B
bamse
Guest
Hello
I am wondering if it is possible to design a filter with the impulseresponse
h(t) such that the convolution of
a signal p(t)=f(t)*cos(w*t)+g(t)*sin(w*t) with h(t) is equal to
f(t)*sin(w*t)+g(t)*cos(w*t)???
In other words, I am looking for a filter H(s) in the s-domain that has the
following property:
InverseLaplace { H(s)*P(s) } = f(t)*sin(w*t)+g(t)*cos(w*t)
where P(s)=Laplace{p(t)}
Some more info:
f(t) is a train of half-sine pulses with the period T
g(t) is also a train of half-sine pulses with the period T, but
g(t) is delayed 0.5T in relation to f(t)
The pulsefrequency in rad/sec = 2*pi/T is much lower than
the carrier-frequency w.
I am wondering if it is possible to design a filter with the impulseresponse
h(t) such that the convolution of
a signal p(t)=f(t)*cos(w*t)+g(t)*sin(w*t) with h(t) is equal to
f(t)*sin(w*t)+g(t)*cos(w*t)???
In other words, I am looking for a filter H(s) in the s-domain that has the
following property:
InverseLaplace { H(s)*P(s) } = f(t)*sin(w*t)+g(t)*cos(w*t)
where P(s)=Laplace{p(t)}
Some more info:
f(t) is a train of half-sine pulses with the period T
g(t) is also a train of half-sine pulses with the period T, but
g(t) is delayed 0.5T in relation to f(t)
The pulsefrequency in rad/sec = 2*pi/T is much lower than
the carrier-frequency w.