JELLYFISH AND A CLOWNFISH NAMED VOLTAIRE

JELLYFISH AND A CLOWNFISH NAMED VOLTAIRE
BE CAREFUL!!! GOT A FRIEND WITH ME HAVING THE LUCKY FIN OF A CLOWNFISH NAMED VOLTAIRE! WE CAN BE VERBALLY AGGRESSIVE.

E = mc3: THE NEED FOR NEGATIVE THEOLOGY

E = mc3: THE NEED FOR NEGATIVE THEOLOGY
FUSION CUISINE: JESUS, EINSTEIN, and MICKEY MOUSE + INTERNETS (E = mc3) = TAO ~g(ZERO the HERO)d~OG

About Me

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Hearing impaired (tendency to appear dumb, dense, and/or aloof), orthodox atheist (believe faith more harmful than doubt), self depreciating sense of humor (confident/not to be confused with low self esteem), ribald sense of humor (satorical/mocking when sensing Condescension), confirmed bachelor (my fate if not my choosing), freakish inclination (unpredictable non-traditionalist opinions), free spirit (nor conformist bohemian) Believe others have said it better...... "Jim! You can be SO SMART, but you can be SO DUMB!" "Jim! You make such a MARTYR of yourself." "He's a nice guy, but...." "You must be from up NORTH!" "You're such a DICK!" "You CRAZY!" "Where the HELL you from?" "Don't QUITE know how to take your personality." My favorite, "You have this... NEED... to be....HONEST!"

Saturday, August 2, 2014

Gyroscope - Wikipedia, the free encyclopedia

Gyroscope - Wikipedia, the free encyclopedia: A gyroscope is a device for measuring or maintaining orientation, based on the principles of angular momentum. Mechanical gyroscopes typically comprise a spinning wheel or disc in which the axle is free to assume any orientation. Although this orientation does not remain fixed, it changes in response to an external torque much less and in a different direction than it would with the large angular momentum associated with the disc's high rate of spin and moment of inertia. The device's orientation remains nearly fixed, regardless of the mounting platform's motion, because mounting the device in a gimbal minimizes external torque.



Within mechanical systems or devices, a conventional gyroscope is a mechanism comprising a rotor journaled to spin about one axis, the journals of the rotor being mounted in an inner gimbal or ring; the inner gimbal is journaled for oscillation in an outer gimbal for a total of two gimbals.



The outer gimbal or ring, which is the gyroscope frame, is mounted so as to pivot about an axis in its own plane determined by the support. This outer gimbal possesses one degree of rotational freedom and its axis possesses none. The next inner gimbal is mounted in the gyroscope frame (outer gimbal) so as to pivot about an axis in its own plane that is always perpendicular to the pivotal axis of the gyroscope frame (outer gimbal). This inner gimbal has two degrees of rotational freedom.



The axle of the spinning wheel defines the spin axis. The rotor is journaled to spin about an axis, which is always perpendicular to the axis of the inner gimbal. So the rotor possesses three degrees of rotational freedom and its axis possesses two. The wheel responds to a force applied about the input axis by a reaction force about the output axis.



The instrument used more like an actual gyroscope was made by German Johann Bohnenberger, who first wrote about it in 1817. At first he called it the "Machine". Bohnenberger's machine was based on a rotating massive sphere. In 1832, American Walter R. Johnson developed a similar device that was based on a rotating disc. The French mathematician Pierre-Simon Laplace, working at the École Polytechnique in Paris, recommended the machine for use as a teaching aid, and thus it came to the attention of Léon Foucault. In 1852, Foucault used it in an experiment involving the rotation of the Earth. It was Foucault who gave the device its modern name, in an experiment to see (Greek skopeein, to see) the Earth's rotation (Greek gyros, circle or rotation), which was visible in the 8 to 10 minutes before friction slowed the spinning rotor.

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