Thank you for the video, a very fundamental operating principle is explained in understandable manner. I have a unclear detail. The waveform rate can be several thousands on even million wfps but the typical display update rate is 50/60 Hz. How are these multiple waveforms displayed on a such low display update rate and how are combinded into a single picture?
Interesting... Curious re "all scopes have this"... I'd think they duplicate the processing to eliminate the blind spots on better scopes. Seems unnecessary to have blind spots on expensive scopes if it's necessary to catch infrequent events to the extent that they run them for hours or days for this purpose. Just take a page from graphics processing pipelines and have blind-spot-length-divided-by-acquisition-window-size number of processing units to catch everything in parallel, no?
Our newest oscilloscope, the MXO4, is able to acquire ~4.5 million waveforms / sec with almost no blind time - a first in the industry. We spent several years developing a custom ASIC in order to make this possible. And you're absolutely right that parallel processing is needed to overcome this limitation - our new ASIC does in fact use massive parallel processing :)
Lovely presentation,🌹🌹🌹🌹🌹🌹
Thank you!
Thank you for the video, a very fundamental operating principle is explained in understandable manner. I have a unclear detail. The waveform rate can be several thousands on even million wfps but the typical display update rate is 50/60 Hz. How are these multiple waveforms displayed on a such low display update rate and how are combinded into a single picture?
Interesting... Curious re "all scopes have this"... I'd think they duplicate the processing to eliminate the blind spots on better scopes. Seems unnecessary to have blind spots on expensive scopes if it's necessary to catch infrequent events to the extent that they run them for hours or days for this purpose. Just take a page from graphics processing pipelines and have blind-spot-length-divided-by-acquisition-window-size number of processing units to catch everything in parallel, no?
Our newest oscilloscope, the MXO4, is able to acquire ~4.5 million waveforms / sec with almost no blind time - a first in the industry. We spent several years developing a custom ASIC in order to make this possible. And you're absolutely right that parallel processing is needed to overcome this limitation - our new ASIC does in fact use massive parallel processing :)
@@pauldenisowski Well then congrats to the dev team :D also these videos are all excellent! Thank you!
@@enotdetcelfer Thanks!