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Probes
I need to buy a probe for my oscilloscope which is 60 MHZ.
My question is can I buy a probe that rated 100 MHZ or must I make sure it is rated 60 MHZ the same as my system? Thanks |
Probes
On May 30, 3:12�pm, Plasmah77
wrote: I need to buy a probe for my oscilloscope which is 60 MHZ. My question is can I buy a probe that rated 100 MHZ or must I make sure it is rated 60 MHZ the same as my system? Thanks -- Plasmah77 The 100 MHZ probe will work fine. The 60 MHZ specification on your scope means its vertical amplifier and display will start to degrade at 60 MHZ or higher in frequency. Therefore using a probe with a 60 MHZ rating will allow you to realize all of your scope's capabilities. Gary N4AST |
Thank you very much Gary.
I just won a set of 100 MHZ probes with kit on ebay. I'm building 15 HZ zapper circuits and I need the scope to make sure my signal is as close to 15 HZ as possible. I almost bought one of those DSO nano's but someone told me they are **** ;). They told me I was better off spending money on an analog unit rather then waste cash on the Nano. Me being new to all this it took me a bit to learn how to read an analog scope but I'm picking it all up pretty good. Thanks again and have a great day. Jim Quote:
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Probes
"Plasmah77" wrote in message ... I need to buy a probe for my oscilloscope which is 60 MHZ. My question is can I buy a probe that rated 100 MHZ or must I make sure it is rated 60 MHZ the same as my system? Thanks -- Plasmah77 You can buy a probe with a higher frequency rating than your scope has and it will work fine, it just will be more expensive. Regards, Bob |
Probes
Gary wrote:
On May 30, 3:12�pm, Plasmah77 wrote: The 60 MHZ specification on your scope means its vertical amplifier and display will start to degrade at 60 MHZ or higher in frequency. No. It is 3dB Bandwidth. Degrade will start earlier. You will have lost half power or in voltage around 30% of the signal. Therefore using a probe with a 60 MHZ rating will allow you to realize all of your scope's capabilities. There is also a capacitance specification that should match. It is however unlikely that it should not. Go ahead with the 100MHz probes if you get them at a fair price. |
Probes
nobody wrote:
Gary wrote: On May 30, 3:12?pm, Plasmah77 wrote: The 60 MHZ specification on your scope means its vertical amplifier and display will start to degrade at 60 MHZ or higher in frequency. No. It is 3dB Bandwidth. Degrade will start earlier. You will have lost half power or in voltage around 30% of the signal. Therefore using a probe with a 60 MHZ rating will allow you to realize all of your scope's capabilities. There is also a capacitance specification that should match. It is however unlikely that it should not. Go ahead with the 100MHz probes if you get them at a fair price. Here are some guidelines to determine more exactly what the interaction between the scope and probe is: Bandwidth is BW Risetime is Tr BW = 0.35/Tr Tr(overall) = Sqrt(Tr(scope)^2 + Tr(probe)^2) Then if Scope Tr at 60 MHz = 5.9nS Probe Tr at 100 MHz = 3.5 nS Overall Tr = 6.80 nS, making overall -3db bandwidth = 51.4 MHz -- David dgminala at mediacombb dot net |
Probes
Dave M wrote:
nobody wrote: Gary wrote: On May 30, 3:12?pm, Plasmah77 wrote: The 60 MHZ specification on your scope means its vertical amplifier and display will start to degrade at 60 MHZ or higher in frequency. No. It is 3dB Bandwidth. Degrade will start earlier. You will have lost half power or in voltage around 30% of the signal. Therefore using a probe with a 60 MHZ rating will allow you to realize all of your scope's capabilities. There is also a capacitance specification that should match. It is however unlikely that it should not. Go ahead with the 100MHz probes if you get them at a fair price. Here are some guidelines to determine more exactly what the interaction between the scope and probe is: Bandwidth is BW Risetime is Tr BW = 0.35/Tr Tr(overall) = Sqrt(Tr(scope)^2 + Tr(probe)^2) Then if Scope Tr at 60 MHz = 5.9nS Probe Tr at 100 MHz = 3.5 nS Overall Tr = 6.80 nS, making overall -3db bandwidth = 51.4 MHz Though this sounds plausible, and it's thought through, I think the result is mistaken. A 60MHz scope is not a 60 MHz scope only if used with (say) 3 GHz probes; its a 60 MHz scope if used with the probes as provided or specified by the maker. Brian W |
Probes
brian whatcott wrote:
Dave M wrote: nobody wrote: Gary wrote: On May 30, 3:12?pm, Plasmah77 wrote: The 60 MHZ specification on your scope means its vertical amplifier and display will start to degrade at 60 MHZ or higher in frequency. No. It is 3dB Bandwidth. Degrade will start earlier. You will have lost half power or in voltage around 30% of the signal. Therefore using a probe with a 60 MHZ rating will allow you to realize all of your scope's capabilities. There is also a capacitance specification that should match. It is however unlikely that it should not. Go ahead with the 100MHz probes if you get them at a fair price. Here are some guidelines to determine more exactly what the interaction between the scope and probe is: Bandwidth is BW Risetime is Tr BW = 0.35/Tr Tr(overall) = Sqrt(Tr(scope)^2 + Tr(probe)^2) Then if Scope Tr at 60 MHz = 5.9nS Probe Tr at 100 MHz = 3.5 nS Overall Tr = 6.80 nS, making overall -3db bandwidth = 51.4 MHz Though this sounds plausible, and it's thought through, I think the result is mistaken. A 60MHz scope is not a 60 MHz scope only if used with (say) 3 GHz probes; its a 60 MHz scope if used with the probes as provided or specified by the maker. Brian W It's not mistaken... in fact, it's well documented. Here are some attributions that elaborate on the effects of a probe on the overall bandwidth of a scope/probe combination. http://books.google.com/books?id=xHA...0probe&f=false http://www.adler-instrumentos.es/ima...%C3%B1al.pd f pg 3 http://www.freelists.org/post/si-lis...nt-equipment,9 http://www.analog.com/library/analog...cd/vol41n1.pdf pg 13 As you can see from the documents, the scope and probe bandwidths do interact as the RMS sum of the two. The vertical bandwidth or risetime of scopes is specified at the scope's input connector. If the bandwidth specification includes the probe, it will be specified as such. In those cases, the scope's bandwidth will be specified separately, and will be higher than the scope/probe combination. Vertical bandwidth on many high quality scopes will be described in their manuals or spec sheets when using a variety of probes, and will reflect the equivalent bandwidth accordingly. -- David dgminala at mediacombb dot net |
Probes
I agree with the equation for summing bandwidth determining components,
and I agree with many of your other comments. But concluding that a 60 MHz scope with 100MHz probes provides a 51 MHz bandwidth combination is (in my view) mistaken. This is not the Tektronix way. And the Tektronix way is the ONLY way with scopes! :-) Brian W Dave M wrote: brian whatcott wrote: Dave M wrote: nobody wrote: Gary wrote: On May 30, 3:12?pm, Plasmah77 wrote: The 60 MHZ specification on your scope means its vertical amplifier and display will start to degrade at 60 MHZ or higher in frequency. No. It is 3dB Bandwidth. Degrade will start earlier. You will have lost half power or in voltage around 30% of the signal. Therefore using a probe with a 60 MHZ rating will allow you to realize all of your scope's capabilities. There is also a capacitance specification that should match. It is however unlikely that it should not. Go ahead with the 100MHz probes if you get them at a fair price. Here are some guidelines to determine more exactly what the interaction between the scope and probe is: Bandwidth is BW Risetime is Tr BW = 0.35/Tr Tr(overall) = Sqrt(Tr(scope)^2 + Tr(probe)^2) Then if Scope Tr at 60 MHz = 5.9nS Probe Tr at 100 MHz = 3.5 nS Overall Tr = 6.80 nS, making overall -3db bandwidth = 51.4 MHz Though this sounds plausible, and it's thought through, I think the result is mistaken. A 60MHz scope is not a 60 MHz scope only if used with (say) 3 GHz probes; its a 60 MHz scope if used with the probes as provided or specified by the maker. Brian W It's not mistaken... in fact, it's well documented. Here are some attributions that elaborate on the effects of a probe on the overall bandwidth of a scope/probe combination. http://books.google.com/books?id=xHA...0probe&f=false http://www.adler-instrumentos.es/ima...%C3%B1al.pd f pg 3 http://www.freelists.org/post/si-lis...nt-equipment,9 http://www.analog.com/library/analog...cd/vol41n1.pdf pg 13 As you can see from the documents, the scope and probe bandwidths do interact as the RMS sum of the two. The vertical bandwidth or risetime of scopes is specified at the scope's input connector. If the bandwidth specification includes the probe, it will be specified as such. In those cases, the scope's bandwidth will be specified separately, and will be higher than the scope/probe combination. Vertical bandwidth on many high quality scopes will be described in their manuals or spec sheets when using a variety of probes, and will reflect the equivalent bandwidth accordingly. |
Probes
[Re 60 MHz scope]
