A Practical Guide to Rife Fullrife-x.com/A Practical Guide to Rife_Full.pdf · Published as Public Domain by Rife-X.com Aug. 2010 1/16 A Practical Guide to Experiment with Rife Frequency

Published as Public Domain by Rife-X.com Aug. 2010 1/16

A Practical Guide to Experiment with Rife Frequency Technology at Minimal Cost.

The Audio Driver RF1 is a driver interface board connected between a frequencygenerator and a subject target. It’s use is strictly for experimental purposes.

Avantages: Driven by the internal soundcard of a laptop/PC computer (5Hz to 20KHz) Driven alternatively, by an instrumentation frequency generator (DC to 4MHz) Input frequency waveforms ‘direct’ or ‘gated’ with a 4MHz RF carrier. (Switch

selectable) Class 2 circuit: operating supply voltage 12V-18Vdc battery or 12Vdc adapter. Output signal: 10Vdc minimum (60ma) with DC offset (‘no’ negative spikes). No output signal attenuation is normally required. Dual output channels (common negative return). Monitoring circuit feedback to laptop/PC to ensure good conductivity. Inexpensive hardware circuit with full documentation in the Public Domain. Input/output drivers socketed for easy replacement or customizing. Easy to interface to. Can drive other devices with additional drive circuitry. Rife frequency generating software available free of charge on the Internet.

Disadvantages: Limited output: one frequency at a time, no heterodyning of multiple frequencies. RF carrier limited to 4MHz. Open frame design, no enclosure.

Disclaimer:

Any experimentation with the ADRF1 circuit is at the total risk or responsibility of the user.The user should be well qualified to assess his/her risks, otherwise the user should seekthe advice of a qualified medical professional before using.

Do not use this circuit if you have a pacemaker or if you are pregnant.Do not place the contact electrodes near the eyes or thyroid gland (throat).

The ADRF1 circuit is not a medical device nor can it cure any disease or medical ailment,any ailment should be referred to the medical expertise of a health care professional. Thecircuit may be beneficial in boosting the immune system which in turn may promote well-being. There are no guarantees to its effectiveness.

This paper is informative by nature and is not to be taken as medically or scientificallyproven. The material and opinions presented are not offered as medical advice for thetreatment or cure of any disease. Please consult a licenced physician for any medicalcondition.

Published to the ‘Public Domain’ by Rife-X.com in August 2010.The information and designs presented may not be used in pursuit of a registered patentworldwide, nor may they be sold to other parties for profit. Email: [email protected]


Startup: Feb. 2010

‘Public domain' plans were followed to built the FreX-PFA-2 amplifier circuit where an audio PCsound card output drives the amp to produce 18V square waves. It worked beautifully andflawlessly. As shown on the website (www.heal-me.com.au), the sharp square wave pulsesproduce rich harmonic frequencies into the low MHz range.

(Additional circuitry is 1st attempt for RF component mixed with TSH22 op-amp. Couldn’t get the TSH22to work above 2MHz with RF, probably due to the saturation of the ouput signal).

But upon trying it out, the sharp square waves tend to round off due to loading by body resistanceand capacitance. The better the conductance with the electrical probes/plates, the more roundedoff the square waves became. Photos show the effect.

While the harmonics are still there, they are much more subdued due to the rounded-off squarewaves on the rising and falling edges of the pulses. Previously, a Hulda Clark ‘Zapper’ was builtto try out as well. The 10 volt output had the same effect once hooked up to a person, though theZapper was more pronounced, probably due to its 1K output impedence. Both of these circuitsproduced square waves with a positive offset which Clark says is important to work effectively.

Beck’s ‘Blood Purifier’ was also built but this device does not fall under the harmonics effect, itsimply passes an alternating polarity DC current through the veins in the wrist, to kill pathogens.

Having looked at the effects and having researched Dr. Rife’s work, he made a point that the lowfrequency signals had to have an RF carrier component because the high frequency carrier isneeded to break through the cells while the low frequency resonated with the pathogensdestroying them. The RF carrier that Rife used, and that he claimed worked well, was between 2-6 MHz apparently.

As a result a circuit was designed and built that accepts low-level audio signals from yourcomputer, or portable MP3 device, and drives a circuit that produced minimum 10VDC pulsesgated or pulsed with high-frequency, while also providing a DC offset. Dr. Richard Loydmentioned that 10VDC was as good as 200VAC, and assumingly that was the basis for Clark’sZappers.


