ConclusionSignificant improvements are required in the performance of MSW dispersive delay lines and filter banks before they are ready for systems application. Typically delay lines with bandwidths of 1 GHz or greater, differential delays in the range 200 ns to 1μs, and minimum phase errors (<±1 °) are required for large (∿40 dB) dynamic range compressive receivers. However, techniques are evolving (see rest of this issue) in this relatively new area of technology which will allow systems performance requirements on phase errors to be met. Possible approaches to low phase error dispersive delay lines include reflective arrays, stepped ground planes, and multiple YIG films. The stepped ground plane technique is the most advanced and uses an optimization approach to the delay-line design, which results in a minimum phase error [20]. Ultimately the minimum achievable phase error will be limited by reflections from transducers and multiple mode effects in the delay lines. The MSW compressive receiver requires parallel advances in high-speed digital processing techniques to achieve its full potential.The MSW filter bank provides a simple channelization technique applicable up to approximately 20 GHz. Narrowband channels with 10 dB insertion loss, 3 dB bandwidths of 10 to 40 MHz, and 50 dB bandwidths of 30 to 120 MHz are possible with the already demonstrated techniques. Broader bandwidth channels in the range 50 to 200 MHz with flat passband response require improved transducer design techniques. The channelized receiver does not require extremely high-speed operations but, since a large number of channels are involved, size and cost become very significant.
[1]
G. L. Moule.
SAW compressive receivers for radar intercept
,
1982
.
[2]
M. R. Daniel,et al.
MSW Dispersive Delay Lines in a Compressive Receiver
,
1982
.
[3]
P. R. Emtage,et al.
Dispersive delay at gigahertz frequencies using magnetostatic waves
,
1985
.
[4]
J. M. Owens,et al.
Tunable Microwave Filters using YIG Grown by Liquid Phase Epitaxy
,
1974
.
[5]
J. Collins,et al.
Propagating magnetic waves in thick films A complementary technology to surface wave acoustics
,
1973
.
[6]
W. L. Bongianni,et al.
Magnetic Wave Devices for Microwave Applications
,
1974
.
[7]
M.A. Jack,et al.
The theory, design, and applications of surface acoustic wave Fourier-transform processors
,
1980,
Proceedings of the IEEE.