' Page 2 of 27

PHASER PAIN FIELD GENERATOR

THE FOLLOWING SET OF tONSTRUCTION PLANS DESCRIBE A POTENTIALLY POSSIBLE HAZARDOUS DEVICE TO HUMANS AND ANIMALS AND MUST BE TREATED WITH CAUTION. Remember, just because you do not hear this energy does not mean it is not affecting you. When testing always direct transducers towards accoustical ~bsorbing material such as accoustical board, etc.

If at any time your head or neck feels swollen or you feel light headed or sick to your stomach, it is an indication that you are being affected. Some times you may experience a continuous ringing in the ears even after the device is turned off.

High powered ultra-sonics have been known to have the capabilities of dam­aging hearing, affecting mental states and in extreme cases, causing brain damage. Very high powered ultra-sonics can be SUPER HAZARDOUS if not used with discretion. The described device in these plans are intended as a lab­oratory source of moderate powered accoustical ultrasonics. It can be used to control rodents by disrupting their metabolic functions, forcing them into the open from hiding places; studyimg rodent behavior and other con­Crolled scientific functions.

It is only suggested as a possible potential intrusion deterrent. It is to be clearly underst-od that the device is not intended to be used on humans. We at SCIENTIFIC SYSTEMS in no way encourage the use of this device for human exposure and strongly advise all safety precautions to be exercised.

The information and specifications are purchased at buyer's risk only. The literature we sell is usually based on well know scientific facts and general knowledge and are written by experienced graduat~ scientists, but we assume no responsibility or liability for informational accuracy or reliability or infringements upon patents or proprietary information or the use of use information for unlawful or illegal purposes. Projects and plans for projects are developed or constructed at Buyer's risk only. Since fab­rication is out of our control, we will not guarantee operation or proper function. We are not liable or responsible for personal injuries, property damage, infringements of the law or delayed delivery of merchandise as a result of information or plans we supply.

• Page 3 of 27

The unit can be used as a property protection device by proper placement and installation of the transducers at certain points in the area to be protected. Because of the relative newness of the product, little can be said about the effective area per transducer for this type of application. The difference in hearing from one animal to another also presents a problem in determining a hard, fast rule of installation.

The designer of these plans suggests two transducers per 1000 square feet, so placed as to direct maximum energy toward the suspected entry point. This serves as starting points and will no doubt require more energy if there are many accoustical absorbing materials in the area and vice-versa.

It must be understood that the device in this application may not always present a problem of pain to the intruder but will not doubt create a paranoia situation scaring him away having never been exposed to a device such as this before. Please note that our model PPGl as described inside the front cover is more suited to this application.

INTRODUCTION Please note before constructing this device the potential possible hazards involved. Ultrasonics at very high accoustical levels are known to be dangerous to humans if overly exposed, possibly producin~ brain damage. It is therefore, extremely important that adequate accoustical shielding of the operator and his immediate surroundings be capable of attenuating these waves down to a safe level. You will note that the directional.character­isl.ics of a system such as this becomes more pronounced at the higher fr0quency end. Proper safety precautions are a necessity and must be heeded to their fullest both in construction and using. Therefore, the builder and alternate user must be aware of the potential consequences of this device and must treat it the same way he would a laser, high voltage power supply, X-rays, radioactivity, micro-waves, etc. Many devices have useful purposes, but in the wrong hands can create hazards and be a nuis­ance in the users surroundings. Because of this reason, we cannot offer the device to the general public with the exception of authorized law enforcement agencies and proven responsible individuals in completed form. This particular design at present is under contract in a similar package to several law enforcement agencies both home and abroad. Therefore, these plans will no doubt be unavailable to the general public such as was the case with the electric dart guns, etc., within a year, without proper permits and licensing.

The following plans show how to construct a moderately high powered, variable sweep frequency, ultrasonic accoustical generator capable of handling the equivalent of 400 patts of resultant power obtainable from an equivalent conventional dynamic transducer system. This is possible due to a recently developed piezoelectric tweeter speaker developed by MOTOROLA. These devices produce six times the accoustical output obtainable from convent­ional dynamic methods for the same required driving power. This feature allows the use of relatively light-weight, low powered equipment to obtain these high accoustical energies enabling portable, light weight and hand­hnld use. The device described is directional and offers the options of adding up to sixteen transducers either in an array for high sonic densi­ties or placement in individual locations for large area coverage. Effec­tive animal or rodent control with a device such as this is the result of a11tomatically varying the frequency so these animals cannot develop a tolerance (such as deafness, immunity) to it. Many fixed frequency ultra­Ronic devices lose their effectiveness after several weeks because of this immunity problem.

• Page 4 of 27

APPLICATIONS Application of this device, other than laboratory uses are mainly in the fi<'lds of animal and pest control. Certain rodents when exposed will go into a frenzy, sometimes causing brain hemmoraging, vomi tinp;, decrea'ses in macing urges, slowing down of metabolic functions. etc. All of these results are of course related to species of animals, frequency setting of the device and of course, wave intensitites being directly related to distances from the device.

Typical area for use of this device are food storage areas, waste areas, or where ever animals such as rats and rodents are a problem. Also, note that these devices should be safety interlocked, automatically being turned off when areas are entered by humans. Other known uses of this device are control of crowds and demonstrations by law enforcement personnel. The French Police have been known to use such a device for breaking up un­~nthorized groups of potentially unruly people.

It should be understood that certain people are affected more than others, some to a point where they will vomit, experience severe headaches and cranial pains. Some people will experience severe pain in the ear, teeth, lower head, etc. Statistically, women and younger children are many times more sensitive to this device than average male adults. With this in mind, the builder must exercise consideration when testing and using the device as many people will not be aware of the source of this pain or uncomfort­able feeling and attribute it to a headache or other physical ailment. Also, certain people are affected mentally to a point of actually losing their tempers completely or becoming extremely quick tempered. Some people will experience a state of extreme anxiety when overly exposed. Therefore, consideration must be used at all times when testing or using this or similar devices.

It should also be noted that construction using the tweeters in an array configuration is more hazardous to people than the individual placement of these tweeters when used to control a large area for rodent and pest infestation. The array approach produces high sound pressure density occuring on axis of the array.

