systems with a single run of coaxial
cable tapped by parallel connected receiver modules or transmitter
modules. The general method, however, permits use of twisted pair wiring
(instead of coaxial cable) in some installations. In addition, since the
carrier frequencies can be quite low (50 KHz to 2 MHz), virtually
unlimited branching of cables is possible permitting high flexibility of
configuration.
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