Μετάφραση και ανάλυση λέξεων από την τεχνητή νοημοσύνη ChatGPT
Σε αυτήν τη σελίδα μπορείτε να λάβετε μια λεπτομερή ανάλυση μιας λέξης ή μιας φράσης, η οποία δημιουργήθηκε χρησιμοποιώντας το ChatGPT, την καλύτερη τεχνολογία τεχνητής νοημοσύνης μέχρι σήμερα:
- πώς χρησιμοποιείται η λέξη
- συχνότητα χρήσης
- χρησιμοποιείται πιο συχνά στον προφορικό ή γραπτό λόγο
- επιλογές μετάφρασης λέξεων
- παραδείγματα χρήσης (πολλές φράσεις με μετάφραση)
- ετυμολογία
radio-astronomy - translation to Αγγλικά
![opacity]]) of various [[wavelength]]s of electromagnetic radiation.](https://commons.wikimedia.org/wiki/Special:FilePath/Atmospheric electromagnetic opacity.svg?width=200 "opacity]]) of various [[wavelength]]s of electromagnetic radiation.")
![Chart on which [[Jocelyn Bell Burnell]] first recognised evidence of a [[pulsar]], in 1967 (exhibited at [[Cambridge University Library]])](https://commons.wikimedia.org/wiki/Special:FilePath/Chart Showing Radio Signal of First Identified Pulsar.jpg?width=200 "Chart on which [[Jocelyn Bell Burnell]] first recognised evidence of a [[pulsar]], in 1967 (exhibited at [[Cambridge University Library]])")
![A radio image of the central region of the Milky Way galaxy. The arrow indicates a supernova remnant which is the location of a newly discovered transient, bursting low-frequency radio source [[GCRT J1745-3009]].](https://commons.wikimedia.org/wiki/Special:FilePath/GCRT J1745-3009 2.jpg?width=200 "A radio image of the central region of the Milky Way galaxy. The arrow indicates a supernova remnant which is the location of a newly discovered transient, bursting low-frequency radio source [[GCRT J1745-3009]].")
![Antenna 70 m of the [[Goldstone Deep Space Communications Complex]], [[California]]](https://commons.wikimedia.org/wiki/Special:FilePath/Goldstone DSN antenna.jpg?width=200 "Antenna 70 m of the [[Goldstone Deep Space Communications Complex]], [[California]]")
![Green Bank radio telescope]], USA](https://commons.wikimedia.org/wiki/Special:FilePath/Green Bank Telescope.jpg?width=200 "Green Bank radio telescope]], USA")
![[[Grote Reber]]'s Antenna at [[Wheaton, Illinois]], world's first parabolic radio telescope](https://commons.wikimedia.org/wiki/Special:FilePath/Grote Antenna Wheaton.gif?width=200 "[[Grote Reber]]'s Antenna at [[Wheaton, Illinois]], world's first parabolic radio telescope")
![HST]]), a radio image of same galaxy using '''Interferometry''' ([[Very Large Array]] – '''VLA'''), and an image of the center section ('''VLBA''') using a ''Very Long Baseline Array'' (Global VLBI) consisting of antennas in the US, Germany, Italy, Finland, Sweden and Spain. The jet of particles is suspected to be powered by a [[black hole]] in the center of the galaxy.](https://commons.wikimedia.org/wiki/Special:FilePath/M87 VLA VLBA radio astronomy.jpg?width=200 "HST]]), a radio image of same galaxy using '''Interferometry''' ([[Very Large Array]] – '''VLA'''), and an image of the center section ('''VLBA''') using a ''Very Long Baseline Array'' (Global VLBI) consisting of antennas in the US, Germany, Italy, Finland, Sweden and Spain. The jet of particles is suspected to be powered by a [[black hole]] in the center of the galaxy.")
![The [[Atacama Large Millimeter Array]] (ALMA), many antennas linked together in a radio interferometer](https://commons.wikimedia.org/wiki/Special:FilePath/The Atacama Compact Array.jpg?width=200 "The [[Atacama Large Millimeter Array]] (ALMA), many antennas linked together in a radio interferometer")
![[[Frequency]] spectrum of a typical modulated AM or FM radio signal. It consists of a component ''C'' at the [[carrier wave]] frequency <math>f_c</math> with the information ([[modulation]]) contained in two narrow bands of frequencies called [[sideband]]s (''SB'') just above and below the carrier frequency.](https://commons.wikimedia.org/wiki/Special:FilePath/Modulated radio signal frequency spectrum.svg?width=200 "[[Frequency]] spectrum of a typical modulated AM or FM radio signal. It consists of a component ''C'' at the [[carrier wave]] frequency <math>f_c</math> with the information ([[modulation]]) contained in two narrow bands of frequencies called [[sideband]]s (''SB'') just above and below the carrier frequency.")
![Radio communication. Information such as sound is converted by a transducer such as a [[microphone]] to an electrical signal, which modulates a [[radio wave]] produced by the [[transmitter]]. A receiver intercepts the radio wave and extracts the information-bearing modulation signal, which is converted back to a human usable form with another transducer such as a [[loudspeaker]].](https://commons.wikimedia.org/wiki/Special:FilePath/Signal processing system.png?width=200 "Radio communication. Information such as sound is converted by a transducer such as a [[microphone]] to an electrical signal, which modulates a [[radio wave]] produced by the [[transmitter]]. A receiver intercepts the radio wave and extracts the information-bearing modulation signal, which is converted back to a human usable form with another transducer such as a [[loudspeaker]].")
![Volkswagen's RNS-510 receiver supports [[Sirius Satellite Radio]].](https://commons.wikimedia.org/wiki/Special:FilePath/SiriusXM Display on Volkswagen's RNS-510 Receiver.png?width=200 "Volkswagen's RNS-510 receiver supports [[Sirius Satellite Radio]].")
![shows its own photo]]](https://commons.wikimedia.org/wiki/Special:FilePath/Wireless network.jpg?width=200 "shows its own photo]]")
Ορισμός
Βικιπαίδεια
Radio astronomy is a subfield of astronomy that studies celestial objects at radio frequencies. The first detection of radio waves from an astronomical object was in 1933, when Karl Jansky at Bell Telephone Laboratories reported radiation coming from the Milky Way. Subsequent observations have identified a number of different sources of radio emission. These include stars and galaxies, as well as entirely new classes of objects, such as radio galaxies, quasars, pulsars, and masers. The discovery of the cosmic microwave background radiation, regarded as evidence for the Big Bang theory, was made through radio astronomy.
Radio astronomy is conducted using large radio antennas referred to as radio telescopes, that are either used singularly, or with multiple linked telescopes utilizing the techniques of radio interferometry and aperture synthesis. The use of interferometry allows radio astronomy to achieve high angular resolution, as the resolving power of an interferometer is set by the distance between its components, rather than the size of its components.
Radio astronomy differs from radar astronomy in that the former is a passive observation (i.e., receiving only) and the latter an active one (transmitting and receiving).