BRIEF DESCRIPTION OF OPERATION

We shall now proceed to give a brief description of the electronic cir­cuitry referencing the "Block Diagram" layout. The device is essentially a high-powered source of ultrasonic accoustical energy of a frequency con­stantly varying between preset low and high limits at an operationally adjustable sweep iate when operated in the "Auto" mode. "Manual" mode allows presetting a continuous frequency to a fixed value and also the lower limit at the swept frequency when in the "Auto" mode. PLEASE NOTE THE ABBREVIATIONS OF THE BLOCK DIAGRAM STAGES AS THEY WILL BE USED FROH HERE ON IN. An array or individually located tweeter transducers (TR) of from 4 to 16 are driven by a transformer coupled final amplifier (FA) consisting of two Class B operated power transistors mounted on a heatsink. These transistors are driven by a pulse driver and inverter (PID). this stage is driven by a ~oltage c~ntr;l oscillator (VCO) with an adjustment for the lower frequency limit. The VCO is driven by either a varying DC level generated by the Stair-case generator (SCG) in the "Auto" mode or an adjustable DC level termed "Manual Frequency Control" (MFC). These two functions are selected by the "Mode" switch. The SCG also contains the adjustment for the upper frequency limits of the VCO. The SCG is driven by the Step Rate Generator (SRG) that determines the rate of frequency sweep between the preset "Auto'' limits. The SRG is controlled by the sweep control rate (SCR).

sTeP (<:."'Tc

G£AiiiRfiToR.

Si<JlicP /ZF}7C C.ONTI'€OL.

"Ps''

PowER. SU!'l'LV

II '

SCG"

5TflrR ens£ QENEI?.flTOJ{

/(1 3 ,,_, •• ~ ... "llu:ro''oNLY

/] vPP€'1< Fi<Eip /.Jf'1J(

Page 5 of 27

·t-12

., pu-ro' ··vee"

,, , ?I:P II FA"

VoLTI'>G€ PuLSE C OA/7!f!Oi. /11/lle"-TFR

1-----1 fYNP 1-------1 O$ClLLATOI'i, Pf(IVE R

Sf

SYSTEM BLOCK DIAGRAM

TJet9NSDucE~

Tv.JEETER.S

The power supply for this device can be any medium duty source of batteries developing 12Vdc. Plans show the use of 8 - ll, "D" cells of the nickel cadmium variety connected in series for 12 volts. The Nicads are easily changed and reusable. Batteries may be replaced by a battery eliminator or conventional power supply capable of 2 amps at

a low ripple rate.

•

CONSTRUCTION STEPS (ASSEMBLY BOARD) Page. 6 a f 2 7

PLEASE REFER TO ASSEMBLY BOARD PICTORIAL (SHEET B) AND SCHEMATIC FOR STEPS l - 26.

The construction steps to this device will be divided into sections, each containing assembly steps, circuit theory and functions. Note, use compon­ent leads for wiring whenever possible.

STEP RATE GENERATOR (SRG) 1 Layout the 2.5" x 5" piece o.f perfboard as shown in sketch. Use

Sheet B for component interconnection sketch aid.

2. Insert and wire Rl, R2, R3, R4, Cl, C2, Ql, Q2, and C3 as shown. OhRerve polarity of Cl and C2 and position of Ql and Q2.

3. Insert ~, d R:l2B (SWEEP of these wires.

the three leads (J,K.M) , each about CONTROL RATE). Use holes in perfboard

Tape together and wire to R32A & B as

12" as shown to R32A for strain relieving shown in schematic.

4. Check wiring and soldering for errors and quality.

5. Apply 12Vdc to respective points and measure. Observe test po1nts (2) with scope as shown in test patterns #2. Vary R32B and note f•equency varying from 10 to 100 pps.

6. Verify correct operation and proceed to next step.

fulse rep. v""'"•• 1//lf 1i!:s.:tl48 Fttolfl 10 M:J 1: o too ms

THEORY OF STEP RATE GENERATOR (SRG)

This circuit is ndthing more than a free running multi-vibrator consisting of rtn astable switch with Ql and Q2 switching from an "off" to "Saturating" mode producing a square wave output of voltage equal to approximately vee ( + 12V).

This circuit performs as follows: Ql (for reference sake) starts to conduct causing its collector voltage to decrease consequently producing a negative voltage via Cl at the base of Q2 completely "off''. Cl now must discharge through R32A and R4 t6 a point where the base of Q2 will cause conduction repeating this sequence of events through C2 and the base of Ql. You will note that the wave form may be deteriorated at the high rep rate end. This is due to the charging time of Cl and C2 through R2 and R3 respectively. The dual pot R32A and B Determines the discharge time of Cl and C2 con­sequently the pulse rep rate.

'II. STAIRCASE GENERATOR (SCG) Page 7 of 27

7. Drill extra holes for pins of Il and arm of Rl3 in perfhoard,

8. Insert and wire Il and other related components, R5, R6, R7, RS, R9. RlO, Rll. Rl2, Rl3, Dl and C4. Observe polarity and position of Dl and · •. Wire and solder as shown. Mount C5 under hoard as shown.

9. Insert and wire D2 and C6 and connect +12 and ground buss lines together with SRG section. Note that D6 provides protection of Il and I2 from reversed polarity during testing.

10. Check wiring and soldering for errors remembering that mistakes may cost you the Il intergrated circuit.

11. Connect 12 volts as in Step 5 and observe test points 3,4,5, & 6 n~ shown. Set R32AB at midrange.

0 ~I { { I c +--t-~

't SliME /9& 'iTa" I'DNII'r 2.

THIS IS THE STEP VOLTAGE TO IlA AND DETERMINES THE RATE OF STAIRCASE GROWTH. NOTE THE WAVE FORM BEING CLIPPED DOWN TO .5V DUE TO THE INPUT OF THE AHPL 1I'IER I 1.

0CHMIDT OUTPUT PULSE THIS PULSE IS THE RESET PULSE FOR THE STAIRCASE GENERATOR AND OCCURS WHEN THE STAIRCASE GROWS TO ABOUT 75% OF THE 12 VOLTS VC OR ONCE EVERY SWEEP. THIS IS THE OUTPUT OF THE SCHMIDT DISCRB!INATOR IlB. IT IS TRIGGERED BY EC CONNECTED AS A COMPARATOR SAMPLING THE OUTPUT LEVEL AT DIN 4, IlA. IT ~IA"BE NECESSARY TCl EXTERNALLY TRIGGER THE SCOPE FOR A CLEAR PICTURE OF THIS WAVR

.,. 7V v

COMPARATOR OUTPUT PULSE THTS MEASUREMENT IS UNNECESSARY IF WAVE FORM PICTURES 4 & 6 ARE OK INDI­C.~TTN(; THE SCG STAGE IS PERFORHING CORRECTLY. IF NECESSARY, EXTERNAL TRIGGERING WILL BE REQUIRED - Use PIN 9 of IlB.

