`
`
`
`
`EXHIBIT 1011
`
`
`EXHIBIT 1011
`
`
`
`
`
`
`
`
`
`United States Patent
`
`[19]
`
`[11] Patent Number:
`
`5,345,592
`
`Woodmas
`[45] Date of Patent:
`Sep. 6, 1994
`
`
`USOOS345592A
`
`[54] SIGNAL TRANSFERAND POWER
`DELIVERY SYSTEM FOR A TELEVISION
`CAMERA STATION
`
`Assistant Examiner—Chi Pham
`Attorney, Agent, or Firm—Hovey, Williams, Timmons &
`Collins
`
`Inventor: Charles D. Woodmas, Lyndon, Kans.
`[75]
`[73] Assignee: Concept W Systems, Inc., Emporia,
`Kans.
`
`[21] Appl. No.: 866’664
`[22] Filed:
`Apr. 8, 1992
`i251
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`'
`'
`' """"""""""""""""""""
`'310/3 10'13:
`[58] Field of Search
`358/86' 455/3 1 3 3
`455/5 163340/310 R 3’10 A 316 CI;
`’
`,,
`’
`'
`’
`'
`’
`References Cited
`U S PATENT DOCUMENTS
`'
`'
`4,899,217 2/1990 MacFadyen et 3.1. ................. 358/86
`5,032,820
`7/1991 Tamkawa et a1.
`.............. 340/310 R
`5,033,112
`7/1991 Bowling et a1. .......... 340/310 CP X
`
`[56]
`
`Primary Examiner—Reinhard J. Eisenzopf
`
`ABSTRACT
`[57]
`A television production system provides both signaling
`and power over a single coaxial cable between a televi-
`sion control station and a remote camera station. The
`control station includes a power delivery unit for cou-
`pling with the coaxial cable for delivering DC. voltage
`and current along with signaling over the coaxial cable.
`The camera station includes a power receiving unit
`which receives power from the coaxial cable and deliv-
`ers it to the television camera and other camera station
`equipment. The receiving unit also monitors the re-
`ceived voltage and provides a power status signal repre-
`sentative thereof over the cable to the power delivery
`unit. The delivery unit controls the delivered voltage in
`accordance with the status signal in order to maintain
`the received voltage at the camera station at a desired
`level in order to compensate for cable voltage drop.
`
`31 Claims, 5 Drawing Sheets
`
`10
`
`16
`
`control station
`
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`14
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`
`power delivery
`unit
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`34
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`station
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`__________________ _|
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`|
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`station
`I
`24
`module
`L, __________________ _l
`
`28
`
`SONY, AXIS, HP Ex. 1011
`
`
`
`US. Patent
`
`Sep. 6, 1994
`
`Sheet 1 of 5
`
`5,345,592
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`US. Patent
`
`Sep. 6, 1994
`
`Sheet 4 of 5
`
`5,345,592
`
`402>
`
`BEGIN
`
`INITIALIZE VARIABLES, DISPLAY ALARM,-
`ACTIVATE PDVER IIUTPUT AT LUN LEVEL
`440
`
`
`
`PULL DISPLAY SETUP
`
`
`SVITCHE$ AND
`
`
`DISPLAY SWITCHES
`
`
`SETUP RUUTINE
`
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`DISPLAW
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`'ALERT-CHECK
`CUNTINUDUS
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`STATIUN SIGNAL
`SIGNAL UNIT'
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`'AUTU PDWER
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`SURGE MDNITDRING
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`
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`
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`
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`
`
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`
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`
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`
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`
`EXECUTE WAIT RUUTINE.
`
`0
`
`
`
`DETERMIN REMDTE VDLTAGE
`FRDM PDVER STATUS SIGNAL
`
`
`
`
`
`US. Patent
`
`Sep. 6, 1994
`
`Sheet 5 of 5
`
`5,345,592
`
`GREATER
`
`F1946.
`
`AT MAXIMUM?
`
`DISPLAW
`'EXCESS CABLE
`
`LDSS'
`
`LESS
`
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`THAN
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`
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`
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`
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`
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`
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`
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`
`
`
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`D/A VALUE
`
`
`
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`
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`SET D/A VALUE
`
`AT MINIMUM;
`
`'EXCESS CURRENT
`
`
`DPEN PDVER
`
`DRAW}
`
`SWITCH
`
`
`
`CURRENT
`
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`YES
`AMPS?