No. It is 3dB Bandwidth. Degrade will start earlier. You will have lost half power or in voltage around 30% of the signal. The idea that a 55 MHz sine wave of 5 volt P-P amplitude would only register about 3.6 volts on a 60 MHz scope is an alien idea to me. That would render such a scope all but useless.... I think it is possibly a European style definition of the scope bandwidth as a 3 Db down bandwidth that's causing this debate. I suggest that in American usage, I would be more likely to expect a 60 MHz sine wave to be not more than 5% down as indicated on a 60 MHz scope with its maker's standard probes. Brian W |
Probes
brian whatcott wrote:
I agree with the equation for summing bandwidth determining components, and I agree with many of your other comments. But concluding that a 60 MHz scope with 100MHz probes provides a 51 MHz bandwidth combination is (in my view) mistaken. This is not the Tektronix way. And the Tektronix way is the ONLY way with scopes! :-) Brian W Dave M wrote: brian whatcott wrote: Dave M wrote: nobody wrote: Gary wrote: On May 30, 3:12?pm, Plasmah77 wrote: The 60 MHZ specification on your scope means its vertical amplifier and display will start to degrade at 60 MHZ or higher in frequency. No. It is 3dB Bandwidth. Degrade will start earlier. You will have lost half power or in voltage around 30% of the signal. Therefore using a probe with a 60 MHZ rating will allow you to realize all of your scope's capabilities. There is also a capacitance specification that should match. It is however unlikely that it should not. Go ahead with the 100MHz probes if you get them at a fair price. Here are some guidelines to determine more exactly what the interaction between the scope and probe is: Bandwidth is BW Risetime is Tr BW = 0.35/Tr Tr(overall) = Sqrt(Tr(scope)^2 + Tr(probe)^2) Then if Scope Tr at 60 MHz = 5.9nS Probe Tr at 100 MHz = 3.5 nS Overall Tr = 6.80 nS, making overall -3db bandwidth = 51.4 MHz Though this sounds plausible, and it's thought through, I think the result is mistaken. A 60MHz scope is not a 60 MHz scope only if used with (say) 3 GHz probes; its a 60 MHz scope if used with the probes as provided or specified by the maker. Brian W It's not mistaken... in fact, it's well documented. Here are some attributions that elaborate on the effects of a probe on the overall bandwidth of a scope/probe combination. http://books.google.com/books?id=xHA...0probe&f=false http://www.adler-instrumentos.es/ima...%C3%B1al.pd f pg 3 http://www.freelists.org/post/si-lis...nt-equipment,9 http://www.analog.com/library/analog...cd/vol41n1.pdf pg 13 As you can see from the documents, the scope and probe bandwidths do interact as the RMS sum of the two. The vertical bandwidth or risetime of scopes is specified at the scope's input connector. If the bandwidth specification includes the probe, it will be specified as such. In those cases, the scope's bandwidth will be specified separately, and will be higher than the scope/probe combination. Vertical bandwidth on many high quality scopes will be described in their manuals or spec sheets when using a variety of probes, and will reflect the equivalent bandwidth accordingly. I'm interested in seeing info on the Tektronix way that proves that I am mistaken. I provided several sources that defend my statements. Did you read the sources that I provided links for? All quite credible sources. Did you do the math, or is your conclusion just an opinion? How would you calculate the combined risetime/bandwidth of a scope/probe combination? Please don't interpret my questions as being confrontational, I'm genuinely interested in learning if the technique that I used for years in calibration labs was, in fact, correct or totally wrong. The technique that we used was this: Using a high bandwidth scope, measure its risetime without the probe being connected (scope connected directly to a fast-rise pulse generator). Connect the probe being calibrated to the scope input, and connect the probe tip directly to the pulse generator output. Measure the resulting pulse risetime. Using the formula that I gave previously (rearranged to find the probe's risetime), calculate the probe's risetime and bandwidth. This method of measuring the performance of a probe worked quite well for the lab and our customers for the years that I was a cal technician (commercial and military). -- David dgminala at mediacombb dot net |
Probes
"brian whatcott" wrote in message