REQUIRED - USE PIN 9 OF IlB. Page 8 of 27

INVERTED VCO CONTROL VOLTAGE - THIS IS THE INVERTED STAIRCASE FOR CONTROL­LI\CG THE VCO. YOU WILL NOTE THAT IT ALWAYS STARTS AT 11.4 VOLTS AND RA!fPS DOWN TO SOME VALUE PRESET BY Rl3. DIODE D3 SUPPLIES OFFSET AND PREVENTS PIN 5 OF THE VCO FROM APPROACHING THE VALUE VC 12V A~~ CONSEQUENTLY LOCKING UP. THE RAMP OUTPUT OF Q3 IS FAIRLY LINEAR OVER THE REQUIRED RANGE OF SWEEP VOLTAGE.

19. Preset R22 to midrange and connect scope to tes_tpoint 8. This noint is the pulse output of the VCO and should be constantly varying along with the, staircase ramp voltage noted at test point 7. It is this varying f'requency that is amplified and used to drive the transducers of this system. When in the "auto" mode of Sl you will note that this frequency '"Rlue is constantly varying between certain limits at a sweep rate deter­minPd by R32B. When in the "manual" mode of Sl, the VCO frequency output is adjusted by Rl8, "Manual Frequency Control" and does not vary or sweep back and forth.

20, Tn adjust the upper and lower frequenc.y limit, perform the following: Adjust R32 for slowest sweep rate. Determine limits in this case, 10Khz to 25Khz. Observing test point 8;

A. Preset all trimpots midrange, Rl8 full CW (highest frequency). B. Sweep switch to "auto". C. Set R22 to 20Khz-50 usee Low end. D. Set Rl3 to 25Khz 40 usee High end, sets frequency window. E. Set sweep sw1tch to manual. F. Set Rl7 to 20Khz (50 usee). G. Check range of Rl8 Low end to less than 10Khz both auto & Hanual.

You will note that when in the "Auto" sweep position that a frequency window of 5Khz exists with the low point being set by

0 Rl8.

fliN " II AI/.~===:_:;;====;;;===

Bv~

0---------------------------------------VCO OUTPUT WAVESHAPE ,- THE ABOVE WAVESHAPE VARIES FROH t=lOO usee to 50 usee OR A CORRESPONDING FREQUENCY OF FROM 10KHZ TO 20KHZ, depending on Step 20 adjustments. NOTE SYMETRY OF THIS WAVESHAPE.

VOLTAGE CONTROLLED OSCILLATOR (VCO)

This circuit is the heart of the device. It determines the operating

·REQU~RED- USE PIN 9 of IlB. .. --7 .:•

; sv _ _,_t-

STAIRCASE OUTPUT THIS IS THE RAMP OR STAIRCASE OF VOLTAGE THAT CONTROLS THE VCO. ITS RATE OF OCCURENCE IS THE SWEEP RATE OF THE SYSTEMS GENERATING LOW TO BIGH FRE­QUENCIES. NOTE THAT THESE INDIVIDUAL STEPS BECOME LESS PRONOUNCED WITH FASTER SWEEP RATES. .,,,.. " ·-

THEORY OF STAIRCASE GENERATOR (SCG)

This-circuit-utilizes a quaa operational arriplifier wfiere--fh-ree-o~-tfieie circuits are used - the other remains as a spare.

•

The first amplifier Il functions as an intergrator where the current pulses from the step rate generator are intergrated and held on C4 It is this voltage that builds up in a staircase fashion (hence the name of the circuit, etc), a step at a time determined by the step rate generator (SRG). Dis­charging C4 is necessary to reset the circuit and again start from the bottom of the staircase and resetting at this upper limit. This is accom­plished by amplifier IlC functioning as a comparator, sampling the stair­case level when it reaches approximately 75% of 12-volts and triggering a Schmidt descriminator consisting of IlB that resets IlA through blockin~ diode Dl and resistor R6 commencing the sequence once again. The Staircase voltage variation produced at pin 4 of IlA is used as the control voltage of a "Voltage controlled oscillator", VCO.

III. VOLTAGE CONTROLLED OSCILLATOR (VCO)

12. Drill extra holes in perfboard for I2 .. and arms of Rl7 and R22.

13. Insert Rl4, Rl5, Rl6, R2l, D3, C7 & C8, C9. Insert Rl7 and R22 and bend over tabs to secure in place. Insert Q3 and I2 and note proper position.

14. Wire and Solder as shown.

15. Insert 12" wire leads to points indicated on board and connect to external controls: Rl8 and Sl. Strain relieve and twist these leads via jnserting through holes in perfboard.

16. Connect 12V and ground buss lines as shown.

17. Carefully check all wiring and soldering for shorts, etc. Note errors can be costly to the intergrated circuits.

18. Connect Rl8 at midrange. and stepping down

12 volts as in step 5. Place Sl in "Auto" position and Observe test point 7 and note DC level starting from 11.4 to about SV. (INVERSE OF WAVE FORM at Test Point 6).

\

frequency as a function of the level DC voltage at voltage is the result of the staircase generator. frequency excursions are controlled via Rl3 (Upper limit).

P;ege 10 of 2!il

pin 5 of I2. This You will note that the limit) and R22 (lower

The VCO is the intergrated circuit I2 and contains an internal current source that charges external capacitor C8. When C8 reaches a certain voltage a Schmidt triggers and produces a square wave output at Pin 3.

An external resistor connected at Pin 6 along with the external capacitor C8 determines the center frequency of the device.

IV. PULSE INVERTER AND DRIVER (PID)

21 Drill extra holes for th~ bases of ~7 and Q8.

22. Insert R23, 24, 25, 26, 27, 28, 29, 30, 31, Q4, Q5, Q6, Q7, Q8 as shown. Note Q6 is a 2N2907 PNP. Note position and polarity of transistor.

23. Wire and solder as shown connecting VCE, grounds and R20 as shown. Check for accuracy soldering and shorts.

24. Connect 12Vdc as in Step 5. Observe test point 8, set Sl to "Hanual" and adjust Rl8 for 20Khz.

25. Note the following waveforms at test points 9, 10, 11, 12. Connect external trigger of scope to test point 8 to establish time reference. These waveforms are such without Bl and B2 being connected to the FINAL AMP. When connected the voltage should drop from 12 to less than .4 on waveform sketches 11 & 12.

