OT: USB and LSB - How we got there

> Here's a URL to a website with lots of information:
>
> http://www.ac6v.com/73.htm#LSB
>
> Or, search "BC-458 command set transmitter" and
> "Central Electronics 10A" with your browser.
>
> 73!
>
> Ken Kopp - K0PP

>-----Original Message-----
>From: [hidden email] [mailto:elecraft-
>[hidden email]] On Behalf Of Ian White
>Sent: 15 February 2018 10:11
>To: 'Alan'; [hidden email]
>Subject: Re: [Elecraft] OT: USB and LSB - How we got there
>
>
>In 2003 I researched the subject for my RSGB Q&A column, 'In
>Practice', and was fortunate to be in contact with some amateurs

>different people on different continents, and at different times in
>the late 1940s.
>
>Those post-war years saw a rapid development in intercontinental HF
>telephone links. These links used independent-sideband (ISB)
>modulation to carry two separate voice channels on opposite
>sidebands, and a major manufacturer of ISB equipment at this time
>was the Marconi company. The ISB signal was created by up-
>converting
>two separately generated USB and LSB voice channels to the same
>suppressed carrier frequency, and the Marconi engineers made the
>smart decision to generate the ISB signal on 10.000MHz (a frequency
>on which they would never need to transmit, because it was already
>occupied by beacons such as WWV).
>
>For transmitted frequencies above 10MHz, Marconi used a
>crystal-controlled LO that was 10MHz below the output frequency; so
>the IF frequency was added to the LO and the two independent
>sidebands remained "the right way up". But for transmitted
>frequencies *below* 10MHz, the LO frequency was 10MHz *above*
>the
>output frequency; so the IF frequency was *subtracted* from the LO
>and the opposite sidebands were *inverted*. In an ISB system, that
>meant that the two telephone channels might very easily become
>swapped, so station engineers all around the world needed to be

>when to flip the appropriate switches.
>
>Out of these working arrangements between engineers, a worldwide
>CCIR standard emerged that 10MHz would be the frequency where the
>sidebands in ISB systems changed over.
>
>So what has this to do with amateur SSB? Amateur development in the
>late 1940s quickly followed the developments in commercial world -
>and sometimes involved the same individuals. A major influence was
>the W1DX SSB exciter, published in 1949, which automatically
>produced a sideband inversion between 80m and 20m. The W1DX
>design
>used the phasing method which allowed easy sideband selection by
>flipping a switch at AF, but by the early 1950s there were also

>filter-method exciters that were not so agile.
>
>By 1951-52, experimenters in Europe and the USA were beginning to
>talk to each other on 20m, and quickly realised that they were
>heading for a mess. Most people were using USB on 20m, but there
>was
>no international agreement on 80m... and what about the other
>bands?
>>From eyewitness accounts, April 1952 was the moment when the
>agreement crystallized as we know it today.
>
>The two key points in this history are: amateurs were *already
>aware* of the commercial dividing line at 10MHz; and the popular
>W1DX exciter was *already compatible* with the new proposed
>standard
>[1].
>
>And so it was that two entirely separate and obscure design
>decisions - by Marconi engineers and by W1DX - came together to
>create the standard that we have today.
>
>
>[1] SSB exciters using 9MHz SSB generation and a 5MHz VFO are not
>relevant to this history. They all came *after* the 10MHz standard
>was already in place.
>
>73 from Ian GM3SEK
>

>-----Original Message-----
>From: [hidden email] [mailto:elecraft-
>[hidden email]] On Behalf Of Ian White
>Sent: 15 February 2018 10:11
>To: 'Alan'; [hidden email]
>Subject: Re: [Elecraft] OT: USB and LSB - How we got there
>
>
>In 2003 I researched the subject for my RSGB Q&A column, 'In
>Practice', and was fortunate to be in contact with some amateurs

>different people on different continents, and at different times in
>the late 1940s.
>
>Those post-war years saw a rapid development in intercontinental HF
>telephone links. These links used independent-sideband (ISB)
>modulation to carry two separate voice channels on opposite
>sidebands, and a major manufacturer of ISB equipment at this time
>was the Marconi company. The ISB signal was created by up-
>converting
>two separately generated USB and LSB voice channels to the same
>suppressed carrier frequency, and the Marconi engineers made the
>smart decision to generate the ISB signal on 10.000MHz (a frequency
>on which they would never need to transmit, because it was already
>occupied by beacons such as WWV).
>
>For transmitted frequencies above 10MHz, Marconi used a
>crystal-controlled LO that was 10MHz below the output frequency; so
>the IF frequency was added to the LO and the two independent
>sidebands remained "the right way up". But for transmitted
>frequencies *below* 10MHz, the LO frequency was 10MHz *above*
>the
>output frequency; so the IF frequency was *subtracted* from the LO
>and the opposite sidebands were *inverted*. In an ISB system, that
>meant that the two telephone channels might very easily become
>swapped, so station engineers all around the world needed to be

