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Radio waves faster than light
" Using such a pulse pattern makes the echo, which arrives back from the
moon 2.4 seconds later". From: http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* |
Radio waves faster than light
"Szczepan Bialek" ha scritto nel messaggio ... 384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* No. Maybe I don't understand the complex calculation under your quoted division by 2.4, but.... Your "mean distance" have to be doubled: received *back* in 2,4 sec mean that the signal traveled the double distance. At minimum distance the moon is 356375 km far from earth. 356375*2 is 712750 km, that at light speed means a travel time of 2,37 sec. Any greatest distance agree with classical physics laws, and a normal mind don't care if the light travel faster, maybe care about the distance of the moon at the time of test: exactly 360000 km from the earth. Don't you ? -.-. --.-, Italy. (sorry for my poor english). |
Radio waves faster than light
On Mar 7, 8:17*am, "Szczepan Bialek" wrote:
" Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From:http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* i'm glad you checked their calculation and found that obvious error... i guess all the other radar calibrations in the world have to be changed to account for the bialek speed effect... i wonder if that would get you out of a radar gun speeding ticket? |
Radio waves faster than light
Użytkownik "-.-. --.-" napisał w wiadomości ... "Szczepan Bialek" ha scritto nel messaggio ... 384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* No. Maybe I don't understand the complex calculation under your quoted division by 2.4, but.... You understand. Should be: 2x384 000 = 320 000. Your "mean distance" have to be doubled: received *back* in 2,4 sec mean that the signal traveled the double distance. At minimum distance the moon is 356375 km far from earth. 356375*2 is 712750 km, that at light speed means a travel time of 2,37 sec. The test was made at "full Moon". ""Even though lunar echoes have been detected before at higher frequencies, it was really exciting to see them arrive in real time out under the full moon in the New Mexico desert," I do not know the distance. But some radio amateur practice communication via Moon. Have they own observations? Any greatest distance agree with classical physics laws, and a normal mind don't care if the light travel faster, maybe care about the distance of the moon at the time of test: exactly 360000 km from the earth. Now are transmitters on the Mars. They are able to give the answer for Maxwell. He wrote: " " Incidentally, Maxwell once suggested that Roemer's method could be used to test for the isotropy of light speed, i.e., to test whether the speed of light is the same in all directions. Roemer's method can be regarded as a means of measuring the speed of light in the direction from Jupiter to the Earth. Jupiter has an orbital period of about 12 years, so if we use Roemer's method to evaluate the speed of light several times over a 12 year period, we will be evaluating the speed in all possible directions (in the plane of the ecliptic). " From: http://www.mathpages.com/home/kmath203/kmath203.htm As you see Maxwell care if the light travel everywhere with the same speed. The same is with the wave lenght. Longer water waves travel faster. Is it the same with radio waves? S* |
Radio waves faster than light
Uzytkownik "K1TTT" napisal w wiadomosci ... On Mar 7, 8:17 am, "Szczepan Bialek" wrote: " Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From:http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 384 000/2.4 = 320 000 km/s. Should be 2x384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* i'm glad you checked their calculation and found that obvious error... i guess all the other radar calibrations in the world have to be changed to account for the bialek speed effect... i wonder if that would get you out of a radar gun speeding ticket? Did you communications via Moon? S* |
Radio waves faster than light
On Mar 7, 5:22*pm, "Szczepan Bialek" wrote:
U ytkownik "-.-. --.-" napisa w wiadomo ... "Szczepan Bialek" ha scritto nel messaggio .. . 384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* No. Maybe I don't understand the complex calculation under your quoted division by 2.4, but.... You understand. Should be: 2x384 000 = 320 000. Your "mean distance" have to be doubled: received *back* in 2,4 sec mean that the signal traveled the double distance. At minimum distance the moon is 356375 km far from earth. 