What is PIP?

 
Polycontrast Interference Photography (PIP) is a new scanning system that is internationally recognised as an effective ‘Biofield Imaging System’. It reveals the interference of light patterns, at and beyond, the visible spectrum and shows energy dynamics at work. The theory is based on the fact that our eyes see in two principal ways; amplitude and frequency changes. Firstly, in amplitude changes, low light gives small amplitude changes whereas bright light gives larger ones. Secondly, we see in color, represented by frequency changes – Red has long wavelengths and slow oscillations per second, whereas Violet has shorter wavelength yet faster oscillations.

PIP is used in many ways around the world, from medical and clinical research, to energy field assessment and validating healing techniques. It highlights areas of well-being and disease with clear patterns and colors. The system shows similarities and differences within the body and energy fields. The PIP system also comes with various light interpretation formulas that make PIP possible within a variety of light conditions.

How does it work?

Through specially developed software, PIP looks at photon (light) interference and its changes in and around the body. The innovation is in the computer programming, which allocates a number to each specific grade or frequency of light and then re-codes every number into the visible light range so we can see it. PIP uses software on a PC with a video feed and takes a scan of energetic and light interference. An image is displayed live on a monitor where signals from the video camera are graded into clearly visible colors. Energy intensity differences can be distinguished that would otherwise be impossible to see with the human eye. We don’t see the difference in energy absorption with our own eyes because we use heuristics that generalize colors, patterns and shapes so that we can better distinguish borders and objects.

What does it show?

Scanning a client enables a practitioner to make an energy field assessment, which leads to a better understanding of their health trajectory. Areas of well-being are indicated by a mixture of lighter, brighter, balanced and more harmonious patterns, symmetry and colors, with diseased and stressed areas showing as distorted, darker and congested pools of energy. When used, the operator and client can uncover the root disharmonies of their disease and PIP therefore enables effective monitoring of a client’s ongoing condition.

“An ability to detect illness and energetic disturbances reliably and accurately in a person’s etheric body days or weeks prior to the appearance of actual physical symptoms would be truly miraculous”
(Richard Gerber, 2000)

Hypothesis of Polycontrast Interference Photography

In Polycontrast Interference Photography a subject is continuously exchanging energies with its surrounding environment and forms interference patterns on and around its body with the incident rays from the light source. The energies captured by PIP are electromagnetic and include both visible and invisible ranges. The colors and images shown are interference and transference patterns and captured by a video camera and processed by the PIP software program. This PIP software then re-codes the data and amplifies it into the visible range. To support the electromagnetic vibrations or energy fields it is also possible to measure these using a sophisticated oscilloscope

According to most studies, electromagnetic energies have a strange property; they do not appear to require any medium through which to travel. They behave like waves but do not appear to need a physical medium, like air, in which to travel. Some people thought that these fields were modifications of the subtle medium, or ether.

The human energy field might possibly interfere with photons, 'energy packets of light,' sometimes called 'subtle energy photons'. Ambient (surrounding) light is interfered with by the field both when the incident ray travelling towards the object and when the reflected ray bounces off the object. For capturing images, an analogue or digital video camera is used as it constantly updates and refreshes the image. The software program has to compare the reflected rays with the incident rays and then re-codes them and produces a PIP image. The system identifies a set of numbers from the image and then gives the photons a designated number. It is a digital encoding system and the minutest change in density of photons is recorded and amplified and viewed on a computer screen. It can scan at 50 frames per second, so it is a lot of information being processed.