`
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`
`DISPLAY
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`
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`
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`
`
`SWITCH SUBRDUTINE
`'
`DISPLAY:
`'CHECK AND DISPLAY
`MENU SETUP RDUTINE.’
`
`
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`
`
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`UNIT AT 48
`
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`
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`
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`
`FIRST
`TIME THRUUGH
`
`
`
`EXECUTE ALARM
`
`SUBRDUTINE
`
`
`
`1
`
`5,345,592
`
`SIGNAL TRANSFER AND POWER DELIVERY
`SYSTEM FOR A TELEVISION CAMERA STATION
`
`BACKGROUND OF THE INVENTION
`
`1. Field of the Invention
`
`The present invention relates to the field of television
`production using remotely located cameras. More par-
`ticularly, the invention concerns a system for providing
`both signaling and power over a single coaxial cable
`between a television control station and a remote cam-
`
`era station and for controlling the voltage delivered to
`the camera station.
`2. Description of the Prior Art
`On-location production of television programs typi-
`cally involves the use of a production control center
`housed in a trailer or van connected with a number of
`
`remote camera stations by way of control and power
`cables. Each camera station typically includes a camera,
`camera operator headset,
`talent earpiece, and talent
`microphone. The control cables must have the capabil-
`ity of carrying a wide variety of signals including cam-
`era video and program audio signals from the camera
`station to the control facility, and two-way intercom
`audio between the control facility and the camera oper-
`ator and talent. The cables also carry various control
`signals from the control center to the camera station
`such as system master reference signals including color
`black and a composite video signal (black burst) used as
`a synchronizing signal (gen-lock), and an on-air tally
`signal which activates the tally light on the camera
`viewable by the talent as an on-air cue.
`In one prior art cabling technique, 'a plurality of coax-
`ial cables are used for carrying signals and power is
`provided to the camera station by a portable power
`generator or conventional drop cords connected to the
`nearest A.C. outlet. The number of individual cables
`required for this technique can range from two to a
`more common seven consisting of four audio twisted
`pairs and three coaxial cables plus a power cord. As
`those skilled in the art will appreciate, a seven-line bun-
`dle for one camera station weights about ninety pounds
`for a reach of three hundred fifty feet.
`Another cabling technique uses a multi-conductor
`cable containing several narrow diameter mini-coaxial
`cables and several wire pairs for audio and power. A
`more recent development uses a triaxial cable in which
`video and audio signals are modulated and multiplexed
`along the center conductor and the intermediate con-
`ductor with power provided over the center and outer
`conductors.
`
`As those skilled in the art appreciate, all of these prior
`art cabling techniques are expensive and the cabling is
`relatively heavy and stiff making it awkward to carry
`and route. An even more recent technique is called the
`CAMPLEX system and uses a single coaxial cable over
`which all of the signalling is modulated and multi-
`plexed. Because only a single coaxial cable is used, the
`use of this system is inexpensive and the single cable is
`very easy to carry, route and splice. This system does
`require, however, a separate power supply such as a
`conventional drop cord or the use of camera’s internal
`battery.
`
`SUMMARY OF THE INVENTION
`
`The signal transfer and delivery system of the present
`invention solves the prior art problems discussed above
`and provides a distinct advance in the state of the art.
`
`2
`More particularly, the invention hereof provides both
`signalling and power over a single conductor pair.
`Broadly speaking, the present invention includes re-
`spective control and remote station modules operable
`for transferring signals between a conductor pair. The
`control station module includes a power delivery unit
`for delivering power to the conductors;
`the remote
`station module includes a power reception unit for re-
`ceiving power from the conductors and delivering the
`power to the remote stations. The remote station mod-
`ule also includes means for sensing the status of the
`power at the remote station, for producing the power
`status signal representative of the power status and for
`transferring the status signal to the conductors. The
`power delivery unit includes means for receiving the
`status signal and for controlling the delivery of power
`accordingly to the conductors.
`More particularly, the power status signal is represen-
`tative of the DC. voltage delivered to the power sta-
`tion. The power delivery unit controls the DC. voltage
`delivered to the conductors in order to maintain the
`
`5
`
`10
`
`15
`
`20
`
`desired remote voltage despite variations in power con-
`sumption by the camera station and losses in the cable.