BUFFER STAGE OUTPUT - THIS SINGLE IS A SYMETRICAL SQUARE WAVE SATURATING 06 AND APPEARING ACRO~S R25.

INVERTER STAGE - THIS IS THE OUTPUT OF THE INVERTER STAGE Q5 AND INVERTS THE SQUARE WAVE DRIVING Q8.

Page 11 of. 27

~

I zv •

t I I I

DRIVER OUTPUT TO BASE - THESE WAVE FORMS ARE 180 dq;rccs OUT OF PHASE RESPECTIVE TO ONE ANOTHER (TEST POINTS AND (11 ar·<l 12) MUST SUPPLY SUFFI­CIENT CURRENT TO CAUSE COMPLETE SATURATION OF TEE FTN;\L AMPLIFIER TRAN­SISTORS.

CIRCUIT DESCRIPTION OF THE PULSE INVERTER .~ND DRIVER (PID)

This state is a DC amplifier with an inverter stage suplllying two positive going symetrical pulses of current 180 degrees out of phase for driving the final amplifier in a push-pull configuration.

Pulses occuring at "B" of Q4 switch Q4 and QG off and on (saturated). Voltage pulses across R25 ar separated and routed to ctriver transistor Q7 and inverter transistor sta(!;P (,l5 and driver transistor q8 providing square waves or voltages 180 degrees of out phase between Bl and B2.

The above described was the most difficult construction and comnletes the electronic assembly board of this system. This section must be properly operating before interfacing with the remainder of the circuit or damage to the final amp, transducers, etc., can result. The frequency limits des­cribed are only an example. Range can be as low as 5Khz to as high as 25Khz.

s

-t 1211

0

C5@

+12.

+ C.d

ASSEIIBLY BOARD ELECTRONICS SCHEMATIC

HEXAGONS ARE TEST POINTS TRIANGLES ARE EXTERNAL CONNECTIONS.

YOUR UNIT IS PRESET AT THE FACTORY {OR RECOMHENDED PRESET) TO THE FOLLOWING FREQUENCY LIMITS:

Page 12 of 27

Range is 5Khz to 20Khz adjustable via Rl8 "HAIN FREQ CONTROL". In the "auto" mode Rl8 selects the lower starting frequency at the beginning of the sweep. Frequency now increases by approximately 5Khz at a rate determined by the R32 SWEEP RATE CONTROL. When in the "UA N" mode the frequency remains constant to that selected by Rl8. Examples of Frequency sweep are the following: A. Rl8 at 5Khz sweeps to 10Khz - ANTI INTRUSION C. Rl8 at 15Khz sweeps to 20Khz - RODENT, UNINHABITATED B. Rl8 at 10Khz sweeps to 15Khz - CROWD CONTROL D. Rl8 at 20Khz sweeps to 25Khz - RODENTS, INHABITATED

No internal adjustment should be made unless familiar with steps 20A to G in the plans. If you desire different ranges, please drop us a line.

SHEET 8 Pa l3of27·

----------------- -----

\ ---- @--.... ... \ ...... .. -- --- ... .;\ ...

'-···--~ . - ----

Page 14 of 27 It is assumed that the assembly board is completed and set to the frequency limits desired. At this point the builder must decide how many transducers he is going to use, if he is going to mount them in an array, individual placements, etc.

The plans and sketches show an array of four mounted in the configuration shown on Sheets E & F, along with approximate dimensions for this approach. It should be noted that variations from this design will require mechanical enclosure changes while not requiring excessive circuit re-design other than that indicated.

lA Form CAl from a piece of #22 quage galvanized or equivalent thickness in aluminum from a piece of sheet metal, as shown in Sheet A. Note stiffening and cover mounting flanges along bottom. Use this sketch for dimensions noting 1":::: 2" scale. It may also be desirable to construct this housing from smaller pieces fastening them to­gether with flanges, brackets, sheet metal screws, etc. Note also that the cover may slope saving space if desired (Note dotted Lines) . · - -

with a fly cutter. Drill holes for Use caution when cutting holes for transducers cnntrols of rear of enclosure and for mounting brnckets, etc.

of components, heat sinks, handle,

2. Assemble transducers on front panel and control (R32, Rl8 and Sl) from assembly bo~rd ,fuse and bushing on rear panel as shown on sheets C, D, & E. Do not attach assembly board to double tape at this point.

3. Assemble Transformer Tl as shown and mount. as shown on Sheet D. Be careful not t0 break cores - use a thin piece of rubber.

4. Assemble Power Transistor Q9 & QlO, to heat sink using 'TOJ insulated mounting kits. (check with ohmeter before applying power).

5. Wire as shown in Final Amp Schematic and Sheets C, D, & E.

6. Install battery holders if using them. Test should be done using external power supply to monitor current, etc.

Apply external 12-V power and quickly check wave form at test points 13 and 14, the collectors "C" of Q9 and QlO respectively. If waveforms shown are not correct, immed­iately remove power and check for errors. Externally trigger for ti.me reference if desired. Note that transducers are not connected to "E" and "F" (Tl unloaded)

•

3

~ .

"' 5op.s~c.

t:"'

0 LJ EI2.S K oo TJ 'R.OUIVDf NG

1

f)LL- /o Bl=

J -

RiNG!NG

PRooP

Page 15 of 27

Vee must be no more than . 2 volts '"ith Vee being equal to 12V. Haveform must be symetrical respective to one another with a minimum of ringing and rounding of corners. The adverse conditions will increase as the load is increased.

Note that this wave form must he that sho~.-m rLs transistors may immediatelv overheat. Also any excessive overshoot could cause breakdown.

PLEASE READ THE FOLLOWING DATA PERTAINING TO THE FINAL AMPLIFIER AND TRANSDUCERS.

The final amplifier consists of 2 power transistors connected in a push, push configuration connected to Tl as shown in The FA schematic. Note R33 and R34 emitter resistors for current balance between the transistors.

PERFORM THE FOLLOWING:

With the 4 transducers disconnected observe \Javeform across E & F on Tl (TP15) as qhown in sketch (Frequency set at 20Khz).

r--...Ji' I

A I i

__,_____-+---J-+-tj---

HAVESHAPE AT E & F HITHOUT TRANSDUCERS CONNECTED

cJAVESHAPE AT E & F lHTH n:ANSDUCERS CONNECTED Al'PROXP!ATELY 30 to 1;0 VOLTS PEAK TO PEAK.

