ASN9 - 3rd Harmonic & QSD: Difference between revisions
Jump to navigation
Jump to search
Jodi.Hodge (talk | contribs) No edit summary |
Jodi.Hodge (talk | contribs) No edit summary |
||
| (22 intermediate revisions by the same user not shown) | |||
| Line 1: | Line 1: | ||
[[Jodi Hodge|Back to my home page]] |
[[Jodi Hodge|Back to my home page]] |
||
Third Harmonic Sampling |
|||
Third harmonic sampling is used in some applications, such as the SoftRock-40 software defined radio, to divide the local oscillator frequency by three. |
|||
'''Third Harmonic Sampling''' |
|||
Consider the simple representation of part of a software defined radio below. |
|||
The cosine series is made up of a infintie sum of harmonics |
|||
<math> |
|||
\sum_{n=1}^{\infty} \frac{1}{n} cos(n \omega t) = cos(\omega t) + \frac{1}{2}cos(2\omega t) + \frac{1}{3}cos(3\omega t) + \frac{1}{4}cos(4\omega t) + \cdots </math> |
|||
The third harmonic is the third term |
|||
The local oscillator can be defined as , giving us a square wave. Note that |
|||
<math> \frac{1}{3}cos(3\omega t)</math>. |
|||
The benefit of using the third harmonic for sampling in a circuit rather than than the first harmonic is that it creates an oscillation that is three times as fast. SoftRock -40 software defined radio for example uses third harmonic sampling as a technique to obtain faster oscillation. In addition, third harmonic sampling is that it is cheaper to buy a low frequency oscillator and the parts driven by one. The disadvantage is that it results in power loss of -9.54dB.See how Softrock uses Third Harmonic Sampling[http://www.groups.yahoo.com/group/softrock40 Soft Rock] |
|||
The output voltage of the radio, or is |
|||
Now can be written as the series |
|||
We are interested in the third harmonic term, or |
|||
This frequency is three times that of . Note that the period decreases by a factor of three. |
|||
We can use the third harmonic to drive the mixer in the radio at a frequency three time that of the local oscillator. |
|||
The advantage of using the third harmonic rather than using a higher speed oscillator is that it costs less to buy both a lower frequency oscillator as well as the parts that are driven by the oscillator. |
|||
The disadvantage is that there is some loss in the signal when the third harmonic is used, specifically |
|||
We can now apply the same concept to a radio with parallel doubly balanced mixers. The radio could be represented such as in the diagram below. |
|||
We could use a mixer like this one. |
|||
[edit] Quadrature Sampling Detector |
|||
If you read the above section about third harmonic sampling, then you might be wondering how we input both and into the parallel mixers. The answer is that we can use a quadrature sampling detector, or QSD. |
|||
The local oscillator is directly fed to the lower-channel mixer and is delayed 90 to feed the upper-channel mixer. The upper channel provides the in-phase signal , and the lower channel provides the quadrature signal . |
|||
A common QSD is the Tayloe detector, named after designer Dan Tayloe. The Tayloe detector can be thought of as a four-position rotary switch. The switch revolves at the same rate as the carrier frequency. Each of the four switch positions is connected to a sampling capacitor, and the 50 ohm antenna impedance is connected to the rotor. Each capacitor will track the carrier's amplitude for exactly one-quarter of the cycle since the switch rotor is turning at exactly the RF carrier frequency, causing the switch to sample the signal at 0°, 90°, 180° and 270°. If the switch is off, each capacitor will hold its value for the remainder of the cycle. The 180° and 270° outputs carry redundant information with the 0° and 90° outputs respectively. Therefore the 0° and 180° outputs can be summed differentially to produce the in-phase signal (I). Similarly, the 90° and 270° can be summed to form the quadrature signal (Q). |
|||
Problem Statement |
|||
Explain how Third Harmonic Sampling works and explain how a Quadrature Sampling Detector works too. |
|||
Solution |
|||
When considering the properties of an oscillator's wave it is important to include its Fourier series. From electronics last year we were able to construct a square wave by summing multiple sine waves with the same basic n * ω or rather the summation . As indicated in the problem statement we are interested in the third one, or rather the third harmonic: |
|||
Comparing this to our original function of cos(ωt) we have three times the frequency or rather a third of the period. |
|||
For the soft rock 40 radio this property is used to maintain a cost effective ham radio while achieving a high quality signal output. It is important for the mixer to have a very high frequency but oscillators that operate at the frequencies required are very expensive so a cheaper oscillator may be purchased while maintaining the function of the radio. |
|||
Unfortunately their is loss attributed to increasing the oscillator frequency. Because our amplitude in the series is reduced by 1/n for each harmonic we are only at 1/3 the amplitude for the third harmonic. Rather this is a loss. |
|||
In electronics we built a radio that required both the real and imaginary parts of the signal to go through the mixer. This requires us to mix with a sine and cosine wave simultaneously in different parts of our circuitry. To do this it is necessary to use a QSD (Quadrature Sampling Detector). This can be built with either diodes and transformers or transistors and transformers. I believe we attempted both designs and finally settled on the transistor schematic. The concept that allowed me to understand the QSD had to do with the unit circle. |
|||
(I apologize for the large size, I didnt bother resizing it.) |
|||