`
`25'
`
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`30
`
`35
`
`45
`
`50
`
`55
`
`65
`
`FIG. 1 is a schematic representation of a television
`production facility in accordance with the present in-
`vention;
`FIG. 2 is an electrical block diagram illustrating the
`power delivery unit of FIG. 1;
`FIG. 3 is an electrical block diagram illustrating the
`power reception unit of FIG. 1;
`FIG. 4A is a computer program flow chart illustrat-
`ing the operation of the microcontroller of FIG. 2; and
`FIG. 4B is a continuation of the computer program
`flow chart of FIG. 4A.
`
`DETAILED DESCRIPTION OF THE
`PREFERRED EMBODIMENT
`
`FIG. 1 is a schematic representation of signal transfer
`and power delivery apparatus 10 illustrated as part of
`television production facility 12 which includes control
`station 14 and camera station 16. Control station 14
`includes conventional television production equipment
`well known to_those skilled in the art such as the pro-
`duction switcher, video and audio transmitters, camera
`monitors, preview monitors, program monitors, direc-
`tor’s intercom, control signal generators, and COntrol
`signal receivers. Camera station 16 is also conventional
`in nature and includes D.C. powerable video camera 18,
`talent earpiece 20, camera operator intercom headset
`22, and talent microphone 24.
`Apparatus 10 broadly includes control station module
`26 and camera station module 28 interconnected by
`conventional 75-Ohm coaxial cable 30. Control station
`module 26 is also coupled with control station 14 for
`bi—directional signal
`transfer therewith, and camera
`station module 28 is coupled with components 18—24 of
`camera station module 16 also for bi-directional signal
`transfer therewith.
`Control station module 26 includes control station
`signal unit 32 and power delivery unit 34. Signal unit 32
`is preferably a conventional signal multiplexing unit
`such as a CAMPLEX console adaptor available from
`Concept W Systems, Inc. of Emporia, Kans. Signal unit
`32 is operable to receive a plurality of signals from
`control station 14 and to combine and multiplex those
`
`
`
`3
`signals onto coaxial cable portion 36 for transmission to
`camera station 16 by way of power delivery unit 34 and
`camera station module 28. Similarly, unit 32 is operable
`to receive multiplexed signals over cable portion 36 and
`to separate the signals for presentation to control station
`14. In operation, preferred signal unit 32 imposes 12
`VDC on line 36 when energized and imposes 24 VDC
`when activated for signal transfer. In the context of the
`present invention, these two voltages are used as signals
`indicative of the presence and signal operation of unit
`32 as explained further herein.
`FIG. 2 illustrates power delivery unit 34 which, in
`general, delivers power in the form of D.C. voltage and
`current to cable 30 for transmission thereover to camera
`
`station module 28 which then separates the power from
`the signals for delivery to the appropriate components
`of camera station 16. Power delivery unit 34 includes
`variable output DC. power supply 38, transformer 40,
`current monitor 42, solid state switch and current surge
`detector/limiter 44, voltage divider 46, signal separator
`and power combiner 48, RF choke 50, tracking filter
`and square wave generator 52, microcontroller 54, digi-
`tal-to-analog converter (DAC) 56, alpha-numeric dis-
`play 58, display setup switches 60 and 62, and audible
`alarm 64.
`
`Power supply 38 (Vicor FlatPAC VI-LE4-CW) re-
`ceives 120 VAC power from a conventional source
`thereof and delivers an output DC. voltage to common
`mode transformer 40 (RENCO RL-l329-5-1000) used
`to remove high frequency noise from the output volt-
`age. The output voltage from power supply 38 varies
`between about 15 and 48 volts in accordance with the
`analog signal received from DAC 56.
`The input and output terminals of one leg of trans-
`former 40 are coupled to the respective inputs of cur-
`rent monitor 42 which includes two reference diodes 66
`and 68 (LM336) and operational amplifier 70 (NE5532).
`Diodes 66,68 provide calibrated voltage offsets to the
`inputs of amplifier 70. Monitor 42 detects the current
`flow from power supply 38 by monitoring the voltage
`drop across the monitored leg of transformer 40 and
`thereby provides an output voltage to microcontroller
`54 between 0 and 5 VDC corresponding to a power
`supply output current flow between 0 and 2 amps.