>when to flip the appropriate switches.
>
>Out of these working arrangements between engineers, a worldwide
>CCIR standard emerged that 10MHz would be the frequency where the
>sidebands in ISB systems changed over.
>
>So what has this to do with amateur SSB? Amateur development in the
>late 1940s quickly followed the developments in commercial world -
>and sometimes involved the same individuals. A major influence was
>the W1DX SSB exciter, published in 1949, which automatically
>produced a sideband inversion between 80m and 20m. The W1DX
>design
>used the phasing method which allowed easy sideband selection by
>flipping a switch at AF, but by the early 1950s there were also

>filter-method exciters that were not so agile.
>
>By 1951-52, experimenters in Europe and the USA were beginning to
>talk to each other on 20m, and quickly realised that they were
>heading for a mess. Most people were using USB on 20m, but there
>was
>no international agreement on 80m... and what about the other
>bands?
>>From eyewitness accounts, April 1952 was the moment when the
>agreement crystallized as we know it today.
>
>The two key points in this history are: amateurs were *already
>aware* of the commercial dividing line at 10MHz; and the popular
>W1DX exciter was *already compatible* with the new proposed
>standard
>[1].
>
>And so it was that two entirely separate and obscure design
>decisions - by Marconi engineers and by W1DX - came together to
>create the standard that we have today.
>
>
>[1] SSB exciters using 9MHz SSB generation and a 5MHz VFO are not
>relevant to this history. They all came *after* the 10MHz standard
>was already in place.
>
>73 from Ian GM3SEK
>

>-----Original Message-----
>From: [hidden email] [mailto:elecraft-
>[hidden email]] On Behalf Of Ian White
>Sent: 15 February 2018 10:11
>To: 'Alan'; [hidden email]
>Subject: Re: [Elecraft] OT: USB and LSB - How we got there
>
>
>In 2003 I researched the subject for my RSGB Q&A column, 'In
>Practice', and was fortunate to be in contact with some amateurs

>different people on different continents, and at different times in
>the late 1940s.
>
>Those post-war years saw a rapid development in intercontinental HF
>telephone links. These links used independent-sideband (ISB)
>modulation to carry two separate voice channels on opposite
>sidebands, and a major manufacturer of ISB equipment at this time
>was the Marconi company. The ISB signal was created by up-
>converting
>two separately generated USB and LSB voice channels to the same
>suppressed carrier frequency, and the Marconi engineers made the
>smart decision to generate the ISB signal on 10.000MHz (a frequency
>on which they would never need to transmit, because it was already
>occupied by beacons such as WWV).
>
>For transmitted frequencies above 10MHz, Marconi used a
>crystal-controlled LO that was 10MHz below the output frequency; so
>the IF frequency was added to the LO and the two independent
>sidebands remained "the right way up". But for transmitted
>frequencies *below* 10MHz, the LO frequency was 10MHz *above*
>the
>output frequency; so the IF frequency was *subtracted* from the LO
>and the opposite sidebands were *inverted*. In an ISB system, that
>meant that the two telephone channels might very easily become
>swapped, so station engineers all around the world needed to be

>when to flip the appropriate switches.
>
>Out of these working arrangements between engineers, a worldwide
>CCIR standard emerged that 10MHz would be the frequency where the
>sidebands in ISB systems changed over.
>
>So what has this to do with amateur SSB? Amateur development in the
>late 1940s quickly followed the developments in commercial world -
>and sometimes involved the same individuals. A major influence was
>the W1DX SSB exciter, published in 1949, which automatically
>produced a sideband inversion between 80m and 20m. The W1DX
>design
>used the phasing method which allowed easy sideband selection by
>flipping a switch at AF, but by the early 1950s there were also

>filter-method exciters that were not so agile.
>
>By 1951-52, experimenters in Europe and the USA were beginning to
>talk to each other on 20m, and quickly realised that they were
>heading for a mess. Most people were using USB on 20m, but there
>was
>no international agreement on 80m... and what about the other
>bands?
>>From eyewitness accounts, April 1952 was the moment when the
>agreement crystallized as we know it today.
>
>The two key points in this history are: amateurs were *already
>aware* of the commercial dividing line at 10MHz; and the popular
>W1DX exciter was *already compatible* with the new proposed
>standard
>[1].
>
>And so it was that two entirely separate and obscure design
>decisions - by Marconi engineers and by W1DX - came together to
>create the standard that we have today.
>
>
>[1] SSB exciters using 9MHz SSB generation and a 5MHz VFO are not
>relevant to this history. They all came *after* the 10MHz standard
>was already in place.
>
>73 from Ian GM3SEK
>

