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Transcript
Companding in Fixed Point DSPs A scheme to reduce the quantization (roundoff) errors in Fixed Point DSPs ADVANTAGE OF LARGE SIGNALS • When the signals in the DSP are large, they take full advantage of the available bits. • When the signals in the DSP are small, only a few of the available bits are used. • The roundoff error is essentially independent of the signal level, so the distortion due to roundoff is much worse for small signals To reduce roundoff error, I would like to keep all digital signals as large as possible at all times. Since the system has a set overflow tolerance, I would like all digital signals to have a roughly constant envelope, where the constant is slightly lower than the system overflow tolerance Suppose I have analog input, u(t), and analog output, y(t), so I need an ADC and a DAC: u(t) ADC DAC y(t) Consider multiplying the analog input by a time varying signal, g(n), which is LARGE when the input signal is SMALL, and SMALL when the input signal is LARGE, so that I get a roughly constant envelope signal For example, if env(n) is the (sampled) envelope of the input, g(n) could be k/env(n) where k is some constant slightly lower than the system overflow tolerance level. If g(n) is LARGE when u(nT) is SMALL, and SMALL when u(nT) is LARGE, then g(n)*u(nT) stays at a roughly constant signal level, and can be set large always. I would therefore like to multiply my input by g(n) BEFORE it gets to the ADC, so that the ADC ALWAYS sees a large signal. To preserve the input/output behavior (but with less quantization noise), I would like to multiply the output signal by 1/g(n). The multiplication by 1/g(n) should come AFTER the DAC so that THE SIGNAL STAYS LARGE WHENEVER IT IS DIGITAL. So I would get: u(nT) X ADC g(n) X DAC y(nT) 1/g(n) This is “classical” companding. The input signal level can vary wildly, but the digital system sees a signal level that is essentially constant. This can therefore allow a digital system to cover a large dynamic range with only a few bits. But note that there is NO DSP here between the ADC and DAC I would like to try this with a DSP in between the ADC and DAC. Would the scheme below work? u(nT) g(n) X ADC DSP DAC 1/g(n) X y(nT) NO! Using classical companding on a DSP will horribly distort the input/output behavior Taking a DSP, multiplying its input by a time-varying signal g(n), and then multiplying the output by 1/g(n) will, in general, CHANGE the input/output behavior of the DSP (dramatically) For example, let y(n)=u(n-k) So the DSP is a k-sample delay. If I do: u(nT) g(n) X ADC Z-k DAC X y(nT) 1/g(n) •The output is now g(n-k)*u(n-k)/g(n) •This is NOT equal to u(n-k). •It is DISTORTED by the factor g(n-k)/g(n). •This is a time-varying distortion. •More complicated systems will have more complicated distortions All is not lost: I can preserve input/output behavior by making internal corrections in the DSP Consider a system given by: x(n+1)=A*x(n)+B*u(n) y(n)=C*x(n)+D*u(n) I want the internal states to be large for all n, so I will do a change of basis in the state space: w(n)=G(n)*x(n) w(n)=G(n)*x(n) so x(n)=G-1(n)*w(n) w(n+1)=G(n+1)*x(n+1)= G(n+1)*A*x(n)+G(n+1)*B*u(n)= [G(n+1)*A* G-1(n)]*w(n)+[G(n+1)*B]*u(n) y(n)=[C*G-1(n)]*w(n)+D*u(n) This is a new internally time-varying system, whose states are always large, but whose input/output behavior is identical to the original system’s! In block form: u(nT) gu(n) X ADC DSP DAC G(n) X gy(n) Taken together, the multiplications at the input and output, along with the internal corrections in the DSP, ensure two things: •All digital signals are always large •The input/output behavior (not including quantization error) is the same as in the original (non-companding) DSP y(nT) Companding for DSPs •Multiplies the input by a signal (based on the G(n) matrix), which ensures that the signal at the ADC is always large. •Makes internal corrections to the states of the DSP to ensure that the states are always large. •Multiplies the output of the DAC by another signal (based on G(n)). This is necessary, since companding ensures that the output of the DAC is always large, while the actual output will not always be large. •These modifications do NOT change the input/output behavior (they only lower the quantization error). Project Proposal •Implement companding on an actual DSP – a simple digital reverberator Project Proposal (cont’d) • For a given output “quality” how many bits are needed in the original, non-companding DSP versus in the companding DSP? • For a given number of bits, how does the output “quality” compare between the original, non-companding DSP versus the companding DSP? Project Proposal (cont’d) • Can I quantify the improvements? For example: •Mean square error of output •SNR (as a function of signal level) •Harmonic distortion in spectrum I would like to find all these for both the companding and the non-companding systems as a function of the number of bits used in the system.