`Detector/limiter 44 receives the power flow from
`transformer 40 and provides two levels of current limit-
`ing. One level limits current to a low level at 15 milliam—
`peres using two transistors conventionally configured
`as a constant current amplifier between the input and
`output. As explained further hereinbelow, this low level
`of output power is applied to cable 30 when power
`delivery unit 34 is initially energized. The second level
`of current limiting is for high level or operating power
`and conventionally includes a power field effect transis—
`tor (FET) (MTP8P10) used as a power switch and a
`second transistor (MPSA93) which monitors the volt-
`age drop across a resistor in series with the FET power
`switch as a current limiter. Detector/limiter 44 receives
`a control input from microcontroller 54 which controls
`the on-off status of the power switch but which can be
`over-ridden by the second transistor. In this way, detec-
`tor/limiter 44 presents a self-contained current limiter
`which prevents large current surges in the high power
`output as might be caused by a short in cable 30 as a
`result of being cut or pinched.
`The output from detector/limiter 44 is coupled with
`voltage divider 46 and combiner 48. Voltage divider 46
`is composed of series-coupled resistors 72 and 74 with
`
`10
`
`15
`
`20
`
`25
`
`3O
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`35
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`45
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`50
`
`55
`
`60
`
`65
`
`5,345,592
`
`4
`the connection therebetWeen coupled with microcon-
`troller 54 as an input thereto. The values of resistors
`72,74 are selected so that one tenth of the output voltage
`from detector/limiter 44 is provided to microcontroller
`54 as a representative signal thereof.
`Signal separator and power combiner 48 includes
`inductors L1 and L2 and capacitors C1 and C2 inter-
`connected as shown. Series connected inductor L1 and
`capacitor C2 form a low pass filter with an insertion-
`/isolation loss of about 10 dB at about 290 Khz which is
`the frequency of the power status signal received by
`combiner 48 over cable 30 from camera station module
`28 as explained further hereinbelow. Capacitor C1 in-
`terconnects cable portion 36 and cable 30 for passing
`the various signals therebetween unaffected by the de-
`livery of power to cable 30 by power delivery unit 34.
`Capacitor C1 forms a high pass filter with a 3 dB point
`at about 1.0 Mhz to isolate control station signal unit 32
`from the power supplied to cable 30 by power delivery
`unit 34.
`
`As mentioned above, signal unit 32 also provides two
`DC. voltage outputs at 12 and 24 volts respectively
`corresponding to power-up and signal activation.
`Choke 50 interconnects cable portion 36 at combiner 48
`and microcontroller 54 which allows the passage of
`these two voltages for monitoring by microcontroller
`54 while preventing passage of the RF signals passing
`between control station and camera station 16. As ex-
`plained further hereinbelow, microcontroller 54 moni-
`tors these two voltages provided by unit 32 in order to
`test for the presence and activation thereof.
`Tracking filter and square wave generator 52 is a
`combination of a conventional phase locked loop (PLL)
`(EXAR XR-221l), voltage comparator and binary rip-
`ple counter. Generator 52 receives the power status
`signal as an input from combiner 48. In turn, generator
`52 provides two outputs, the first is in the form of a
`“signal valid” output which indicates the presence of
`the status signal to microcontroller 54.
`The second output is in the form of a reduced fre-
`quency square wave representative of the frequency of
`the input signal. This frequency represents the voltage
`provided to camera station 16 by camera station module
`28 and is used by microcontroller 54 to control the
`output voltage delivered to cable 30 by power delivery
`unit 34. The conventional PLL is configured to operate
`as a tracking filter tuned to lock to the status signal
`which typically presents a frequency range from 250 to
`300 Khz. The output from the tracking filter’s oscillator
`is provided as the input
`to a voltage comparator
`(LM393) which converts the input to an output square
`wave.
`
`Passage through the tracking filter and comparator
`also provides selected amplification, removes spurious
`signals, and provides a logic level square wave signal to
`the binary ripple counter (CD4024). This ripple counter
`serves as a frequency divider (divide by 64) providing a
`lower frequency square wave as an input to microcon-
`troller 54 which still retains the frequency variations of
`the input signal. The tracking filter also provides the
`“signal valid” output which is the “lock detect” output
`therefrom.
`
`Microcontroller 54 (Motorola MC68705R3), in addi-
`tion to the connections mentioned above, is also con-
`nected to audible piezo alarm 64, to switches 60,62, and
`to display 58 (available from Industrial Electronic Engi-
`neers, Inc. LCM-2006) as illustrated in FIG. 2. The
`operation of components 58—64 is explained further
`
`
`
`5,345,592
`
`5
`hereinbelow in connection with the flowcharts of
`FIGS. 4A,B.