... The idea that a 55 MHz sine wave of 5 volt P-P amplitude would only register about 3.6 volts on a 60 MHz scope is an alien idea to me. That would render such a scope all but useless.... Have you used many older scopes? Effectively the older the scope, the more like that a scope labeled "60MHz" really did mean that the scope itself was 3dB down at that point -- and of course the probe will just make things worse. Things did get blurry over time, with HP and Tek starting to spec scopes based on a combination of the probe and mainframe used ... and perhaps not use 3dB as a reference anymore (all the bandwidth extension tricks they used tended to make the frequency response no longer look like a simple single-pole roll-off, and one could suggest that a 3dB point definition of bandwidth isn't that useful if you're already dropping at, e.g., 12dB or 18dB/octave rather than the expected 6 at that point...). And finally, once scopes started "going digital" in the late '80s and beyond, the response of the scope itself often became a lot closer to a brick-wall rather than the single-dominant-pole roll-off the old analog scopes often saw, at which point -- if you had a good enough probe -- the frequency response at the stated bandwidth might very well be 1dB down (...which is still 10% down in voltage, though!). I suggest that in American usage, I would be more likely to expect a 60 MHz sine wave to be not more than 5% down as indicated on a 60 MHz scope with its maker's standard probes. If you buy a new scope today, that's very likely the case... but if you get an old boat anchor, it'd be VERY surprising if it were anywhere close to "only" 5% off. ---Joel |
Probes
"Dave M" wrote in message
... I'm genuinely interested in learning if the technique that I used for years in calibration labs was, in fact, correct or totally wrong. The technique that we used was this: Using a high bandwidth scope, measure its risetime without the probe being connected (scope connected directly to a fast-rise pulse generator). Connect the probe being calibrated to the scope input, and connect the probe tip directly to the pulse generator output. Measure the resulting pulse risetime. Using the formula that I gave previously (rearranged to find the probe's risetime), calculate the probe's risetime and bandwidth. This method of measuring the performance of a probe worked quite well for the lab and our customers for the years that I was a cal technician (commercial and military). If all you have available is a pulse generator, this is a decent enough method -- just know that the formula to convert between rise time and bandwidth assumes a single-pole frequency rolloff, which is usually -- but not always -- a reasonable assumption. A more insightful means of measuring scope bandwidth is to take an RF generator that can produce a repetitive frequency sweep (with a leveled output), have the start of it trigger the scope, and then adjust the timebase settings so that you get, e.g., 10MHz or 100MHz or some other convenient MHz sweep per division. In other words, the scope's display effectively becomes a Bode plot of the system (scope + probe combined) response. ---Joel |
Probes
Joel Koltner wrote:
"Dave M" wrote in message ... I'm genuinely interested in learning if the technique that I used for years in calibration labs was, in fact, correct or totally wrong. The technique that we used was this: Using a high bandwidth scope, measure its risetime without the probe being connected (scope connected directly to a fast-rise pulse generator). Connect the probe being calibrated to the scope input, and connect the probe tip directly to the pulse generator output. Measure the resulting pulse risetime. Using the formula that I gave previously (rearranged to find the probe's risetime), calculate the probe's risetime and bandwidth. This method of measuring the performance of a probe worked quite well for the lab and our customers for the years that I was a cal technician (commercial and military). If all you have available is a pulse generator, this is a decent enough method -- just know that the formula to convert between rise time and bandwidth assumes a single-pole frequency rolloff, which is usually -- but not always -- a reasonable assumption. A more insightful means of measuring scope bandwidth is to take an RF generator that can produce a repetitive frequency sweep (with a leveled output), have the start of it trigger the scope, and then adjust the timebase settings so that you get, e.g., 10MHz or 100MHz or some other convenient MHz sweep per division. In other words, the scope's display effectively becomes a Bode plot of the system (scope + probe combined) response. ---Joel Thanks for the elaboration... makes sense. And yes, after wideband leveled generstors became available, we did use them to measure frequency response on scopes, but still relied on the risetime method to characterize probes. The reason for that was that the leveled generators that we had didn't cover the full spectrum of the scopes and probes that we encountered; we had a 30 picosecond risetime pulser that handled everything we saw. It has been several years since I worked in a cal lab, so the technology has progressed a good deal since. Are there any texts that describe the technique(s) by which the response of any given scope/probe combination can be calculated and verified? Not that I need to do it any more, just interested in knowing. -- David dgminala at mediacombb dot net |