The Audio Driver RF1 circuit was designed to accept bipolar 400mV audio signals, up to 100Khz,and gate a high-frequency oscillator up to 4MHz, which is the practical limit of the CMOS outputdrivers.

The design used a 3.6864MHz oscillator as the HF component, and the circuit was prototyped ona breadboard. It worked well, even without decoupling capacitors. It can be tried out very simply,just strip off all the components that are not required for the prototype, such as the DC adapter,RCA jack, terminal blocks, extra 15V voltage regulator and second output driver IC. All that isrequired is the MAX487 receiver, the 5V regulator, the MXO45 (3.6864MHz) oscillator, and theCD4504BE CMOS buffer IC.

The circuit was built, tested, and everything worked well. (Not tried with MP3 player yet). Detailswith regards to the high-frequency carrier that Rife insisted upon, are available on the websitementioned above, re: James Bare hyperlink.

This circuit will be published in the ‘public domain’ to advance Rife technology, should it be of anyvalue.

Here are the circuit’s characteristics:

The ouptut waveform is clean, sharp and of sufficient amplitude, typically over 15 volts. The RFcomponent is also fairly clean with decent square wave pulses. There is a 1.4V DC offset biasfrom ground which still gives a differential voltage of greater than 10VDC at 60ma. See below:

The setting on the scope is 5V/division, notice the 1.4V offset from ground (set at 2 divisionsbelow the center-line of the scope).

Now hookup the electrode wiring:


Notice the 3.68MHz pulses before/after hooking electrode wires to the circuit board. They are notnegative when electrode wiring is not hooked-up (left). Hooked up, the wires radiate RF energy.

Ground is at 2 divisions below the centerline. Spikes below the 2nd division are negative. (-3.5V)

The pictures on the right side above would not be acceptable to Dr. Hulda Clark because of thenegative spikes. However, when a person is hooked up to the electrodes, this dampens andabsorbs the HF component and with the 1.4 VDC offset, the spikes no longer extend into thenegative range, below ground. (Electrode wiring is 4ft. long) :

The signals were identical whether the electrodes were hand-held or in contact with the feet.

A 100 Ohm resistor on the output of the IC drivers,helps this attenuation, yet the differential outputpulses still exceed the +10VDC spec.These pictures are taken with the scope probe atthe electrodes end (away from the circuit board).


Two Audio Driver RF1 circuits are shown below populated with both options of output driver ICs.

The option of 2 different Output Buffer ICs is only in case one IC is not available or discontinued.

Everything is mounted on sockets so that different oscillator frequencies can be experimentedwith and, in case an IC is blown, for easy replacement. The circuit accepts either full-can or half-can oscillator packages, but they must have the output Tri-state/enable function.

On the 1st. protoype circuits, the 100 ohm output resistors are not mounted on board, neither isthe jumper to short the 1.4VDC offset bias (solder jumper wire across diodes to remove DC offsetbias). This may be beneficial to drive a bank of LEDs directly from this circuit. Question is, willthe LEDs be modulating the light with a high-frequency component as Rife wanted. This is still tobe experimented with.

The Audio Driver RF1 will be used in different applications from electrodes, LEDS, possiblydriving a Plasma Lamp or other light sources with additional external drive circuitry.

Prototypes may be made available to researchers who wish to experiment with this circuit.Schematic and Eagle PCB CAD files are also available.

Note: The ICs chosen in this design make for a simple compact circuit, but any mix of off -the-shelf or discrete parts can be used to achieve the same functionality, though a little more complexto build.

This information is public domain and if anyone, who has experience with such circuits,has anything of value to add, please share this information for the common good.Conversely, should anyone have cautions or reservations, with regards to this, pleaseshare these as well.

Any experimentation with this circuit is at the total risk or responsibility of the user. Theuser should be well qualified to assess his/her risks, otherwise the user should seek theadvice of a qualified medical professional.


Further development of the Audio Driver RF1 circuit Rev2. April 2010

The Rife frequencies listed are all audio range square wave frequencies which depend on higherfrequency harmonics to attack the pathogens. Could we actually apply higher sq. wavefrequencies (Hoyland’s) directly and obtain stronger signals that might be more effective? Thiswould require that a function generator be used instead of the audio output of a PC sound cardwhich is usually limited to 20KHz.