`Cable 30 interconnects control station module 26
`with camera station module 28 for bi-directional signal
`transfer therebetween and for delivery of power from
`power delivery unit 34. Camera station module 28 sepa-
`rates the power from the signals on cable 30 and deliv-
`ers the power to camera station 16 for operational use.
`Camera station module 28 includes power reception
`unit 76 and camera station signal unit 78. The preferred
`camera station signal unit is the CAMPLEX camera
`adaptor available from Concept W Systems, Inc. of
`Emporia, Kans. with the circuitry of power reception
`unit 76 integrated therewith to form a single integrated
`unit.
`
`FIG. 3 is an electrical block diagram illustrating
`power reception unit 76 which includes signal combiner
`and power separator 80, current limited voltage regula-
`tor 82, current monitor 84, voltage regulator 86, voltage
`controlled oscillator 88 and voltage threshold detector
`90.
`
`Separator 80 includes inductors L1 and L2 and ca-
`pacitors C1 and C2 interconnected as shown. Capacitor
`C1 presents a high pass filter with a 3 dB point at about
`1 Mhz and thereby prevents passage of the DC. power
`voltage to camera station signal unit 78 but allows bi-
`directional passage of the high frequency signals be-
`tween cable 30 and signal unit 78. In contrast, series
`coupled inductors L1,L2 prevent passage of the high
`frequency signals but allow passage of the DC. power
`as an output to regulators 82 and 84 as shown in FIG. 3.
`Conventional regulator 82 receives the power input
`from separator 80 and provides a current limited output
`at about 12 VDC to camera station 16 and in particular
`to camera 18. Regulator 82 uses a power field effect
`transistor controlled by current monitor 84 to limit
`current throughput. More particularly, regulator 82
`includes a zener-diode referenced operational amplifier
`(NE5534) which functions as a power output voltage
`error amplifier controlling a power field effect transis-
`tor (MTP8P10) which functions as a series regulator.
`Regulator 82 is controlled by two signals. The first
`signal is a power control signal received from voltage
`threshold detector 90 which enables operation of the
`error amplifier and causes regulated power to pass
`through the transistor. The second signal is a current
`control signal that controls a second transistor to over-
`ride the error amplifier output and thus controls the
`current through the power transistor.
`Current monitor 84 generates a control signal used to
`activate the current limiting function of regulator 82.
`Monitor 84 includes zener diodes 92 and 94 (LM336)
`the anodes of which are connected to the input termi-
`nals of operational amplifier 96 (NE5230). The anode of
`output zener diode 98 (5.6 volts) is connected to the
`output of amplifier 96 and the cathode of diode 98 is
`connected to regulator 82 as a current control input
`thereto. The cathodes of diodes 92,96 are connected
`across inductor L2 of separator 80 to detect the current-
`induced voltage drop thereacross. The gain and offset
`of amplifier 96 is calibrated such that a voltage drop
`across inductor L2 equivalent to 2.0 amperes causes
`output diode 96 to conduct and thereby enable the cur-
`rent limiting function of regulator 82. Power control
`diode 97 interconnects the output of regulator 82 with
`current monitor 84 at
`the power control
`terminal
`thereof and with the output of threshold detector 90.
`Diode 97 holds monitor 84 and voltage regulator 82 in
`
`6
`a power-on state after the power input voltage is ad-
`justed down to its normal level of 15 VDC.
`Voltage threshold detector 90 comprises a zener
`diode having the cathode coupled with the input to
`regulator 82 and having the anode thereof coupled to
`the power control terminal of regulator 82. Detector 90
`prevents regulator 82 from supplying an output voltage
`until the input voltage rises above a threshold level of
`24 VDC.
`Voltage regulator 86 includes two transistors config—
`ured as a constant current amplifier between the power
`input and a zener diode coupled to ground at the power
`output. Regulator 86 provides a clean and stable operat-
`ing power supply to oscillator 88 at the power-in termi-
`nal thereof.
`Voltage controlled oscillator 88 (EXAR XR-2206)
`generates the power status signal as a frequency modu-
`lated signal between 250 and 350 Khz in accordance
`with the voltage applied to the control-voltage-in termi-
`nal corresponding to a range of 15 to 50 VDC. The
`voltage applied to this terminal is the DC. voltage
`provided by separator 80 which in turn is the power
`voltage as received from power delivery unit 34. In this
`way, the frequency of the power status signal represents
`the voltage as delivered by cable 30 to camera station
`module 28. As those skilled in the art will appreciate,
`the delivered voltage can vary according to the power
`draw of camera station 16 and the length of cable 30.