R Connect 4 transdll!Cers and note waveform changing from a square ~1ave to a trj_angular shape. Note voltage value on scope and remove v..dndings on Tl to produee 15 to 20 volts rms across the four transducers.

C. Place a 0-10 amp meter in series '"ith the +12 volt and note current of about .5 to o, amps.

The power output of this system is about 120db measured at 18". It is possible to obtain more power by further selecting of the transducers.

Page 16 of 27

It is important to OBSERVE SAFETY PRECAUTIONS IN PERFORMING THESE FOLLOWING STEPS. Remeber just because you do not hear this energy does not mean it's not affecting. you.

OBTAINING FURTHER OUTPUT

At this point, a transducer connected as a receiver and fed to a sensitive volt meter or scope should be monitoring the accoustical output of this system. The trick here is to obtain maximum accoustical energy output fer FINAL AMP DC inout. This is indicated by observing the waveshape at T013 and TP14, for squareness while adjusting for maximum accoustical !)Utput as indicated by the receiver. You must also be careful not to exceed the voltage limits of the transducer at that point where the frequency starts to cut in half. Enclosed chart on power, impedence, distortion and frequency response of transducers. Output voltage is increased app:oxima~ely 1 volt per adde~ turn on Tl.

When all is satisfactory, connect to battery pack.

STEPS FOR WINDIMG Tl BOBBIN

1. Parallel of Bifilar wind 10 turns pairs of #18 enamel covered magnet (or vinyl) covered wire as shown in BOBBIN WINDING SKETCH. Identify wires as in sketch and evenly spaced along entire bobbin length. This fully utilizes all of the core. 2. Secure and solder leads, A,B,C, & D to lugs as ~--------~~

Page 17 of 27

shown in SIDE AND TOP PICTORIAL sketches. Make sure that the enamel covering is entirely leads are tinned before soldering. Note that sketches may not show all connection to Transformer Tl.

removed and

3. Tape this winding to holq in place.

You may wish to bring out several taps on winding E & F to obtain optimum voltage levels for desired amount of transducers used. Rms voltage under load should be about 15 volts. Higher voltage and more output can be obtained for inter­mittent operation at the expense of possibly blowing transducers.

& ----:/l::-1.1

4. Wind 30 turns of #20 plastic covered wire neatly over above and connect leads to lugs (not shown). Note .that enamel wire is not necessary and it may be necessary to remove turns to obtain the correct voltage levels for the transducer. It is easier to remove this plastic jacket rather than the enamel coating. Bring out taps if desired, at 15, 20 & 25 turns for selection of power output. 5. Carefully place "E" cores to bobbins and scotch tape together.

When the desired turns are determined, you may wish to place the single winding E & F first on the bobbin.

/

" a •

~ / I

I

,,

l /

0

/;, I

I 'I / )

•

•

...-(

I I

i

I i

---I

102 / g

Pilge 18 of 27

Page 19 of 27

I '

l

see Sheet [l

Page 20 of 27

see Sheet r: ~-.....

·------& Slif'f't 1.1 (top vie1~)

Page 21 of 27

I I

/

I I I

~lllTT E

Page 22 of 27

SI!EET F (bottoM view)

Piezoelectric Tweeters MODELS KSN6001A, KSN6005A 3.5 Inch Super Horn

Page 23 of 27

Nominal Power, Impedance, and Distortion Ratings __ 1--t--+---f----+----f----r----IINTERMITI~~ PEAK~A

r;~~-"~-~~-r-.~,-1-- ----~-----1-------~--~"m~E~AA~E~M~US~IC~I-~ ~~ I

: ,_- -- - f-- -.;f\-- ~- ~-:._-.:._-, --=='==--=~ ~~;;,---~~~--- ---0 800 \ ~ - ----· SIGNAL --

7M\ ~ ---- ! 1--1---1-+------+---_ -"""'"+- \ ~ ~7 - , --_ --1---~= 1--1---+---+---1--~:!;--'· ..... ,.,___ ~ --- -- - -I- --- -r -------~-------1- ---- ---~-~---+---+----~~z,~.,.,"'t---- ' I • 1-----+-----+----+----1----=---"""1-·

1----t--1-----+--t--""t'oo. _____ -------1---------~~--+--------;

0 ~

300 500 1000 2000

Frequency Response r ~ lJ I'JJJll!T ; 1 : 1 -4:- T tNPUT:4VOLTS!RMS) r I MICROPHONE DISTANCE: 181NCHES (457mm)

110dB 1

, ,

I 1lf l -- - I ' ccr 1 . 1 ' ;--,~JJ - i y

. t'· I t j -1 IJI_ r -- /: -- , -- t· - -- ~" f+H#--f--+--t-:':f,. · -++ !;j TI,tt"'-f-C+- --;-

i t ' ..

f,f 'I

500 1000- 2000 5000 10000 20000 4a&o FREQUENCY (Hz)

®MOTOROLA INC. COMPONENT PRODUCTS DEPT. Domestic Sales International Sales 2553 N. Edgington {312) 451-1000 Franklin Park, Ill 60131 TWX91D-227-D799 {312)451·1000 TELEX{O) 25·4400

5000

FREQUENCY: (Hz)

Dimensions

10000 20000 40000

-~ and MOTOROLA are trademarks of Motorola Inc Specifications subject to change without notice. Copyright 1976by Motorola Inc. Printed In U. S. A. (7606) Merit

A-29-5-1

Page 24 of 27 SUPPLEMENTAL SHEET ON fREllUENCY ;\DJUSTMFNT OF YOUR TJL TRASONIC UNIT

You will note three controls on the frnnt panel of the console reference "l'RONT VIEW CONSOLE" sketch. The slid,cr switch sel ccts either the "NANUAL" mode of operation or the "AUTOMATIC" mode. The manual mode does not vary i ;1 tone but remains constant depending where the "FREOlJENC:Y ADJUST" knob i :- set. When the sl idcr is placed in the "AlJTO.~IATTC" mode you will note t~e tnne is continually changing from a low to a high value with this rate "f change being controlled by the "SWEEP RATE ADJ[]S~-, knob. The lower 1 i: 1t of this tone is again selected by the "FREOUl'NCY ADJUST" knob and "'ill always vary ahout 5Khz higher than this prese1 1o•; value. As an example; with the "FREQUENCY AD.JUST" knob set at 10Ki;z low end, the high end will sweep to 15Khz, set at 15Khz, the high end will sweep to 20Khz, set ~t 20Khz high end will sweep to 25Khz, (25Khz is the high end limit and should not be exceeded). Obviously, any setting to an i11termediatc value •·< 11 simply add 5Khz as this frequency is varied in the "AUTO" mode.