Note: Hoyland’s listed frequencies were ‘sine-waves’ and thus generating higher frequencyharmonics from the Plasma tube ignition. This is not the case here. Can we use square waves,and their harmonics, at Hoyland’s frequencies and be effective?

The function generator is only required to output 0-2MHz square waves, typically bipolar +/- 500mv (+/-2.5V max) with the possibility of adjusting the duty cycle to a 70/30% ratio. FunctionGenerator Kits may satisfy this requirement. Also FGs from Ebay are available at reasonableprices. Some digital multimeters have frequency counter inputs as well, 2MHz would be required.(Adjusting the duty cycle, from the symmetrical 50/50 ratio, decreases the output frequencyproportionally). In the experiments described below, a 5MHz function generator was used.

Modification to the Audio Driver RF1 circuit:

1) The limitation of the 100KHz signal audio signal into the input circuit of the MAX487driver/receiver IC was solved by using the MAX481 IC which allowed operation close to 5MHz, astested. The slew-rate control circuitry of the MAX487 limited the bandwidth while the MAX481provides a wider bandwidth with a decently clean 0-5V square wave output right up to 5MHz.

2) The OSC frequency was increased slightly from 3.6864MHz to 4MHz. The CMOS outputdriver ICs tested (Texas Instruments CD4504BE) can typically handle signals to 4.3MHz beforeserious degradation of the outputs.

3) As the input frequency approaches the RF frequency, the gated signal from the 4MHz OSCbecomes impossible to control, sometimes hitting it perfectly and other times missing the beatand producing eradict signals which are impossible to control and measure.

The gated RF circuitry works fairly reliably with input signals up to 400-500KHz. Beyond thatfrequency, it is recommended that the MAX481 IC drive the output IC buffers directly, bypassingthe gated RF OSC. For this purpose, a selector jumper header/switch allows the choice from theinput signal directly or from the gated OSC stage. Select DS for direct input signal and GS forgated OSC signal.

Typically, the gated OSC would be bypassed when input signals exceed 400-500KHz. Hopefullythere would be enough ‘cell penetration’ at that frequency to be effective, since Rife’s preferred 2-6MHz RF signal would no longer be achieved. Example: the frequency of 770KHz (Hoyland’s) forB.Coli FV would be fed directly to the input receiver to drive the output buffers. This also appliesfor the 1.604MHz Bacillus X cancer frequency.

4) An optional jumper was installed to allow bypassing the 2 diodes to ground (1.4V bias) whenthis circuit is used to drive LEDs directly or external drive circuitry for higher loads.

5) Provision to install an input series capacitor should the input drive signal be unipolar. Thiswould convert the input to the AC signal that is required to drive the circuit. A 4.7-6.8uF capacitorworks well from 200Hz to 5MHz with a 2V input signal. A 500mV input signal has less bandwidth.

Optionally, a unipolar differential drive signal (RS-485) could be used to drive the inputs,especially at very low frequencies. Or just feed a signal and its inverted signal to the inputs.


The following photos show the effect of Duty Cycle adjustment to the circuitry. The left photo is50/50 duty cycle, the right photo is about 60/40 (also not of the same frequency as on the left).As the duty cycle is increased, the waveform period is extended and the frequency is lowered.

The next photos show the circuit used to drive banks of blue LEDS. The 1.4V ground bias isshorted to use the full range of the signal. The scope ground is positioned on the centreline ofthe display. Notice the negative spikes on the waveforms, which should not have any effect sincefrequencies are being administered by a light source instead of an electrical electrode connection.Direct frequency, gated frequency and varying duty cycles are shown.


Driving LEDs: One Audio Driver RF1 controller can drive 24 LEDs. Each output buffer IC(CD4504BE) can drive 3 banks of 4 LEDs with a 150 ohm current limiting resistor in series witheach bank. The LEDs are spaced 0.3 x 0.3” apart and cover an area of 1.2”x1.8”. The LEDs aresuper bright Kingbright part no. WP711PBC-Z.

The 1st photo below was purposely taken at an angle so that it can be captured withoutoverexposing the camera. Typically, these LEDs provide 5000mcd at 470nm with a 20 degreeviewing angle and a 3.2V drop across each. (Do not look directly at the LEDs).