`The power status signal represents the actual delivered
`voltage which is used by poWer delivery unit 34 to
`compensate.
`The power status signal produced by oscillator 88 is
`coupled to cable 30 by way of inductors L1 and capaci-
`tor C2 which form a low pass filter with an insertion-
`/isolation loss of about 10 dB at the frequency of the
`status signal. With this configuration of power recep-
`tion unit 76, the status of the delivered power, that is,
`the DC. voltage thereof is sensed and a representative
`power status signal in the form of a frequency modu-
`lated signal is transferred to cable 30.
`FIGS. 4A,B are computer program flowcharts illus-
`trating the program for operating microprocessor 54.
`On power-up, the program enters at step 402 which
`initializes the software variables, inputs and outputs,
`display 58 and alarm 64. This step also activates power
`delivery unit 34 to deliver a low level voltage to cable
`30 at 15 VDC limited to 15ma. To accomplish this,
`microcontroller 54 presents the appropriate binary code
`to DAC 56 which, in turn, produces an analog output to
`power supply 38 for producing the output at 15 VDC.
`This low level is delivered to cable 30 by way of trans-
`former 40, detector/limiter 44 and combiner 48. Detec-
`tor/limiter 44 limits the output current to 15ma. By
`limiting the output current to 15 ma, a short circuit in
`cable 30 causes the voltage thereon to drop from the
`nominal 15 VDC which is detected by voltage divider
`46. When the voltage drops below 10 VDC, as repre-
`sented by the signal delivered to microcontroller 54, a
`short circuit is indicated as discussed further hereinbe-
`low.
`
`Step 404 then asks whether control station signal unit
`32 is producing an output at 12 VDC as received by
`microcontroller 54 by way of cable portion 36 and
`choke 50. As explained above, when control station
`signal unit 32 is initially energized, that is, powered up,
`it produces an output at 12 VDC. This output is used by
`the program to determine whether signal unit 32 is
`present and powered.
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`40
`
`45
`
`50
`
`55
`
`65
`
`
`
`7
`If the answer in step 404 is no, step 406 activates
`display 58 to display the message “alert-check signal
`unit.” Step 408 then asks whether this is the first time
`through this portion of the program, and if yes step 410
`initiates execution of a conventional'alarm subroutine
`for activating audible alarm 64. The display and audible
`alarm serve as a prompt to check the status of signal unit
`32. If the answer in step 408 is no, this indicates that the
`alarm subroutine was previously initiated and step 410
`can be skipped. The program continues to loop through
`steps 404—410 until the presence of signal unit 32 is
`indicated by a yes answer in step 404.
`Step 412 then asks whether signal unit 32 is producing
`an output voltage at 24 VDC indicating activation
`thereof for signal transfer. If yes, step 414 initiates dis-
`play of the message “signal unit ready for cable power.”
`If the answer in step 412 is no, step 416 activates display
`58 for the message “signal unit not ready for cable
`power.”
`After low level power output is initiated, step 418
`then asks whether the current output is less than the
`maximum allowable as indicated by the voltage signal
`received by microcontroller 54 from voltage divider 46.
`By limiting the output current to 15 ma, a short circuit
`in cable 30 causes a voltage drop which can be detected
`safely before full operating power is imposed. As those
`skilled in the art will appreciate, a short circuit may
`result if cable 30 is pinched or cut, but may also occur
`if the equipment at the remote end of cable 30 is defec-
`tive or improperly connected.
`If the answer in step 418 is no, indicating that a short
`circuit does exist, step 420 initiates display of the mes-
`sage “check load on cable.” Step 422 then asks whether
`this is the first time through this loop of the program. If
`yes, step 424 initiates the alarm subroutine. If the answer
`in step 422 is no, or after step 424, the program loops
`back to step 418 and continues through steps 418—424
`until the problem is corrected.