> The 5.2 MHz SSB exciter construction article that Ian referred to
>
> in January 1949 QST is here:
>
>
>
> http://p1k.arrl.org/pubs_archive/29327
>
>
> 73
> Frank
> W3LPL

> Clarification:
>
> W2KUJ first published the design concept for a 20/80m SSB exciter
> using 5MHz SSB generation and a 9MHz VFO, in QST for June 1948.
>
> W1DX then expanded W2KUJ's block-diagram concept into a practical
> design for others to copy, and this was published in January 1949.
>
> 73 from Ian GM3SEK
>
>> -----Original Message-----
>> From: [hidden email] [mailto:elecraft-
>> [hidden email]] On Behalf Of Ian White
>> Sent: 15 February 2018 10:11
>> To: 'Alan'; [hidden email]
>> Subject: Re: [Elecraft] OT: USB and LSB - How we got there
>>
>>
>> In 2003 I researched the subject for my RSGB Q&A column, 'In
>> Practice', and was fortunate to be in contact with some amateurs
> who
>> were personally involved in the decision to switch sidebands at
>> 10MHz. This decision was made in April 1952 and eventually became
>> an
>> IARU standard - but its origins are surprisingly technical. The
>> standard came out of two totally unrelated design decisions, made
> by
>> different people on different continents, and at different times in
>> the late 1940s.
>>
>> Those post-war years saw a rapid development in intercontinental HF
>> telephone links. These links used independent-sideband (ISB)
>> modulation to carry two separate voice channels on opposite
>> sidebands, and a major manufacturer of ISB equipment at this time
>> was the Marconi company. The ISB signal was created by up-
>> converting
>> two separately generated USB and LSB voice channels to the same
>> suppressed carrier frequency, and the Marconi engineers made the
>> smart decision to generate the ISB signal on 10.000MHz (a frequency
>> on which they would never need to transmit, because it was already
>> occupied by beacons such as WWV).
>>
>> For transmitted frequencies above 10MHz, Marconi used a
>> crystal-controlled LO that was 10MHz below the output frequency; so
>> the IF frequency was added to the LO and the two independent
>> sidebands remained "the right way up". But for transmitted
>> frequencies *below* 10MHz, the LO frequency was 10MHz *above*
>> the
>> output frequency; so the IF frequency was *subtracted* from the LO
>> and the opposite sidebands were *inverted*. In an ISB system, that
>> meant that the two telephone channels might very easily become
>> swapped, so station engineers all around the world needed to be
> sure
>> when to flip the appropriate switches.
>>
>> Out of these working arrangements between engineers, a worldwide
>> CCIR standard emerged that 10MHz would be the frequency where the
>> sidebands in ISB systems changed over.
>>
>> So what has this to do with amateur SSB? Amateur development in the
>> late 1940s quickly followed the developments in commercial world -
>> and sometimes involved the same individuals. A major influence was
>> the W1DX SSB exciter, published in 1949, which automatically
>> produced a sideband inversion between 80m and 20m. The W1DX
>> design
>> used the phasing method which allowed easy sideband selection by
>> flipping a switch at AF, but by the early 1950s there were also
> many
>> filter-method exciters that were not so agile.
>>
>> By 1951-52, experimenters in Europe and the USA were beginning to
>> talk to each other on 20m, and quickly realised that they were
>> heading for a mess. Most people were using USB on 20m, but there
>> was
>> no international agreement on 80m... and what about the other
>> bands?
>> >From eyewitness accounts, April 1952 was the moment when the
>> agreement crystallized as we know it today.
>>
>> The two key points in this history are: amateurs were *already
>> aware* of the commercial dividing line at 10MHz; and the popular
>> W1DX exciter was *already compatible* with the new proposed
>> standard
>> [1].
>>
>> And so it was that two entirely separate and obscure design
>> decisions - by Marconi engineers and by W1DX - came together to
>> create the standard that we have today.
>>
>>
>> [1] SSB exciters using 9MHz SSB generation and a 5MHz VFO are not
>> relevant to this history. They all came *after* the 10MHz standard
>> was already in place.
>>
>> 73 from Ian GM3SEK
>>
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