The 2nd photo shows the effects of inceasing the frequency on the LEDs. As 1MHz wasapproached the light from the LEDs decreased sharply. This is the frequency bandwidth of theLEDs and demonstrates that above 500KHz, they become largely ineffective. Therefore replacethe 4MHz oscillator with a 500KHz oscillator when working with these LEDs.

The scope photo shows the signal waveform across the LEDs.

To increase the array and drive additonal LEDs, one circuit could control the frequency signalsand drive additional buffers in parallel with the original buffers. PCBs populated with just theoutput stage and with the power (18V, 5V) and the frequency signal hardwired between them,would be sufficient. Power must be applied to all boards at the same time. If separate DCadapters are used, a common power bar with switch should be used.

The next step is to drive Philips’ Luxeon 1W Blue LEDs, to see the effect.

Alternatively, the 6x greater low sinkingcurrent of the 4050BE output driver chipscould be used to an advantage, byinverting the signal waveform and dutycycle, and driving more banks of LEDsfrom the same buffer. (Alternatively usethe 4049BC). Heat sinking or air flow(fan) may be required to keep the ICscool.Color and wavelength of light are veryimportant, are there significant effectspulsing the LEDs with frequencies?


July 2010

Audio Driver RF1 Frequency Circuit - Electrode Hook-up and Monitoring

This next section will illustrate how to hookup the contact electrodes, and also include anadditional circuit that will reverse the polarity of the signals based on a timing circuitwhich sequences small mechanical relays.

The polarity reversal was used in both Robert Beck’s Blood Electrification and the lesssophisticated Godzilla Blood Purifier devices. In the Beck device, the 27Vdc outputsignal switches polarity 4 times/second (4Hz), while in the basic Godzilla device, thesignal is unidirectional but it is recommended to manually reverse the electrodes everyfew minutes or so. The reversal of direction of the electrical current may attack thepathogens more efficiently and completely. This is provided for experimentation.

Milliamp current flow will take the path of least resistance. Therefore you will havemore milliamp current flow between the hands in body figures 2&4 below, then betweenthe hand and foot. Position the contact electrodes for the best effect on the targeted area.The strongest flow of milliamp current will deliver the best coverage of the frequencies.For example, to target the prostate, it may be best to use foot contacts only to deliver thefrequencies from one leg to the other. (Use only one set of contacts across the feet + / -).

Additionally, the software used to generate and monitor the frequencies will be reviewed.Although there is milliamp current sensation when the electrodes are handled, a visualfeedback is beneficial as well, though not absolutely necessary. Frequencies in the lowerhundred Hertz range are sensed more easily than the frequencies in the thousands ofHertz (KHz, Kilohertz). Furthermore, the RF carrier applied to the gated audio pulsesignal, make it still more difficult to be sensed. For a quick test of conductivity, it is bestto temporarily switch to the ‘direct’ audio range signal rather than the ‘gated’ RF signal,at a frequency below 500Hz.

For that reason, if visual feedback is not used, lower frequencies (300Hz) of typicallyshort duration (~30 secs) are included at different steps throughout the frequencysequence, just to check that proper contact is still being made. (If it is not, check theleads and connections, and/or whether the material covering the contact elecrtrodes areproperly wetted with a baking soda or salt/water solution).

Note: An RF signal that is gated by a lower frequency signal can also be describedas an ‘amplitude-modulated’ RF signal.


Setup

Note: Instead of trying to download ‘MP3 Frequency files’, generated by software froma PC, to portable devices, use an old laptop (netbook) computer directly. Laptopcomputers are extremely inexpensive now and even less so ‘used’ ones. Nothing fancy isrequired, almost any old laptop will do. Old laptops are being given away as well. Theprograms illustrated below work very well in old laptops with their older operatingsystems. Check the suppliers’ website for earlier versions of their software if you havean older operating system, it is usually not necessary to upgrade the operating system.