356375*2 is 712750 km, that at light speed means a travel time of 2,37 sec. The test was made at "full Moon". ""Even though lunar echoes have been detected before at higher frequencies, it was really exciting to see them arrive in real time out under the full moon in the New Mexico desert," I do not know the distance. But some radio amateur practice communication via Moon. Have they own observations? Any greatest distance agree with classical physics laws, and a normal mind don't care *if the light travel faster, maybe care about the distance of the moon at the time of test: exactly 360000 km from the earth. Now are transmitters on the Mars. They are able to give the answer forMaxwell. He wrote: " " Incidentally, Maxwell once suggested that Roemer's method could be used to test for the isotropy of light speed, i.e., to test whether the speed of light is the same in all directions. Roemer's method can be regarded as a means of measuring the speed of light in the direction from Jupiter to the Earth. Jupiter has an orbital period of about 12 years, so if we use Roemer's method to evaluate the speed of light several times over a 12 year period, we will be evaluating the speed in all possible directions (in the plane of the ecliptic). " From:http://www.mathpages.com/home/kmath203/kmath203.htm As you see Maxwell care if the light travel everywhere with the same speed. The same is with the wave lenght. Longer water waves travel faster. Is it the same with radio waves? S* no |
Radio waves faster than light
On Mar 7, 5:27*pm, "Szczepan Bialek" wrote:
Uzytkownik "K1TTT" napisal w ... On Mar 7, 8:17 am, "Szczepan Bialek" wrote: " Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From:http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 384 000/2.4 = 320 000 km/s. Should be 2x384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* i'm glad you checked their calculation and found that obvious error... i guess all the other radar calibrations in the world have to be changed to account for the bialek speed effect... i wonder if that would get you out of a radar gun speeding ticket? Did you communications via Moon? S* do you? |
Radio waves faster than light
On 3/7/2011 11:27 AM, Szczepan Bialek wrote:
Uzytkownik napisal w wiadomosci ... On Mar 7, 8:17 am, "Szczepan wrote: " Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From:http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 384 000/2.4 = 320 000 km/s. Should be 2x384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* i'm glad you checked their calculation and found that obvious error... i guess all the other radar calibrations in the world have to be changed to account for the bialek speed effect... i wonder if that would get you out of a radar gun speeding ticket? Did you communications via Moon? S* I have, at another amateur's station, on 432 MHz. Surprisingly the speed came out almost dead on 300m/microsecond. Used .wav file recording of transmit and echo and a good sound file editor with sub-millisecond resolution when zoomed. tom K0TAR |
Radio waves faster than light
tom wrote:
I have, at another amateur's station, on 432 MHz. Surprisingly the speed came out almost dead on 300m/microsecond. Used .wav file recording of transmit and echo and a good sound file editor with sub-millisecond resolution when zoomed. Surprisingly? You were thinking that propagation might be at some other rate? the dominant error source in your measurement is probably the sound card's clock. For other fun measurements of em propagation speed.. melting the mode pattern of a microwave oven cooking chamber at 2450 MHz into a single layer of marshmallows on a plate (turning off the rotating turntable and mode-stirrer, of course). Chocolate morsels might also work. Other methods, for visible light, include the spinning toothed wheels of Fizeau and rotating multifacet prisms of Foucault (later updated by Michelson) Interference fringes from a laser, as well. if one is looking for more "radio" than "light".. look at the doppler effect from a moving source. The fractional change in frequency is equal to the velocity/propagation velocity. If you do something like measure the frequency from, oh, an orbiting satellite and get the whole "doppler curve" you can figure out the frequency of the oscillator (it's the frequency at which the second derivative of measured frequency goes through zero). You can measure the velocity of the satellite optically (if you pick a satellite which is visible, like ISS) |
Radio waves faster than light
On 3/7/2011 2:17 AM, Szczepan Bialek wrote:
" Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From: http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* There is no space. It is packed with compressed aether. John |
Radio waves faster than light
On 3/7/2011 7:04 PM, Jim Lux wrote:
tom wrote: I have, at another amateur's station, on 432 MHz. Surprisingly the speed came out almost dead on 300m/microsecond. Used .wav file recording of transmit and echo and a good sound file editor with sub-millisecond resolution when zoomed. Surprisingly? With implied facetiousness. Should have been more obvious I guess. 10m dish with full legal power, BTW. Very good signal to noise. tom K0TAR You were thinking that propagation might be at some other rate? the dominant error source in your measurement is probably the sound card's clock. For other fun measurements of em propagation speed.. melting the mode pattern of a microwave oven cooking chamber at 2450 MHz into a single layer of marshmallows on a plate (turning off the rotating turntable and mode-stirrer, of course). Chocolate morsels might also work. Other methods, for visible light, include the spinning toothed wheels of Fizeau and rotating multifacet prisms of Foucault (later updated by Michelson) Interference fringes from a laser, as well. if one is looking for more "radio" than "light".. look at the doppler effect from a moving source. The fractional change in frequency is equal to the velocity/propagation velocity. If you do something like measure the frequency from, oh, an orbiting satellite and get the whole "doppler curve" you can figure out the frequency of the oscillator (it's the frequency at which the second derivative of measured frequency goes through zero). You can measure the velocity of the satellite optically (if you pick a satellite which is visible, like ISS) |
Radio waves faster than light
"tom" napisal w wiadomosci . net... On 3/7/2011 11:27 AM, Szczepan Bialek wrote: Uzytkownik napisal w wiadomosci ... On Mar 7, 8:17 am, "Szczepan wrote: " Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From:http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 384 000/2.4 = 320 000 km/s. Should be 2x384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* i'm glad you checked their calculation and found that obvious error... i guess all the other radar calibrations in the world have to be changed to account for the bialek speed effect... i wonder if that would get you out of a radar gun speeding ticket? Did you communications via Moon? S* I have, at another amateur's station, on 432 MHz. Surprisingly the speed came out almost dead on 300m/microsecond. Used .wav file recording of transmit and echo and a good sound file editor with sub-millisecond resolution when zoomed. I have checked the Moon history and now I know that on Oct. 28 2007 was "full Moon" at perygeum. So the speed was close to 300m/microsecond. But I am steel loking for the evidences that the speed of radio waves is temperature and wave lenght dependant. S* |
Radio waves faster than light
"K1TTT" napisal w wiadomosci ... On Mar 7, 5:22 pm, "Szczepan Bialek" wrote: U ytkownik "-.-. --.-" napisa w wiadomo ... "Szczepan Bialek" ha scritto nel messaggio .. . 384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* No. Maybe I don't understand the complex calculation under your quoted division by 2.4, but.... You understand. Should be: 2x384 000 = 320 000. Your "mean distance" have to be doubled: received *back* in 2,4 sec mean that the signal traveled the double distance. At minimum distance the moon is 356375 km far from earth. 356375*2 is 712750 km, that at light speed means a travel time of 2,37 sec. The test was made at "full Moon". ""Even though lunar echoes have been detected before at higher frequencies, it was really exciting to see them arrive in real time out under the full moon in the New Mexico desert," I do not know the distance. But some radio amateur practice communication via Moon. Have they own observations? Any greatest distance agree with classical physics laws, and a normal mind don't care if the light travel faster, maybe care about the distance of the moon at the time of test: exactly 360000 km from the earth. Now are transmitters on the Mars. They are able to give the answer forMaxwell. He wrote: " " Incidentally, Maxwell once suggested that Roemer's method could be used to test for the isotropy of light speed, i.e., to test whether the speed of light is the same in all directions. Roemer's method can be regarded as a means of measuring the speed of light in the direction from Jupiter to the Earth. Jupiter has an orbital period of about 12 years, so if we use Roemer's method to evaluate the speed of light several times over a 12 year period, we will be evaluating the speed in all possible directions (in the plane of the ecliptic). " From:http://www.mathpages.com/home/kmath203/kmath203.htm As you see Maxwell care if the light travel everywhere with the same speed. The same is with the wave lenght. Longer water waves travel faster. Is it the same with radio waves? S* no No for your (Heavisde's) paper waves. My waves are Tesla's waves: http://www.tfcbooks.com/tesla/1929-09-22.htm Tesla say in 1929: " The effects, according to my view, were due to minute particles of matter carrying enormous electrical charges, which, for want of a better name, I designated as matter not further decomposable. Subsequently those particles were called electrons." The same wrote Faraday in 1846: http://www.padrak.com/ine/FARADAY1.html I assume that the two greatest man are right. Electrons are produced by the Sun (rare plasma +dust). They rotate with the Sun and their temperature is place dependent. Speed of the pressure waves must be also the place and frequency dependent. But you do not care about that . You are fine with the EM waves. Are you? S* |