`If the test in step 418 is passed, step 426 then asks
`whether the power status signal is present as detected
`by tracking filter and square wave generator 52. The
`presence of the status signal is provided to microcon-
`troller 54 from the “signal valid” terminal of generator
`52. When low level power is imposed on cable 30 and
`power reception unit 76 is present and operational,
`oscillator 88 (FIG. 3) senses the low level voltage deliv-
`ered to reception unit 76, produces the power status
`signal representative of the low level voltage and re—
`turns the signal by way of cable 30 back to delivery unit
`34. In this way both the presence and functionality of 50
`power delivery unit 76 are checked before full power is
`imposed on cable 30.
`If the power status signal is present, step 428 initiates
`display of the message “camera unit present.” If the
`answer in step 426 is no, step 430 initiates display of the
`message “camera unit not present.”
`After steps 428 and 430, step 432 asks whether the
`voltage signal from camera station signal unit 32 is still
`at the high level voltage of 24 VDC. If no, the message
`“system standby” is displayed indicating that power
`delivery unit 34 is ready to deliver power. If the answer
`in step 432 is yes, step 436 again asks whether the power
`status signal is present. If no, step 438 displays the mes-
`sage “system power ready.” After steps 434 or 438, step
`440 polls setup switches 60,62 and in response, executes
`the “display menu setup” routine. More particularly,
`successive activation of “select” switch 60 causes dis-
`play 58 to successively display the five bar-graph menu
`
`45
`
`5
`
`10
`
`15
`
`20
`
`25
`
`3O
`
`35
`
`55
`
`60
`
`65
`
`5,345,592
`
`8
`
`options of voltage bar graph on, off, current bar graph
`on, off or the combination voltage and current bar
`graph. When the desired menu option is displayed,
`activation of “enter” switch 62 selects the display bar
`graph option for display. The program then loops back
`to step 404.
`If the answer in step 436 is yes, then it is known that
`both control station signal unit 32 and power reception
`unit 76 are ready for full power operation. Step 442 then
`displays the message “auto power now.” Step 444 then
`executes the alarm power—on routine and clears the
`interrupt mask. Step 444 also enables the current surge
`monitoring by detector/limiter 44 by providing an input
`to the power control terminal thereof from microcon-
`troller 54. This action also closes the power transistor
`and detector/limiter 44 which delivers full power out-
`put to cable 30.
`.
`Initially full power output is imposed at the lower end
`of the allowable range (between about 15 and 50 VDC)
`and step 446 then increments the output voltage by
`incrementing the binary code delivered to DAC 56.
`The program then executes a standard wait subroutine
`then asks in step 448 whether the output voltage as
`delivered to cable 30 is at 48 VDC. If no, the program
`continues to loop through steps 446 and 448, increment-
`ing the voltage each time until 48 VDC is achieved
`taking about one fourth second to bring the voltage up
`to this level. When this occurs, step 450 again executes
`the wait routine to allow the voltage to stabilize at
`power reception unit 76.
`During this time, the solid state switch of regulator 82
`(FIG. 3) is open and no power output is provided until
`the voltage reaches 24 VDC. At this point voltage
`threshold detector 90 activates regulator 82 which be-
`gins producing an output at 12 VDC. In turn, this out-
`put latches in current monitor 84 and regulator 82 by
`way of diode 97. In step 452, microcontroller 54 then
`reads the power status signal as presented by generator
`52 from the square wave output terminal thereof. In
`other words, in this step the program determines the
`voltage as present at power reception unit 76.
`The program next moves to step 454 in FIG. 4B
`which asks whether the voltage as received by power
`reception unit 76 is within the allowable range. A range
`is provided as a so-called “dead band” to keep the pro-
`gram from “hunting.” If the answer in step 454 is yes,
`the program moves to step 456 which displays the mes-
`sage “output power nominal.”
`If the received voltage is greater than the allowable
`range, step 458 asks whether the binary value to DAC
`56 is already at its allowable minimum. If no, step 460
`decrements the binary value.
`If step 454 indicates that the received voltage is less
`than the range, step 462 asks whether the binary value
`presented to DAC 56 is already at its maximum. If no,
`step 464 increments this binary value to increase the
`voltage.
`If the answer in step 458 is yes, or after steps 460, 456
`or 464, step 456 asks whether the power status signal is
`still present as indicated by the “single valid” output on
`generator 52 (FIG. 2). If yes, step 468 then asks whether
`control station signal unit 32 is still activated as indi-
`cated by its voltage output signal at 24 VDC.
`If the answer in step 468 is yes, step 470 then reads the
`current output as represented by the signal from current
`monitor 42 and asks whether this value is greater than
`the allowable two amps. If the current flow is below
`t