Matched, Lossless, Reciprocal Devices

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/6/009 Matched reciprocal lossless present / Matched, Lossless, Reciprocal Devices As we discussed earlier, a device can be lossless or reciprocal. In addition, we can likewise classify it as being matched. Let s examine each of these three characteristics, and how they relate to the scattering matrix. Matched A matched device is another way of saying that the input impedance at each port is equal to Z 0 when all other ports are terminated in matched loads. As a result, the reflection coefficient of each port is zero no signal will be come out of a port if a signal is incident on that port (but only that port!). In other words, we want: + m mm m = = 0 for all m a result that occurs when: mm = 0 for all m if matched Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present / We find therefore that a matched device will exhibit a scattering matrix where all diagonal elements are zero. Therefore: 0 0. j 0. = 0. 0 0.3 j 0. 0.3 0 is an example of a scattering matrix for a matched, three port device. Lossless For a lossless device, all of the power that delivered to each device port must eventually find its way out! In other words, power is not absorbed by the network no power to be converted to heat! Recall the power incident on some port m is related to the amplitude of the incident wave + ) as: ( 0m m + = While power of the wave exiting the port is: + 0m 0 Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present 3/ m = 0m 0 Thus, the power delivered to (absorbed by) that port is the difference of the two: + 0m 0m + m = m m = 0 0 Thus, the total power incident on an -port device is: ote that: + = m + = + 0m m= 0 m= m= ( ) + + + 0m = where operator indicates the conjugate transpose (i.e., ermetian transpose) + operation, so that ( ) + is the inner product (i.e., dot product, or scalar product) of complex vector + with itself. Thus, we can write the total power incident on the device as: Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present 4/ ( ) + + + + = 0m = 0 m= 0 imilarly, we can express the total power of the waves exiting our M-port network to be: ( ) 0m 0 m= Z0 = = ow, recalling that the incident and exiting wave amplitudes are related by the scattering matrix of the device: + = Thus we find: ( ) ( ) + + = = 0 0 ow, the total power delivered to the network is: M = = m= + Or explicitly: Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present 5/ where I is the identity matrix. + = ( ) ( ) + + + + = 0 0 0 = ( ) ( I ) + + Q: Is there actually some point to this long, rambling, complex presentation? A: Absolutely! If our M-port device is lossless then the total power exiting the device must always be equal to the total power incident on it. + If network is lossless, then =. Or stated another way, the total power delivered to the device (i.e., the power absorbed by the device) must always be zero if the device is lossless! If network is then 0 lossless, = Thus, we can conclude from our math that for a lossless device: Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present 6/ = ( ) ( I ) = 0 for all 0 + + + This is true only if: I = 0 = I Thus, we can conclude that the scattering matrix of a lossless device has the characteristic: If a network is lossless, then = I Q: uh? What exactly is this supposed to tell us? A: A matrix that satisfies matrix. = I is a special kind of matrix known as a unitary If a network is lossless, then its scattering matrix is unitary. Q: ow do I recognize a unitary matrix if I see one? Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present 7/ A: The columns of a unitary matrix form an orthonormal set! = 3 4 33 4 3 3 33 43 4 33 44 matrix columns In other words, each column of the scattering matrix will have a magnitude equal to one: m = mn = for all n while the inner product (i.e., dot product) of dissimilar columns must be zero. ni nj = ij + ij + + i j = 0 for all i j n = In other words, dissimilar columns are orthogonal. Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present 8/ Consider, for example, a lossless three-port device. ay a signal is incident on port, and that all other ports are terminated. The power incident on port is therefore: + = + 0 0 while the power exiting the device at each port is: 0m m 0 + m = = = m 0 0 The total power exiting the device is therefore: = + + 3 + + + 3 = + + ( ) + 3 = + + ince this device is lossless, then the incident power (only on port ) is equal to exiting + power (i.e, = ). This is true only if: + + 3 = Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present 9/ Of course, this will likewise be true if the incident wave is placed on any of the other ports of this lossless device: + + 3 = 3 3 33 + + = We can state in general then that: 3 m = mn = for all n In other words, the columns of the scattering matrix must have unit magnitude (a requirement of all unitary matrices). It is apparent that this must be true for energy to be conserved. An example of a (unitary) scattering matrix for a lossless device is: 0 3 j 0 3 0 0 j = 3 j 0 0 3 0 j 0 Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present 0/ Reciprocal Recall reciprocity results when we build a passive (i.e., unpowered) device with simple materials. For a reciprocal network, we find that the elements of the scattering matrix are related as: = For example, a reciprocal device will have = or 3 = 3. We can write reciprocity in matrix form as: mn nm T = if reciprocal where T indicates (non-conjugate) transpose. Jim tiles The Univ. of Kansas Dept. of EEC

/6/009 Matched reciprocal lossless present / An example of a scattering matrix describing a reciprocal, but lossy and non-matched device is: 0.0 0.40 j 0.0 0.05 0.40 j 0.0 0 j 0.0 = j0.0 0 0.0 j0.30 0. 0.05 j 0.0 0. 0 Jim tiles The Univ. of Kansas Dept. of EEC

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