Radio waves faster than light
Uzytkownik "John - KD5YI" napisal w wiadomosci ... On 3/7/2011 2:17 AM, Szczepan Bialek wrote: " Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From: http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 2x 384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? There is no space. It is packed with compressed aether. No aether as "a medium filling all space, called the ether, which was structureless, of inconceivable tenuity and yet solid and possessed of rigidity incomparably greater than that of the hardest steel" (Tesla). Space is filled with the ISM (rare plasma +dust). ISM is produced by stars and rotate with them. So radio waves are the electron waves. Acoustic waves are ions waves. S* |
Radio waves faster than light
Szczepan Bialek wrote:
"tom" napisal w wiadomosci . net... On 3/7/2011 11:27 AM, Szczepan Bialek wrote: Uzytkownik napisal w wiadomosci ... On Mar 7, 8:17 am, "Szczepan wrote: " Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From:http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 384 000/2.4 = 320 000 km/s. Should be 2x384 000/2.4 = 320 000 km/s. Speed of light is 300 000. But long waves travel quicker in glass. Would be the same in space? S* i'm glad you checked their calculation and found that obvious error... i guess all the other radar calibrations in the world have to be changed to account for the bialek speed effect... i wonder if that would get you out of a radar gun speeding ticket? Did you communications via Moon? S* I have, at another amateur's station, on 432 MHz. Surprisingly the speed came out almost dead on 300m/microsecond. Used .wav file recording of transmit and echo and a good sound file editor with sub-millisecond resolution when zoomed. I have checked the Moon history and now I know that on Oct. 28 2007 was "full Moon" at perygeum. So the speed was close to 300m/microsecond. But I am steel loking for the evidences that the speed of radio waves is temperature and wave lenght dependant. S* in vacuum, of course, there is no dependency on wavelength. in a dispersive medium, there is a dependency on wavelength. A good practical example of a dispersive medium for radio is the ionosphere. interplanetary space also is very slightly dispersive (due to the small, but non-zero, ion content) Inasmuch as temperature and ionization are related, I suppose there's a relation, but nothing like you see with sound, where there's a very strong relationship between propagation velocity and temperature (but that's because the mechanism of sound propagation is molecules/atoms colliding with each other) |
Radio waves faster than light
On 3/8/2011 2:25 AM, Szczepan Bialek wrote:
I have, at another amateur's station, on 432 MHz. Surprisingly the speed came out almost dead on 300m/microsecond. Used .wav file recording of transmit and echo and a good sound file editor with sub-millisecond resolution when zoomed. I have checked the Moon history and now I know that on Oct. 28 2007 was "full Moon" at perygeum. So the speed was close to 300m/microsecond. Well that's a nice bit of trivia you bring up, but that was not the correct date, and not even the correct decade. So why did you bring it up? But I am steel loking for the evidences that the speed of radio waves is temperature and wave lenght dependant. S* You won't see it except when it's not in vacuum and then it's very difficult for people like you to detect it. You actually have to do something. tom K0TAR |
Radio waves faster than light
"tom" napisal w wiadomosci et... On 3/8/2011 2:25 AM, Szczepan Bialek wrote: I have, at another amateur's station, on 432 MHz. Surprisingly the speed came out almost dead on 300m/microsecond. Used .wav file recording of transmit and echo and a good sound file editor with sub-millisecond resolution when zoomed. I have checked the Moon history and now I know that on Oct. 28 2007 was "full Moon" at perygeum. So the speed was close to 300m/microsecond. Well that's a nice bit of trivia you bring up, but that was not the correct date, and not even the correct decade. So why did you bring it up? On Oct. 28 2007 radio echo appeared after 2.4s. But I am steel loking for the evidences that the speed of radio waves is temperature and wave lenght dependant. S* You won't see it except when it's not in vacuum and then it's very difficult for people like you to detect it. You actually have to do something. Jim wrote: "interplanetary space also is very slightly dispersive (due to the small, but non-zero, ion content)" Are many people who detect physical phenomenon. I am looking for the description. S* |
Radio waves faster than light