The 1st photo shows the original Audio Driver RF1 circuit (ADRF1) connected to aseparate interface circuit that will monitor and provide feedback to the PC soundcard.These circuits are mounted in a 3” wide Snaptrack plastic extrusion for convenience.Power is supplied by a 12V 1000ma UL rated Class2 transformer DC adapter, which willallow safe operation from the electrical service. Alternatively, the circuit can run on two9V batteries connected in series to provide 16/18Vdc power to the circuit. This preventsnoise radiated back into the house wiring through the AC adapter. Battery power ispreferred by the experts. Two 9V battery snaps can be connected directly to the ADRF1circuit. (Recommended batteries are the rechargeable Nickel-Metal Hydride type). The2nd photo shows a standard 6ft. audio cable (3.5mm stereo plug to RCA phono plugs)plugged into the Audio-In jack of the circuit.

Connect the Line-out (Headphones) of the laptop soundcard to the Audio Input of theADRF1 circuit. This signal is AC coupled and connects directly to the jack. Please referto the schematic for further details and limitations of the input signals and their frequencyranges. Soundcards are typically limited from 5 Hz to 20KHz. Other types of signals,from DC to higher frequencies (max. 4MHz), can be connected directly from a test/repairshop frequency generator to the ADRF1 circuit. If you are not sure how to configure theinput, please consult the schematics and someone with a knowledge of electronics.

Attention: The redesigned ADRF1 Rev2 circuit combines these 2 separate circuitfunctions into one PCB assembly. EaglePCB Cad files are available on-line.


The contact electrode is a 3/4” dia. stainless steel tube 4” long (made from a polishedkitchen egg-cutter utensil) to which a hole is drilled and a 6-32x 3/8” long stainless steelscrew is attached with a lockwasher and nut (best if they are stainless too, but notabsolutely necessary). The tube has a piece of terrycloth material (dollar-store facecloth)wrapped around it which is held in place with 2 small rubberbands. This allowsdampening the material with a conductive solution, such as baking soda or salt/water, tomake proper contact between the electrode and body. (Any cotton material can be used,even paper towels). The alligator clip-lead is clipped onto the screw of the contactelectrode. (Any other means of electrical connection can also be used).

This photo shows the contact electrodewiring connected to the circuit. Each set ofwires are connected to the board with plug-in terminal block connectors.Regular speaker wires (20AWG), withalligator clips attached to each end of wire,are used to connect to the contactelectrodes. Speaker wires are normallycolor-coded which may be used to identifythe + / - signals. Recommended wirelength is 4ft. maximum.Note: Radio-Frequency Interferencemay result with the use of this RF circuit.It is the responsibility of the user to complywith domestic emission regulations.(If required, remove the high frequencyoscillator and operate below 10KHz).


Foot contact electrodes can be made from the same stainless steel tube. Push an elasticstrap (dollar store) through the tube so that it can be tied (single knot) around the footwhile exerting a little pressure. (in photo, terrycloth material has not been wetted yet).

Laptop and Frequency Generating Software

Many different frequency generating programs (Rife) are available on the Internet. Thesoftware used in this demonstration is very sophisticated, having excellent features, and isprovided free of charge. If you do not register the program and pay the registration fee,the program interrupts every 10 minutes, and must be restarted manually. Best to registerthe program to work continuously, and to reward/encourage the developer for hisprecious time and expertise in providing an invaluable program for experimentation.Visit website: http://www.heal-me.com.au/ and download the FreX16 software which iscompatible with all operating systems from Win95 on.

The 1st photo shows the FreX16 program running with its display of frequencywaveforms and its spectrum analyser. It is a very easy straightforward program to use.


The signal generated by the program is output at the ‘Line-Out’ stereo jack of the PC.

The 2nd photo shows the visual feedback monitoring program for those would wish to usethis feature. It is positioned at the lower right-hand corner of the screen with only the top‘scope’ window showing, its spectrum analyser is not shown nor necessary.

The “Visual Analyser” monitoring program is also a top quality software that is free ofcharge. Please encourage the developer for his worthy efforts. Visit the website at:http://www.sillanumsoft.org/ to download and contribute. Download the version whichis compatible with your operating system, from Win95 on.

Select the ‘scope’ function , click ON, and connect the Audio Output jack, of the ADRF1circuit, to the Line-in or Mic-in of the laptop. Adjust the potentiometer setting on theADRF1 for the appropriate signal strength. Refer to the schematic for details and watchthe scope signals and bar-graph levels to detect conductivity when holding the contactelectrodes. A preload resistance across the contact electrodes will show an initial signalon the PC scope: 1st photo. Interactively, adjust the gain of the scope signal as required.

