Difference between revisions of "Terahertz Electronics"

From KAIST Quantum Computing Lab Wiki
Jump to navigationJump to search
 
(One intermediate revision by the same user not shown)
Line 1: Line 1:
<big>'''THz imaging'''</big>
+
[[Image:THzCDMAimaging.jpg|center|500px]]
[[Image:THzCDMAimaging.jpg|left|500px]]
 
<br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br>
 
  
 
<big>'''THz coherent optical computer'''</big><br>
 
<big>'''THz coherent optical computer'''</big><br>
 
[[Image:THzCOC.jpg|left|300px]]
 
[[Image:THzCOC.jpg|left|300px]]
 
Single point terahertz imagery of 2D objects is demonstrated by exploiting the broadband nature of ultrafast terahertz wave in a coherent optical computing setup. In the devised imagery, a collimated terahertz beam is illuminated on an object and the scattered fields are measured through a spatial mask at the Fourier plane in a 4-f terahertz time-domain spectroscope. This arrangement allows conversion of radial spatial frequencies of the object to the temporal spectrum of the pulse. Hence, a 2D image stored in the terahertz waveforms can be readily obtained.
 
Single point terahertz imagery of 2D objects is demonstrated by exploiting the broadband nature of ultrafast terahertz wave in a coherent optical computing setup. In the devised imagery, a collimated terahertz beam is illuminated on an object and the scattered fields are measured through a spatial mask at the Fourier plane in a 4-f terahertz time-domain spectroscope. This arrangement allows conversion of radial spatial frequencies of the object to the temporal spectrum of the pulse. Hence, a 2D image stored in the terahertz waveforms can be readily obtained.

Latest revision as of 08:48, 11 September 2009

THzCDMAimaging.jpg

THz coherent optical computer

THzCOC.jpg

Single point terahertz imagery of 2D objects is demonstrated by exploiting the broadband nature of ultrafast terahertz wave in a coherent optical computing setup. In the devised imagery, a collimated terahertz beam is illuminated on an object and the scattered fields are measured through a spatial mask at the Fourier plane in a 4-f terahertz time-domain spectroscope. This arrangement allows conversion of radial spatial frequencies of the object to the temporal spectrum of the pulse. Hence, a 2D image stored in the terahertz waveforms can be readily obtained.