ANGELS DON‘T PLAY THIS HAARP Advances in Tesla Technology

displays tell the operators how the experiment is progressing, and local and remote sensors -
incoherent scatter radar, riometers and ionsounders and other esoteric sounding apparatus -
monitor the ionosphere.
The Penn State publication article adds that after the major parts of HAARP are
evaluated in the field, ―a comprehensive series of tests will be completed as a demonstration
of the IRI (Ionospheric Research Instrument) capability to the user community. The goals of
HAARP are ambitious, nevertheless, state of the art capability will allow us to realize this
powerful scientific research instrument which will probe the Alaskan sky‖.
Long before HAARP was conceived, the former Soviet Union built more powerful (one
gigawatt at Zelenogradskaya near Moscow) heaters than the west, and involved more
scientists in ionosphere changing experiments than the West. More recently, Max Planck
Institute in Germany built a heater at Tromso, Norway. In 1991 the Europeans caught up to
the Russians by beaming one gigawatt of effective radiated power from Tromso.
The language in some documents hints that an element of mine is bigger than yours
competition goaded the Americans to build a facility that would be three times more
powerful than anything the Russians or the Germans have. Here we must make it clear that
an ionospheric heater isn‘t judged by height. It may look like a five or ten acre field of fiftyfoot
high crosses (technically called crossed dipoles) in a square arrangement. The larger the
area covered by antennae, the more powerful.
Although they are without an ionospheric heater, Penn State still has a respectably sized
department involved in ionospheric modification – ―about ten faculty and maybe 20 grad
students‖. Formerly called the ionospheric research lab, it has become Communications and
Space Sciences. ―It used to be very large, and very interdisciplinary with math, chemistry and
physics people in it. Now it‘s primarily electrical engineering‖, Ferraro said.
John D. Matthews is a physicist who finds himself in the electrical engineering
department at Penn State because of consolidation of departments. His specialty is the area
of the ionosphere down at about the 100 kilometer altitude. During a phone interview he
noted that the main radar (for high frequency ionospheric heating experiments) at Arecibo,
Puerto Rico, can significantly heat the lower ionosphere as well as the upper. The heating is a
Tesult of a high power diagnostic instrument. Arecibo is currently getting a major upgrade.
Most of the heating is done at around 200 kilometers altitude - called the Lower Region
of the ionosphere - because it is easier to heat that higher region to the maximum.
Penn State got in on the ground floor with HAARP. In 1991 several departments at the
university - the Applied Research Laboratory, Computer Engineering and Engineering
Electronic Design Services - combined resources to go after a desirable contract. They were
among the winners. Penn State, APTI and Raytheon Corporation were each given contracts
to study how to design the HAARP facility. Afterward, APTI invited Penn State to join it,
along with SRI International and Ahtna Inc., an Alaskan corporation, as a team.
The Office of Naval Research chose their team to build and demonstrate the powerful
ionospheric heater near Gakona, Alaska. ―The capability will be further expanded to its final
world class performance capability in 1996."
HAARP: SECRET DUETS AND TRIOS?
Ionospheric heaters are a very specialized area of research. ―There are two groups in the
Soviet Union, several people in Europe and maybe ten people in the states. That‘s about it‖,
said Sacha Koustov, a Canadian/Russian ionospheric scientist at the University of
Saskatchewan.
Like most of the atmospheric scientists interviewed, he was not familiar with the HAARP
literature. Hay J. Lunnen, Jr. and Anthony J. Ferraro, ―High Frequency Active Auroral
Research Program‖, Pennsylvania State in house publication.