Probes
Dave M wrote:
... Here are some attributions that elaborate on the effects of a probe on the overall bandwidth of a scope/probe combination. http://books.google.com/books?id=xHA...0probe&f=false http://www.adler-instrumentos.es/ima...%C3%B1al.pd f pg 3 http://www.freelists.org/post/si-lis...nt-equipment,9 http://www.analog.com/library/analog...cd/vol41n1.pdf pg 13 As you can see from the documents, the scope and probe bandwidths do interact as the RMS sum of the two. The vertical bandwidth or risetime of scopes is specified at the scope's input connector. If the bandwidth specification includes the probe, it will be specified as such. In those cases, the scope's bandwidth will be specified separately, and will be higher than the scope/probe combination. Vertical bandwidth on many high quality scopes will be described in their manuals or spec sheets when using a variety of probes, and will reflect the equivalent bandwidth accordingly. I'm interested in seeing info on the Tektronix way that proves that I am mistaken. I provided several sources that defend my statements. Did you read the sources that I provided links for? All quite credible sources. Did you do the math, or is your conclusion just an opinion? How would you calculate the combined risetime/bandwidth of a scope/probe combination? Please don't interpret my questions as being confrontational, I'm genuinely interested in learning if the technique that I used for years in calibration labs was, in fact, correct or totally wrong. The technique that we used was this: Using a high bandwidth scope, measure its risetime without the probe being connected (scope connected directly to a fast-rise pulse generator). Connect the probe being calibrated to the scope input, and connect the probe tip directly to the pulse generator output. Measure the resulting pulse risetime. Using the formula that I gave previously (rearranged to find the probe's risetime), calculate the probe's risetime and bandwidth. This method of measuring the performance of a probe worked quite well for the lab and our customers for the years that I was a cal technician (commercial and military). I started looking for a reference that I could trust - and I found it in a Tektronix note - a note that totally supports your position. Ooops! I was wrong - with a misplaced sense of what one can measure with Tektronix scopes. Sorry.... I appreciate your level tone though! http://www.tek.com/Measurement/App_N...55_18024_0.pdf Brian Whatcott Altus OK |
Probes
On May 31, 3:13�pm, nobody wrote:
Gary wrote: On May 30, 3:12 pm, Plasmah77 wrote: The 60 MHZ specification on your scope means its vertical amplifier and display will start to degrade at 60 MHZ or higher in frequency. � No. It is 3dB Bandwidth. Degrade will start earlier. You will have lost half power or in voltage around 30% of the signal. Therefore using a probe with a 60 MHZ rating will allow you to realize all of your scope's capabilities. There is also a capacitance specification that should match. It is however unlikely that it should not. Go ahead with the 100MHz probes if you get them at a fair price. The question was would a 100 MHZ probe work with a 60 MHZ scope. The asker claimed to be a beginner. I made a general comment about why it would. I saw no reason to muddy the waters by talking about half power points and 3dB bandwidths. Trying to make it simple. Gary N4AST |
Probes
On Jun 1, 5:45*pm, brian whatcott
http://www.tek.com/Measurement/App_N...fs/bw_rt/55_18... Brian Whatcott *Altus Hey OM: Great link there to the Tech article from tek tronics As pointed out in that article, a scope is worthless for measuring voltages. Towit a 60Mhz scope is only good to 10 Mhz, going by their standards, published, in that article. 73 OM de n8zu |
Probes
"Bob Spooner" wrote in message ... "Plasmah77" wrote in message ... I need to buy a probe for my oscilloscope which is 60 MHZ. My question is can I buy a probe that rated 100 MHZ or must I make sure it is rated 60 MHZ the same as my system? Thanks -- Plasmah77 You can buy a probe with a higher frequency rating than your scope has and it will work fine, it just will be more expensive. Regards, Bob Actually, it will also work "better." Pete |
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