The recommended method of setting the controls is the following: A. Determine the frequency limits per the applic~tion. There are two hac.ic <'pplications of these type of nnits. When used as an anti-intrusion ,leYicc to discourage unauthorized entrance or access of protected premises, ~hP adjustments are made for maximum human annoyance, usually with frequen­cies of from 10-15Khz. When used a~ a rodent device we have found that the loWC'St tolerable frequency to humans in the area usuallv has the most effect on common species of rats. This is not alwavs true, hut serves as a starting point in initial setting of the adjustments. Prequency setting of from 15 to 20Khz for non-htJmans hahitated areas anJ 2li-25Khz for areas where people are present usually suffices for go•.lcl rat control, Note that 8~ no time should the unit he set to go higher thar, 2SKh~.

B. Adjust "FREQUENCY ADJUST" knob to value where o· i .>.:t· ts detectable hy human ear or just above the point of annoyance.

C. Set "SWFEP RATE" adjust to middle of range.

D. Set slider to "AUTO" and note Crequcncv continually varying. r~ must be noted at this point that there is no optilnt•m fre<Juency setting for conditions of operation, or species, infestation of l"odents, etc. However, we have usually found that it is best to set the device to the lowest tone possible withont causing annoyance to people or pets. The "SWEEP RATE" may be experimented 1<i th for the best rcsul ts. It is assumed that the 1nternnl ndinstments arc set bv the factory or bv the h11ildcr per the instruction al.ignment procedure or<tlinc'<l in the con~ strt1ction plans.