The RF component of the waveform will not be visible as it exceeds the frequencybandwidth of the laptop soundcard and therefore is filtered out. However the RF is notrequired to observe the effect of loading (conductivity) by the body. The signalamplitude will increase when making good contact: 2nd photo. Hold and release theelectrodes for comparison. The easiest way to compare is to watch the ‘blue’ signalstrength bar graph just to the right of the PC scope display on the VA program.

NB: The circuit board has a switch to select monitoring of output channel A or B.


The 1st photo shows the RCA plug connected to the Audio Output jack of the ADRF1, asmentioned above. It is not always apparent which plug to use, the red one or the blackone, this depends on your laptop, try either one. Also shown is the addition of thesequential polarity reversing circuit. It is powered by the ADRF1 circuit and connects tothe monitoring circuit having removed the contact electrode wiring. The electrode wiringis now connected at the output side of the relay circuit. The relay timing can be adjustedfrom 2 sec to approximately 80 sec (at 12-16Vdc supply) by the small potentiometer. Aswitch selects the relay switching pattern from 2-Phase half-cyle to 4-Phase full cycle.The switching pattern is described on the schematic diagram of the relay circuit.Illustrations of the expected modulated frequency signal flow are shown below.

The 2nd photo shows the complete setup in operation. Notice that alligator clip leadswere cut in half and soldered to the speaker wires. The Yellow leads are the + pos signalwires while the Green leads are the – neg signal wires. Though there are 2 outputchannels A & B, the Green – neg signals are commoned together on the ADRF1 board.

Keep arms away from legs to prevent any electrically shorted paths for the frequencysignals, even if wearing jeans since they may become dampened by contact with the handelectrodes and allow leakage currents. Also protect the furniture/upholstery from thewetted contact electrodes, salt solutions stain.

The rest is pretty much up to experimentation with frequencies, durations and polarities.There is no signal attenuation from the ADRF1 circuit as the 12-15Vdc output signal iswell within safe operating range of a Class 2 circuit and typically produces no harmfuleffects. The output signal may be attentuated externally by inserting a series resistance inthe + pos output lead if required. R8 and R9 may also be increased on the ADRF1 board.

The body figures below assumes that the + pos contact electrodes are applied to the handswith the – neg electrodes applied to the feet. The polarity reversal then occurs as shownin the figures by the switching pattern of the relays. (Re: schematic diagram for pattern).


1 2

3 4


Figs. 1 & 3 above show the patterns for the 2-Phase half-cycle operation, while Figs. 1, 2,3 and 4 show the 4-Phase full-cycle operation. A jumper on the relay board may beselected to reset and hold the relay pattern so that all relays are off, resulting in theADRF1 circuit driving the electrode wiring directly.

Function Generator driving the ADRF1 board directly instead of a PC Soundcard.

Links/References:

Journal of Experimental and Clinical Cancer Research 2009, 28:51 doi:10.1186/1756-9966-28-51 (also: www.jeccr.com/content/28/1/51)Amplitude-modulated electromagnetic fields for the treatment of cancer: Discovery oftumor-specific frequencies and assessment of a novel therapeutic approach.http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2672058/#B15

Patent Application: Parasite Treatment with Electric Fieldshttp://www.faqs.org/patents/app/20090043346http://www.rexresearch.com/palti/palti.htmhttp://www.novocuretrial.com/science.html

www.rife.org http://www.rt66.com/~rifetech/

http://www.heal-me.com.au/ http://www.resonantlight.com/

http://www.futurefrequency.com/component/content/article/3-front-page/62-mopa-amplifier-replica

http://articles.mercola.com/sites/articles/archive/2010/02/27/what-to-do-when-doctors-and-naturopaths-fail-you.aspx

To generate most of thefrequencies, listed in the CAFL, a2MHz waveform generator isrequired. However if variableduty cycles are desired, then a5MHz generator would bepreferred since frequenciesdecrease as duty cycles increase.An oscilloscope is useful toobserve the waveforms.

A Practical Guide to Rife Fullrife-x.com/A Practical Guide to Rife_Full.pdf · Published as Public Domain by Rife-X.com Aug. 2010 1/16 A Practical Guide to Experiment with Rife Frequency

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