As the oscillator signal is sent through the QSD it in turn rotates around the unit circle. First it is at 0° then it rotates to 90° then to 180° and finally to 270° before returning to 0°. In my mind their is a switch opperating like a clock hand in the center of the circle and wires to hook up with it at each of the axis'. The signals received during these rotations then sent out to the two mixers. The 0° and 180° are sent out to the cosine wave and the 90° and 270° are sent to the sine wave. Although it is only a matter of phase as to which signal they are to mix with and can be adjusted as to the designers preference. |
|||
'''1. How does Third Harmonic Sampling work? (''The [http://www.groups.yahoo.com/group/softrock40 Soft Rock] receiver uses it.'')''' |
|||
<br/> |
|||
'''2. How does the quadrature sampling detector (QSD) work? (''Look at the [http://www.flex-radio.com/News.aspx?topic=publications SDR-1000 QEX] articles.'')''' |
|||
<br/> |
|||
[[Nick Christman|<b><u>Nick Christman</u></b>]]<br/> |
|||
---- |
|||
'''Third Harmonic Sampling''' |
|||
The ''Softrock 40'' software defined radio (SDR) uses a special technique when sampling the data -- this technique is referred to as '''3rd Harmonic Sampling'''. The purpose of 3rd Harmonic Sampling is to eliminate the need to use a high frequency oscillator which is useful economically and physically. (In other words, a high frequency oscillator is expensive and is often incompatible with "cheaper" switches.) However, nothing in this world is perfect and because of this imperfection, Third Harmonic Sampling have a signal loss of <math>\textstyle 20 \log_{10} (\frac{1}{3}) = -9.54 db</math> (Max Woesner). |
|||
So how does Third Harmonic Sampling work? Well, let's take for example a very basic SDR (similar to the one designed in Electronics II). In the most basic SDR there is a local oscillator that outputs a wave in the form of a square wave. Now, this square is not the product of 21st century sorcery, but instead it is the result of an "infinite" sinusoidal series that is evaluated at the desired local oscillation frequency. This sinusoidal series is refereed to as a Fourier series and is defined as |
|||
<br/> |
|||
<br/> |
|||
<math> |
|||
\sum_{n=1}^{\infty} \frac{1}{n} cos(n \omega t) = cos(\omega t) + \frac{1}{2}cos(2\omega t) + \frac{1}{3}cos(3\omega t) + \frac{1}{4}cos(4\omega t) + \cdots </math> |
|||
<br/> |
|||
<br/> |
|||
Of course, the segment of this series we are particulary interested in is the third harmonic, or <math>\textstyle \frac{1}{3}cos(3\omega t)</math>. Notice the constant <math>\textstyle \frac{1}{3}</math> in front of the cosine -- this is where the 9.54 db loss originates from (mathematically). From here, we simply use the third harmonic cosine as our local oscillator frequency. |
|||
<br/> |
|||
<br/> |
|||
'''Quadrature Sampling Detector''' |
|||
'''Quadrature Sampling''' |
|||
A Quadrature Sampling Detector (QSD) is used to create a cosine (or sine) waveform from a established sine (or cosine) waveform. (I say "sine or cosine" because the output waveform is simply sinusoidal -- there is really no way to distinguish between sine and cosine, we can only distinguish between <math>\textstyle O \deg \mbox{ and } 90 \deg</math>.) |
|||
Describe how third harmonic sampling and QSD (Quadrature Sampling Detector works. |
|||
A Quadrature is output signal that is a phase off from the output signal. For example, in a software define radio two signals that are generated from two mixers are phase shifted 90 degrees. One signal is the desired signal and the second is the quadrature signal that is used for quadrature sampling. |
|||
For this assignment I will look third harmonic sampling and QSD as used by SoftRock-40 software defined radio. For SoftRock they needed a high frequency oscillator to provide the necessary signal to mix with the signal coming from the antenna. The reason this oscillation needed to be so high was due to there design which used one oscillator to create both the sin and cos waveform for there mixer. To do this they needed a oscillator with a frequency four times higher than the frequency they wished to sample. Getting an oscillator at these speeds is both difficult and expensive so they came up with a clever way to use the third harmonic form their oscillator to achieve the frequency necessary. |
|||
Further information on Quadrature Sampling |
|||
It is known by using Fourier Series a square wave can be made up of a series of cos wave i.e. <math>\sum_{n=1}^\infty \frac{1}{n} cos(n \omega t)</math>.<br><br> |
|||
[http://www.flex-radio.com/News.aspx?topic=publications SDR-1000 QEX] |
|||
SoftRock decided that they could use the 3rd harmonic of this i.e <math>\frac{1}{3}cos(3\omega t</math> to get the required oscillation without the hassle and cost of using a high frequency oscillator. Stated another way they need an oscillator that has a frequency three time slower than the one originally needed. The disadvantage to this is that the signal strength is a third smaller or around a 9.5 dB loss. |
|||
Latest revision as of 13:50, 19 December 2009
Third Harmonic Sampling
The cosine series is made up of a infintie sum of harmonics
The third harmonic is the third term
.
The benefit of using the third harmonic for sampling in a circuit rather than than the first harmonic is that it creates an oscillation that is three times as fast. SoftRock -40 software defined radio for example uses third harmonic sampling as a technique to obtain faster oscillation. In addition, third harmonic sampling is that it is cheaper to buy a low frequency oscillator and the parts driven by one. The disadvantage is that it results in power loss of -9.54dB.See how Softrock uses Third Harmonic SamplingSoft Rock
Quadrature Sampling
A Quadrature is output signal that is a phase off from the output signal. For example, in a software define radio two signals that are generated from two mixers are phase shifted 90 degrees. One signal is the desired signal and the second is the quadrature signal that is used for quadrature sampling.
Further information on Quadrature Sampling