PPFl - p HASER PAIN FIELD Page 25 of 27

~~~1~ ~.;0:"'~~M~2:.11¥:5~~l.~l:~..:ccK:;;:.u:::: . .r~:~:A~Hn~~:~c:::.~Ac:E_o_:-_-~-I~ ·~~, ~'' _.,, ·~:~;~ v~~~,:-~~11 :-. ~-.-:~~ · -:~::-~·~"'~""J"''"'~E"'9N"'5 n"'J o><'2

"":.;;.0 ... _-

--:;...;;.:"":'-~..:::..:::...-+~;-:-:;-~r-:=---l--:-: -~i :--;;nl0

1m ___ ·,, ·--· --:~---- j . :~-----+--:-: --+ --=-~...:::.::..-r-:'-7-""7+..::...-+------ :-- .. -- -------------- ----------- -----------·-· ·--- j---- ------------ . t ------+

1K/25 " ' ~ n I 11 ·fK ·------~ ·t-· ::· _..;;1..;.•..;;2.;;.;K"-/.:02.-"5-+-;;-;;-:;-+-=--f--"--- L" . "K- - -----· ______ ___'_:___ -- - +---

! 4. 7K " I 4.7K/25 " --- ---------- -----------

_..;:5...:. . ..::6.:.:K:...I..:::2.::.5-+..:.:.-=-=-+-=--f--"-----Js __:_~ _!(_ __ _ "

470K/25 '' i"0K _..:._=:,..='-+_..:.-+ ---+-------- ' .

' 1M/25 " ' ' 1 tl

i

lW

10K/PS Rl8 l

A&B • SOK/PD R32 l

! -----f--:-::--+--f--------[ ---·-·· .·- --------

Rl3,

"

''

"

,.

"

"

"

"

i - -·1

' ••••• - 1

.. 1

' ' ---- ~

"

"

"

I " L--

" -t-----

1 "i --:--·-i " - -1 . .

li

" ----+---1 "

i II

------+------------·-·

.. ---- -

" --RCR32

----

.. ~---

3lVM40l --------

I 131VM405 ···t-

-- 1-25K/T 22 2 , .:. S t\: __ !_E ~-¥1- _p_q_t_~~ r---~--- Ti ___ f:!.SJ.Tl __

' ----:~OI)K t~im pot hor '' _ i

r2RH403

lOOK/T Rl7 1 " , --- --------- --- ·r··--·-' ----- ------- t·.- ---- -

. . --(-2 RH_:2.Q.l_

i ! boWKOlO

i"""

PPFl - PHASER PAIN FIELD Page 26 of 27 I VI:NDOR VENDOR#

1 ELCAP lOOOM/'25 ClO lOOOrnfd @25V E1ec CAP ~MCU 20WK901 ---if-------1

_ _..:-'0~0..!. l.t.. I'-' ~;r~1prr..,g_ ;9 -+...!1L._ +_.!:.P.>'Oc~Co!:A'-!P:__+_,_. !d0!d0~1J'I"l!( d @ 5 0 V p o 1 y " " 23PS210

-----t----t---t----t--------------1-------i----l 470P/50 cs 1 -~..!..l:~:...i.!.l<-f-'""'--+~-+-'D'-'Ic.:. C~A£P_+~4J.7_<,0_p fclj 50 V d i s c

' ' 11 l~OU 21CB470

~·-L·~--~21EGolo • 01M ISO CQ 1 -....:..l<..!.£!..<:.2-!L.f-l..;;z.-+_,~,_-+ _ _::_" --+-'-· _\'OC}JJ. rnc_.t f.?L? 0 v d i s c

• 1M/ 2 5 C4 7 2 -....:....!.!l!.L.o~-t-'~L..!.+L-+--" --+"-'· l_rnf_clj 50 V dis c 1- -·- - - .

11 i " 21KF100 t·-··--· ' 1000PISO C3 1 " _ j ___ ~ ·-----¥2"'1'-"E'-'T~0,_0~1

LM566 I2 1

LM3900 Il 1

! semi-conductor -~~.!U!--t-"o.£-+.-!...-+-'I,0C~---jl-v=c o _d,_L'2__~p,~i'-'n_,__ _________ -+-;GJQ .... ~ LM 56 6

IC __ : ___ c:'~_a_~1 ___ ~mp dip · " ; LM3900 ~~~Yr-'-"'--+-"-+-=-"---+ - "'""'-~-"----------;--- ·--t l ~ :

Ql,2, PN2222 B 4 5 5

,---·- ------ . . . -,-- . -------+----1

-.£.!.~£:-".~-~~<-=-+2--+-"-T RAN f--'"l'.r\ __ p_l_ast_;i,_c ________ _L !• I 0 ___ --~r-'P'-'N"-"-2.,2.=2~2'-1 , . , I PN2907 06 1

D40D5 07,8 2

"--J-riEn __ £lii!".!i-"' __ ·r-- :·_ --·--·~ PN29o7

-===~-1-"'-'-''-"-+-"--+---'-' ----+ .. fiEn~_EO_>l.§'_r __ f:_ab _ ---[-PAr::___ D 4 OD 5

2N3055 09 10 2 i '

-~~~.2....-f-l.:2.JC.:.:'4-~-+---'-' ---+'. nl'_fi...P.0."!." r TO 3 . ,_ r: ·~-· ·:. ---~1.N 30 55

I I

-----+--+---+----~----·---------· ......... ---·---'------!

_ _,I.,N:l-4:ll!O..\<O~ll!.-+.><D"'2~-ii-=1~-l~Dc:Ic>0,__--+_,5"-0ccVy_. _l_E\!fl.P_r~e~c"-t"-------- L.\; Q------~--1 N 4 0 0 2

IN914 D1 3 2 " ! I

r!'.iL_~_:L_g 'l_a_1 ·r-G f. R ___ tiN 914

----+---+---+-----+1-'--- -- -r- ! 'i I ,

_ _,M::,:E:cD:!.:!B~O~B!.....+.=:B~o~b~b~if.!--'1~4--"-"TR"Ao_. ---+_rnP.cl_i_u_l'! __ bD)? 9_:l1J.._T ran sf a ~-1- FER_ __ ~ 2PTB • . i i

_ _,M::.;E:cD~C~O:.;:R"E"-l--"--i-=1~-1f--"----J i·_,tr:~~ d .i._u._rr!__f='_.9_ re "E 11 L~_T_!; ____ ---i--~-~5 ~-1 I !

_.!H!,!D~W~R!dU:.!:BcsO'-'L"'+!JHc:D!.!W!JR"'E"+--'1~--tf-EHc:Dc-:W!.!R"'~---b-dw_ tc _..,_b o_lt /b r k t " i FE H I 5 2 u

-.!.M:!JE"-D~L.,!!U~G~Sa_J...!'Lc.!.U!;G,_;S,__!-..!l~_ji---"-----' 'o_l_qt'~-1 US!_§ r::E~R_ - ~21- 4 3 0 I ~ i

_.:.,:M_E_D_U_L_T_R_A+-T-1---'+-1--1--~"--- ::" e2e< !' C> ' • " _ : '" < C: :lW!'U' _,.:K.:.;,f:.;' O:;:_B:!.._ __ j-::K.:.:N:_::1:_,c24-__:2,__+.::H~Dc::W J?41{ ~---~':'_()_i, 4~~-- c 1: 1 ~ 0 C

---+--+---+---[-~~~~-~- -1

I

- ..

__ c=~·~:.: F'l':........;

1

T:..:rn~P-' I "_,\~.:.:'E":..:!F-+-'-AJ~~· A:..:rT.-+-'-.::(L:.:_,;/T~..:..Y_·-_0~_-+J---.,~~~:~r:_r_r~uu_~-'.: '::-'v,-'A:-L-'-U~E __ -!.2~iil'Q R }VENDOR r"" ~~ 7 . o.L;:f+-l.-. -i small rLLi0:i slid- t

lOSM003 _..;S~L:,:S:.,:W::__--l-"S'-'1'---f-1"---1--"S~W,_ _ _ji_;~y.'_j:. t c h e r D i) __ D'-'-T ____ -+1 __ 1~ 0 D

------i'--- '--~ ii d ,;-;;-J:·1;o 3 h" at;;;~ 11lc l -------~

_,..-H~Eu;S!,o: To..N!;'!.!lK~+.£lHc;S,_l:_+~l:__+---.£E'-'N'-'C"---j ii __ _,s ~'.!:.2.1.0!..". v j n 1: !!2.'~-----t IN!'_() ______ ~_ H_ E S INK

------1----+---+-----l._____________ _ ____ ,-. ________ ; __ _

-t ~- -----~ -_£lM'-!T~G"'K~I.;!T~+.!:M:!1K~l_.4 '-'"2---t--'-' ---1'-To }_I!'_O_!O_n t in g k i t s >C" 4 7 3 2

---------+----r---+-------~­--r-~· 1

.. --·--_________ J__ -- -----1------f

_ _;M~O:.;T"'R~A~N"-+~T~D::..l:_-+-'4"--t--=T-"R'"A"'N"-"D'-~ .. rn o _t_ o_r_?_;:?__.§_l1J2_e r _.bc<or n _ .... I '·'.~_A c !

' ------+----l----!------+---------·-------------------------1 3 a~r fuse holder

__ F::..=U~H~O~L~-+..!:F..:H!.l=-.-+-1=-._-!-...!F:.cLcT-"' S. ___ Luc, c, __ '!. a:nr-2_ f u ~"'-----· ..... i

__ R_.,_J_B_P_~_. --1----+-A-· --4-- _ ----~rubber feet s t~i __ c_k_-::..?!.'~-1,

_ _;B~H..::4:.!D::__-1f--"B"-H'-'l"-L, .=2f-'2"--t-~B-0_T ____ j_ 4 D h o J d e r . ·~i._!:!~. _!_ e a i?. i ! ' ----r - .. --~------ -·--- ---------- -· - --~---·-

_ _!W!..;R~4---~~~+=~+.!'W'-".1F'l'c __ Li!2 4 v.;irr.: rr~:d ----------

-·-- ------t-------_.

.

14.50

$74.50

© 2004, 2013 Information Unlimited, all rights reserved www.amazing1.com Rev.4

[1]

1. FREQ/POWER

2. SWEEP

6. REMOTEJACK 8. FUSE

5. 12V IN

3. LOWRANGE

INT BATTERY

EXT 12 V

PPF/PCC InstructionsCONTROLS:

FREQ/POWER - Turn to click on, and rotate for desiredfrequency. Adjusts frequency from 10 to 25 kHz. Mayrequire experimenting for best results. Make note ofshaft setting effectiveness for specific targets.

SWEEP - Click on to enable sweep, and rotate todesired rate. Changes from a slow increasing rate to achirping effect.

LOW RANGE - Switch lowers output frequency toaudible range.

POWER SOURCE - Selects internal batteries orexternal wall adapter with correct mating plug. DOWNposition is internal batteries, UP is external 12 volts.

12 VOLT IN - This jack connects to mating plug of12VDC/1.5A non-regulated Wall adapter (whenPOWER SOURCE switch is set down to EXT 12V).

REMOTE JACK - This jack must be shorted with theincluded mating plug for normal manual operation. Plugmust be removed for wireless remote/canine control.

CANINE - This jack is used with our CanineController (P/N# CANINE10RC).

FUSE - Fuse holder for 2A circuit protection.

WIRELESS REMOTE TRANSMITTER – Twobutton keychain remote. UP=on, DOWN=off.

INSTRUCTIONS

