PCYPHER LIGHT

ADVANCED SOFTWARE AND HARDWARE FOR ANYONE... ANYWHERE.

AMAZING NEW DISCOVERY! The ultimate encryption system is called Pcypher Light. Randomized keys taken from localized photon activity.

The heart of any crypto system is its keys. The best systems to date have used radioactive decay (ie... atomic clocks) to make their keys. However, even that technology is now obsolete. INTRODUCING...Pcypher Light. Secure keys generated by advanced fiber-optic communications hardware. Get both shot, and thermal noise with photonic activity. The result is you can create massive amounts of REAL random numbers. Pcypher light can measure high/lower energy values over a wide spectrum of light, spanning Ultra-Violet on one end to the mid-infared on the other.

QUANTUM RANDOM NUMBER GENERATOR HARDWARE INCLUDED

NEW Upgraded light probe comes in rugged metal case. Just use ordinary light. In fact, the Pcypher Light probe actually measures light you cannot see.

Pcypher Light is designed to measure the number of photons from around your PC (light particles) and create a random numbers from that light. Pcypher Light is NOT just software but hardware as well. It is easy to install and use. We give you SOFTWAR's advanced technology Light Probe, a highly sensitive phototransistor, which the software samples at thousands of times per second. Think of it as a microphone for light. In fact all you have to do is plug it directly into the MIC input of any PC sound card. That is it. Run the PC Windows software and start making REAL randomized keys. NOT A PSEUDO KEY GENERATOR.

The Light Probe is sensitive to both visible and infrared light. You can use any light source of your choice, natural or artificial. The sun, lamps, flashlights, flames, CRTs... Any source of light! Even reflections. You can create as many keys as you like. Photon keys are 100% compatible the DOS version of Pcypher.

LIGHT PROBE SENSOR SPECTRAL RESPONSE

 % 100 +                             *   *
    90 +                        *            *
    80 +                     *                  *
    70 +                  *                      *
    60 +                *                        *
    50 +              *                           *
    40 +            *                             *
    30 +          *                                *
    20 +       *                                    *
    10 +    *                                         *
        ----x-----x-----x-----x-----x-----x-----x-----x-
          400   500   600   700   800   900  1000   1100

                 WAVELENGTH IN NANOMETERS
       *************************************************
       UV-->VISIBLE-------------->INFRA-RED------------>
       *************************************************

Absolute Maximum Ratings

• Collector-Emitter Voltage 30 Volt
• Emitter-Collector Voltage 5 Volt
• Power Dissipation 70 mW
• Operating Range -40C to 85C
• test conditions: Sunlight at 25 degrees C (76 F)

The sensor will be capable of detecting both amplitude and frequency modulation across a wide band of photon emissions, ranging from ultra-violet to the infra-red wavelengths. The typical output of several photon emission sources is listed below. However, generation of photons is not limited to the sources listed. Other photon emitters, such as combustion using gas, liquid or solid materials, LEDs, lasers, or natural sources such as sunlight, are also available.

TYPICAL EMITTER SPECTRAL OUTPUT

 % 100 +              *     # # # #            @  @  @
    90 +           *    #           #   #   @    
    80 +          *  *# *                @ #      
    70 +          * #    *           @        #   
    60 +          #       *     @               # 
    50 +        # *           @                    #
    40 +      #   *       @ *                         #
    30 +    #     *    @       *                    
    20 +  #     * @              *                   
    10 +#   @  *                   *                   
        ----x-----x-----x-----x-----x-----x-----x-----x-
          400   500   600   700   800   900  1000   1100

                 WAVELENGTH IN NANOMETERS
       *************************************************
       UV-->VISIBLE-------------->INFRA-RED------------>
       *************************************************

KEY : * = NEON LAMP
      @ = TUNGSTEN LAMP
      # = HALOGEN LAMP

The use of electrical power sources for photon generation would seem to present predictable values, according to the type of power input to the emitter. However, randomization factors can be introduced by combinations of light/dark values. D/C current provides a steady light output that varies, according to condition of the emitter and D/C source. Typical U.S. A/C current provides a 60 Hertz cycle in most systems, including lamps. Yet, many other variables effect photon output and sensor detection, providing sufficient randomization which can be extracted. In fact, it is very difficult to produce non-randomized photon output without using light emitting diodes (LEDs) or lasers. Some of the randomization factors are:

• Shot random noise.
• Thermal random noise.
• Modulation of emitter sources.
• Multiple emitter sources.
• Distance from sources.
• Source temperatures.
• Sensor temperature.
• Condition of emitter filament or gas.
• Condition of ballast (neon).
• Variations in source electrical current.
• Harmonics generated in light spectra by emitter.
• Reflection/absorption of light from surrounding materials.
• Movement of sensor.
• Movement of light sources.
• Movement of reflective/absorbing objects around sensor.
• Movement of shadows across sensor.
• Atmospheric motion (wind).
• Atmospheric pressure.
• Atmospheric temperature.
• Atmospheric humidity.
• Atmospheric dust, or smoke.

Light is very effective in the generation of random numbers for encryption. The sensor selected has other advantages over current analog systems. First, it has a low cost and can be provided in quantity. Second, each sensor will vary in size and output, even under the best production conditions, and those variations will change randomly as the sensor ages in the field. It is not impossible to randomly size or configure each sensor because, as many Quality Assurance specialists can testify, it is very difficult to make two that are identical. This may actually be an advantage, and production with randomized output will be an even greater challenge to Q/A. Third, the sensor is rugged, small and light weight. The sensor can easily be mounted to a variety of surfaces and withstand huge variations of environmental conditions, from the bottom of the ocean to the depths of space. Milspec versions are also available in quantity which can withstand hard vacuum and radiation, conditions that far exceed most user applications. Finally, the source of random data, light, is available in quantity all around us.

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