"Jim Lux" napisal w wiadomosci ... Szczepan Bialek wrote: . But I am steel loking for the evidences that the speed of radio waves is temperature and wave lenght dependant. in vacuum, of course, there is no dependency on wavelength. in a dispersive medium, there is a dependency on wavelength. A good practical example of a dispersive medium for radio is the ionosphere. interplanetary space also is very slightly dispersive (due to the small, but non-zero, ion content) Inasmuch as temperature and ionization are related, I suppose there's a relation, but nothing like you see with sound, where there's a very strong relationship between propagation velocity and temperature (but that's because the mechanism of sound propagation is molecules/atoms colliding with each other) If Tesla is right than the radio waves propagation is electrons colliding with each other. Faraday was the same opinion: "I suppose we may compare together the matter of the aether and ordinary matter (as, for instance, the copper of the wire through which the electricity is conducted), and consider them as alike in their essential constitution; i.e. either as both composed of little nuclei, considered in the abstract as matter, and of force or power associated with these nuclei" Faraday known that the speed of waves is the same in copper and space. The media must be the same. Charged particles = electrons. Analogy sound - electric waves is full. S* |
Radio waves faster than light
On Mar 9, 3:42*am, "Szczepan Bialek" wrote:
Faraday known that the speed of waves is the same in copper and space. RF waves (fields/photons) cannot exist or flow IN copper. RF waves (fields/photons) flow in the space surrounding copper. The free electrons in a copper wire move only at a tiny fraction of the speed of light, 0.00028 m/s in the Wikipedia example. For RF signals, the electrons move hardly at all and can be considered to be vibrating in place acting as a sort of bucket brigade for the photons. http://en.wikipedia.org/wiki/Drift_velocity -- 73, Cecil, w5dxp.com |
Radio waves faster than light
"Cecil Moore" napisal w wiadomosci ... On Mar 9, 3:42 am, "Szczepan Bialek" wrote: Faraday known that the speed of waves is the same in copper and space. RF waves (fields/photons) cannot exist or flow IN copper. RF waves (fields/photons) flow in the space surrounding copper. The free electrons in a copper wire move only at a tiny fraction of the speed of light, 0.00028 m/s in the Wikipedia example. For RF signals, the electrons move hardly at all and can be considered to be vibrating in place acting as a sort of bucket brigade for the photons. All waves are the vibrations in place. Faraday wrote: " The velocity of light through space is about 190,000 miles in a second; the velocity of electricity is, by the experiments of Wheatstone, shown to be as great as this, if not greater: the light is supposed to be transmitted by vibrations through an aether which is, so to speak, destitute of gravitation, but infinite in elasticity; the electricity is transmitted through a small metallic wire, and is often viewed as transmitted by vibrations also." The electrons drift is like Stokes drift: http://en.wikipedia.org/wiki/Stokes_drift S* |
Radio waves faster than light
On 3/9/2011 3:24 AM, Szczepan Bialek wrote:
napisal w wiadomosci So why did you bring it up? On Oct. 28 2007 radio echo appeared after 2.4s. What echo? You shouted from a mountain? Be specific, use examples. But I am steel loking for the evidences that the speed of radio waves is temperature and wave lenght dependant. S* You won't see it except when it's not in vacuum and then it's very difficult for people like you to detect it. You actually have to do something. Jim wrote: "interplanetary space also is very slightly dispersive (due to the small, but non-zero, ion content)" Are many people who detect physical phenomenon. I am looking for the description. S* Those comments had no relation whatsoever to what I said. You are blathering again. As usual. tom K0TAR |
Radio waves faster than light
"tom" napisal w wiadomosci . net... On 3/9/2011 3:24 AM, Szczepan Bialek wrote: napisal w wiadomosci So why did you bring it up? On Oct. 28 2007 radio echo appeared after 2.4s. What echo? You shouted from a mountain? Be specific, use examples. My first post: "" Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From: http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 2x384 000/2.4 = 320 000 km/s." At that time the Moon was at perygeum so the speed was 300 000. But I am steel loking for the evidences that the speed of radio waves is temperature and wave lenght dependant. S* You won't see it except when it's not in vacuum and then it's very difficult for people like you to detect it. You actually have to do something. Jim wrote: "interplanetary space also is very slightly dispersive (due to the small, but non-zero, ion content)" Are many people who detect physical phenomenon. I am looking for the description. S* Those comments had no relation whatsoever to what I said. You are blathering again. As usual. Speed of light in air, glass, water is temperature (mirage) and wavelenght.dependent. In space should be the same, but for Tesla's waves. S* |
Radio waves faster than light
On 3/10/2011 2:05 AM, Szczepan Bialek wrote:
napisal w wiadomosci What echo? You shouted from a mountain? Be specific, use examples. My first post: "" Using such a pulse pattern makes the echo, which arrives back from the moon 2.4 seconds later". From: http://www.rense.com/general79/haarp.htm "During the experiment, which was carried out on Oct. 28 and 29, 2007, the radar signals from HAARP were at 7.4075 MHz and 9.4075 MHz" I do not know the distance to Moon on that days but for the mean distance 384 000 km the speed is: 2x384 000/2.4 = 320 000 km/s." I recorded the audio from the 2008/01/19 test. Did you? What measurements did you get from it? I am very interested. I have reportable results. It was a perigee plus or minus your location. And I have a correction factor for the delay from the HAARP site to my location in Minnesota. Do you know your location? What do you have for results? tom K0TAR |
Radio waves faster than light
"tom" napisal w wiadomosci et... On 3/10/2011 2:05 AM, Szczepan Bialek wrote: I recorded the audio from the 2008/01/19 test. Did you? What measurements did you get from it? I am very interested. The "full Moon" was on 2008/01/22. The distance was about 365 000 km. I have reportable results. It was a perigee plus or minus your location. And I have a correction factor for the delay from the HAARP site to my location in Minnesota. Do you know your location? What do you have for results? I am a reader only. S* |
Radio waves faster than light
Szczepan Bialek wrote:
"tom" napisal w wiadomosci et... On 3/10/2011 2:05 AM, Szczepan Bialek wrote: I recorded the audio from the 2008/01/19 test. Did you? What measurements did you get from it? I am very interested. The "full Moon" was on 2008/01/22. The distance was about 365 000 km. The Moon being full has nothing to do with it's distance from Earth or it's radio reflectivity. You are a babbling idiot. I have reportable results. It was a perigee plus or minus your location. And I have a correction factor for the delay from the HAARP site to my location in Minnesota. Do you know your location? What do you have for results? I am a reader only. And a very poor one at that. -- Jim Pennino Remove .spam.sux to reply. |
Radio waves faster than light
On 3/11/2011 3:29 AM, Szczepan Bialek wrote:
The "full Moon" was on 2008/01/22. The distance was about 365 000 km. Which is irrelevant being 3 days later than the HAARP test. What do you have for results? I am a reader only. How unsurprising. You DO nothing. Except repeat theories which were proven incorrect over 100 years ago. S* tom K0TAR |
Radio waves faster than light
On 3/11/2011 3:29 AM, Szczepan Bialek wrote:
The "full Moon" was on 2008/01/22. The distance was about 365 000 km. Quite incorrect, since perigee was 366435 km on the 19th. Your number is way too low for what it would have been on the 22nd. Do you ever check anything for correctness? tom K0TAR |
Radio waves faster than light
Uzytkownik "tom" napisal w wiadomosci et... On 3/11/2011 3:29 AM, Szczepan Bialek wrote: The "full Moon" was on 2008/01/22. The distance was about 365 000 km. Which is irrelevant being 3 days later than the HAARP test. What do you have for results? I am a reader only. How unsurprising. You DO nothing. Except repeat theories which were proven incorrect over 100 years ago. Longer waves travel faster in air and glass. The same is in real space. But I do not know how much. So I am asking. S* |
Radio waves faster than light
Uzytkownik "tom" napisal w wiadomosci et... On 3/11/2011 3:29 AM, Szczepan Bialek wrote: The "full Moon" was on 2008/01/22. The distance was about 365 000 km. Quite incorrect, since perigee was 366435 km on the 19th. Your number is way too low for what it would have been on the 22nd. Do you ever check anything for correctness? I am asking if radio waves are faster than light. Now is possibility to measure the both between the Earth and Moon and speed of radio waves between Mars and Earth.. For centuries is possibility to measure speed of light in space between Jovian and Earth. Probably the Moon is to close to the Earth to pick up the difference. Is it enough at full correctness? S* |
Radio waves faster than light
On 3/12/2011 2:26 AM, Szczepan Bialek wrote:
Uzytkownik napisal w wiadomosci et... On 3/11/2011 3:29 AM, Szczepan Bialek wrote: The "full Moon" was on 2008/01/22. The distance was about 365 000 km. Which is irrelevant being 3 days later than the HAARP test. What do you have for results? I am a reader only. How unsurprising. You DO nothing. Except repeat theories which were proven incorrect over 100 years ago. Longer waves travel faster in air and glass. The same is in real space. But I do not know how much. So I am asking. S* You are incorrect. But explaining it would do no good, as you have proven that you do not listen and can not learn. tom K0TAR |
Radio waves faster than light
On 3/12/2011 2:40 AM, Szczepan Bialek wrote:
Uzytkownik napisal w wiadomosci et... On 3/11/2011 3:29 AM, Szczepan Bialek wrote: The "full Moon" was on 2008/01/22. The distance was about 365 000 km. Quite incorrect, since perigee was 366435 km on the 19th. Your number is way too low for what it would have been on the 22nd. Do you ever check anything for correctness? I am asking if radio waves are faster than light. Radio waves and light are the same thing except we call them something different due to wavelength. Now is possibility to measure the both between the Earth and Moon and speed of radio waves between Mars and Earth.. For centuries is possibility to measure speed of light in space between Jovian and Earth. Probably the Moon is to close to the Earth to pick up the difference. Is it enough at full correctness? S* Tests of earth to moon to earth, earth to venus to earth all give the same speed of light regardless of frequency used. tom K0TAR |
Radio waves faster than light
"tom" napisal w wiadomosci et... On 3/12/2011 2:40 AM, Szczepan Bialek wrote: I am asking if radio waves are faster than light. Radio waves and light are the same thing except we call them something different due to wavelength. Now is possibility to measure the both between the Earth and Moon and speed of radio waves between Mars and Earth.. For centuries is possibility to measure speed of light in space between Jovian and Earth. Probably the Moon is to close to the Earth to pick up the difference. Is it enough at full correctness? Tests of earth to moon to earth, earth to venus to earth all give the same speed of light regardless of frequency used. It is an obiect of interesting for ages. The first was observing of color changes of Io (Jovian's satellite). But the difference in light frequences are small. But light and radio waves have extremally different frequences. You wrote: "Tests of earth to moon to earth, earth to venus to earth all give the same speed of light regardless of frequency used." Write "if radio waves are faster than light". Speed of light in space is known thanks Roemer.s method. Now are radio transmitters on the Mars and is possibility to use the Roemer's method for radio waves. NASA know the results. Are thy pulished? S* |
Radio waves faster than light
Szczepan Bialek wrote:
"tom" napisal w wiadomosci et... On 3/12/2011 2:40 AM, Szczepan Bialek wrote: I am asking if radio waves are faster than light. Radio waves and light are the same thing except we call them something different due to wavelength. Now is possibility to measure the both between the Earth and Moon and speed of radio waves between Mars and Earth.. For centuries is possibility to measure speed of light in space between Jovian and Earth. Probably the Moon is to close to the Earth to pick up the difference. Is it enough at full correctness? Tests of earth to moon to earth, earth to venus to earth all give the same speed of light regardless of frequency used. It is an obiect of interesting for ages. The first was observing of color changes of Io (Jovian's satellite). But the difference in light frequences are small. But light and radio waves have extremally different frequences. You wrote: "Tests of earth to moon to earth, earth to venus to earth all give the same speed of light regardless of frequency used." Write "if radio waves are faster than light". Speed of light in space is known thanks Roemer.s method. Now are radio transmitters on the Mars and is possibility to use the Roemer's method for radio waves. NASA know the results. Are thy pulished? S* The speed of light and the speed of radio waves are identical, you babbling idiot. Light and radio waves are the same thing at different frequencies, you droooing cretin. If you had ever read anything written less than 100 years ago, you would know all this was proved long ago, you gibbering moron. -- Jim Pennino Remove .spam.sux to reply. |
Radio waves faster than light
napisał w wiadomości ... Szczepan Bialek wrote: Speed of light in space is known thanks Roemer.s method. Now are radio transmitters on the Mars and is possibility to use the Roemer's method for radio waves. NASA know the results. Are they published? S* The speed of light and the speed of radio waves are identical, you babbling idiot. Light and radio waves are the same thing at different frequencies, you droooing cretin. If you had ever read anything written less than 100 years ago, you would know all this was proved long ago, you gibbering moron. In todays textbooks is wrote that speed of light is frequency dependent (glass prism). The same is in air (atmosphere). Why the heliosphere is different? S* |
Radio waves faster than light
Szczepan Bialek wrote:
napisa? w wiadomo?ci ... Szczepan Bialek wrote: Speed of light in space is known thanks Roemer.s method. Now are radio transmitters on the Mars and is possibility to use the Roemer's method for radio waves. NASA know the results. Are they published? S* The speed of light and the speed of radio waves are identical, you babbling idiot. Light and radio waves are the same thing at different frequencies, you droooing cretin. If you had ever read anything written less than 100 years ago, you would know all this was proved long ago, you gibbering moron. In todays textbooks is wrote that speed of light is frequency dependent (glass prism). You can't read, you babbling moron, that is NOT what today's textbooks say. The speed of light is not frequency dependent, it is medium dependent, that is it is dependent on the refractive index of the medium. The refractive index of a medium is frequency dependent. You haven't a clue which is the cause and which is the effect. The same is in air (atmosphere). Why the heliosphere is different? S* Yet more meaningless, babbling, nonsense with no connection to reality. -- Jim Pennino Remove .spam.sux to reply. |
Radio waves faster than light
On Mar 14, 3:02*am, "Szczepan Bialek" wrote:
In todays textbooks is wrote that speed of light is frequency dependent (glass prism). The same is in air (atmosphere). Why the heliosphere is different? The difference of which you speak is very small. The atmosphere is about 0.27 % of the total distance between the earth and the moon. 0.27% of "very small" would be very, very small. -- 73, Cecil, w5dxp.com |
Radio waves faster than light
"Cecil Moore" napisal w wiadomosci ... On Mar 14, 3:02 am, "Szczepan Bialek" wrote: In todays textbooks is wrote that speed of light is frequency dependent (glass prism). The same is in air (atmosphere). Why the heliosphere is different? The difference of which you speak is very small. The atmosphere is about 0.27 % of the total distance between the earth and the moon. 0.27% of "very small" would be very, very small. But heliosphere reach the last planet (at least). S* |
Radio waves faster than light
Szczepan Bialek wrote:
"Cecil Moore" napisal w wiadomosci ... On Mar 14, 3:02 am, "Szczepan Bialek" wrote: In todays textbooks is wrote that speed of light is frequency dependent (glass prism). The same is in air (atmosphere). Why the heliosphere is different? The difference of which you speak is very small. The atmosphere is about 0.27 % of the total distance between the earth and the moon. 0.27% of "very small" would be very, very small. But heliosphere reach the last planet (at least). S* Yeah, and what is the density, refractive index, permeability, and permittivity of the helioshpere, you babbling moron? -- Jim Pennino Remove .spam.sux to reply. |
Radio waves faster than light
tom wrote:
On 3/12/2011 2:40 AM, Szczepan Bialek wrote: Uzytkownik napisal w wiadomosci et... On 3/11/2011 3:29 AM, Szczepan Bialek wrote: The "full Moon" was on 2008/01/22. The distance was about 365 000 km. Quite incorrect, since perigee was 366435 km on the 19th. Your number is way too low for what it would have been on the 22nd. Do you ever check anything for correctness? I am asking if radio waves are faster than light. Radio waves and light are the same thing except we call them something different due to wavelength. Now is possibility to measure the both between the Earth and Moon and speed of radio waves between Mars and Earth.. For centuries is possibility to measure speed of light in space between Jovian and Earth. Probably the Moon is to close to the Earth to pick up the difference. Is it enough at full correctness? S* Tests of earth to moon to earth, earth to venus to earth all give the same speed of light regardless of frequency used. Not precisely true. Interplanetary space slightly dispersive. Emphasis on *slightly*. Kenelm Philip predicted a difference back in 1957 Modern estimates for electron density in interplanetary space of 1E6 to 1E10 per cubic meter. dTau = e^2*Ne*L/(2*pi*m*c) * (1/f1^2 - 1/f2^2) e= charge on an electron 1E-18 Coulomb m = mass of an electron at rest (9.11E-31 kg) c = velocity of light (3E8 m/s) L = propagation distance Ne = electron density (pick a number between 1E6 and 1E10) f1 and f2 are the frequencies (in Hz) (assumed relatively closely spaced) To bound the magnitudes.. for 1000 light year and 1 and 2 GHz, the dispersion is about 1 nanosecond. -- if you're interested in optical as opposed to RF http://ipnpr.jpl.nasa.gov/progress_report/42-65/65I.PDF |
Radio waves faster than light
Speed of light in space is known thanks Roemer.s method. Now are radio
transmitters on the Mars and is possibility to use the Roemer's method for radio waves. NASA know the results. Are thy pulished? Of course, they're published. Widely. I would check Journal of Geophysical Research or similar publications. As a practical matter, precise measurements of the time of flight to/from a spacecraft is used to figure out where the spacecraft is and its radial velocity. Typical range accuracy is on the order of a few meters, velocities good to a few cm/s, for something at the orbit of Neptune or Uranus. Precise doppler measurements are used for radio science experiments, e.g. to determine the internal structure of a planet or moon by precisely measuring the orbit of a satellite. A typical performance for such a measurement is 1 part in 1E15 over 1000 seconds at 32 GHz or 8GHz. |
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