Portable operation: Undo plastic cover frommetal enclosure via screws. Determinebatteries and insert into holders, observingpolarity.

Wall Power: For 115 vac opertion insert plugfrom wall adapter to “12V IN” jack. Unit mayalso be powered from a vehicle. Do notreverse polarity when connecting into vehicle12 volt system.

Test control settings and verify properfunctioning.

7. CANINE

WIRELESS ANTENNA

4. POWERSOURCE

1.

2.

3.

4.

5.

6.

7.

8.

9.

9.

© 2004, 2013 Information Unlimited, all rights reserved www.amazing1.com Rev.4

[2]

PPF/PCC Instructions

ATTENTION: READ INSTRUCTIONS BEFORE USING UNIT.

APPLICATIONYour Phasor Pain field System is capable of operating in two modes. Mode 1 is at afrequency that is known to produce paranoia, nausea, disorientation and otherphysiological effects. Mode 2 allows using the system as an audible alarm to frighten offintruders or warn the user of an intrusion. Both modes may be used in combination andare easily controlled from the front panel by the user.

A WORD OF CAUTION:Ultrasonics are a gray area in many respects when application involves the control ofanimals or even as a human deterrent to unauthorized intrusion. It is always best toconsult with local municipal and state laws before using this device to protect home orproperty. REMEMBER MANY STATE LAWS LEAN MORE TOWARDS THE “RIGHTSOF THE CRIMINAL” RATHER THAN THE VICTIM.

INSTRUCTIONS

1. Position unit so as to direct toward target area. Unit will lose all directionality ifoperated inside of a small volume room. This is due to energy being reflected andrefracted throughout the room.

2. Determine power requirements - "Internal" alkaline batteries will provide about 6hrs of use, but cannot be recharged. Ni-Cads will provide about 2-1/2 to 3 hours butcan be recharged. An "External" supply can be provided by a 12 VDC 2 AMPregulated wall adapter or external 12V battery.

3. Set switch on rear panel to desired position of "Internal" battery or "External"supply.

4. Adjust controls for maximized effect to target subject - experiment for optimumresults.

A. Sweep control contains on/off switch to disable aswell as adjusting the sweep rate.

B. Frequency control contains on/off switch for main powerand adjusts frequency of operation.

C. Low range control allows use as an audible alarm andverifies operation.

D. External control jacks are intended for interfacing toremote detectors such as our canine bark controller orintrusion detection system.

E. Wireless Remote is used for control form a safe distance(frequency control switch must be on and remote bypass plugmust be removed for wireless remote to work).

© 2004, 2013 Information Unlimited, all rights reserved www.amazing1.com Rev.4

[3]

There have been numerous requests for information on the effect of these devices on people.First, it should be made clear that no device such as this should purposely be used on humansand we discourage this use due to the possibility of acoustically sensitive people being highlyirritated.

None of these sonic devices have the ability to stop a person with the same effect as a gun,club or more conventional weapon. They will, however, produce an extremely uncomfortable,irritating and even painful effect in most people. Not everyone experiences this effect to thesame degree. Unfortunately younger women are much more affected than older men due tobeing more acoustically sensitive. The range of the devices depends on many variables and isnormally somewhere between 10 feet and 100 feet.

One possible use of the device (that deserves careful consideration) is the installing of alltransducers, directed to an area where protection against unauthorized intrusion is desired.This produces an irritating and painful feeling to the intruder, along with a condition of paranoiafrom not knowing what to expect next.

ATTENTION!

Your sonic acoustical generator is intended for use as a security or property protection device.Please be aware that certain states do not allow the use of any device that may discourage orimpede any criminal activity, claiming such use is a violation of the law-breakers civil rights.Always check with the proper authorities before installing this device with the intent ofdiscouraging illegal entry or protection of your personal home or property.

We have been alerted that use in MASS, NYC, and WASH DC may require licensingrestrictions in the future when used for security or property protection involving a possibleviolation of the law breakers rights!

We have provided the finished device without labeling or control identification for the usersprotection should he run into any of these stupid regulations. The user may choose to do hislabeling using the instructions and a suitable marking pen.

© 2004, 2013 Information Unlimited, all rights reserved www.amazing1.com Rev.4

[4]

KtMU It Kti.Jt Yt K PUSHBUTIO~~fOR

UARNIN<i OR !IWiiH<i TRANSMITI! RS

R!MOT! OPUIATlON INDICATOR LIGHT

BASIC TROUBLESHOOTING

If you should encounter any difficulties with your remote transmitter not working, it may be due to the receiver not recognizing the transmitter:

r----------TROUBLESHOOTING ----------, 1. Make sure the power switch for the PPF/PCC is in the OFF position. 2. Remove the cover for the PPF/PCC. 3. Connect the power cord and plug into wall/insert batteries in the

battery holder. 4. Make sure power source select switch is in the correct position for what

you are using (internal batteries or external power). 5. Push the remote transmitter' s ON button for one second then push the

OFF button for one second. (Check that remote indicator light turns on for each button push. It light does not turn on and you do not hear the relay click, go to next step. If light does turn on and you do not hear the relay click, ca ll us for further help.)

6. Hold the remote receiver's push button for 1-3 seconds until indicator illuminates, release button and light will then start blinking slowly.

7. Press either button on remote transmitter. The indicator light on the receiver will go out.

8. Press either button on remote t ransmitter again. The receiver indicator light shou ld blink rapidly to show that it has learned t he remote transmitter.

9. Press the remote transmitter's OFF button. 10. Make sure that remote jack is disconnected from the unit. 11. Turn PPF/PCC power switch ON. 12. Press the remote transmitter's ON button. Device should generate

loud noise. 13. Press the remote transmitter's OFF button. Loud noise shou ld stop. 14. Turn PPF/PCC power switch OFF. 15. Remove power cord from PPF/PCC. 16. Reinstall cover for PPF/PCC. 17. Your PPF/PCC is now ready tor normal operation .

..._--------TROUBLESHOOTING----------'

© 2004, 2013 Information Unlimited, all rights reserved www.amazing1.com Rev.4

[5]