We show how the ability to design chaotic circuits with prescribed statistical features is fundamental for the reduction of Electromagnetic Interference (EMI) due to timing signals, such as the clock signals widely employed in digital circuits. In fact, due to their periodic nature and to the presence of sharp edges, the power of such signals is concentrated at those frequencies corresponding to the multiples of the timing signal period. This can obviously produce serious concerns in terms of EMI. For simple clock signals, an appreciable EMI reduction can be achieved by means of a simple quasi-stationary frequency modulation (FM) directed at intentionally perturbing a normally narrowband signal, thus spreading the energy associate to each harmonic over a large bandwidth in order to reduce the peak value. More specifically here we review some different solutions to show that modulations which employ a random signal are the most suitable for EMI reduction. Furthermore, we present some analytic expressions linking the power density spectrum of a FM timing signal to the features of the modulation a PAM signal generated by a one-dimensional chaotic map, both in the case of slow (quasi-stationary) modulation and for the opposite case of fast modulation. We also show how the case of fast modulation offers further advantages with respect to slow modulation, in terms of EMI reduction. Theoretical results are also compared with measurement from two different prototypes of low EMI Spread Spectrum Clock Generators (SSCGs) in CMOS technology which employ a fast modulation. The first one is designed in an established technology, and a low frequency (f0 = 100MHz) has been chosen because considered suitable for proving the obtained theoretical results. The second one is the scaling of the first to a more advanced technology, and it has been designed in order to operate at a much higher frequency, namely f0 = 2.5GHz. The EMI reduction, for the two prototypes, has been measured respectively in 18 dB and 16 dB. In both prototype the random modulating signal is given by the output of an ADC-based Random Bit Generator, obtained through a chaotic map, which is described in details in chapter 8.

Implementation of low EMI spread spectrum clock generators exploiting a chaos-based jitter

PARESCHI, Fabio;SETTI, Gianluca;
2009

Abstract

We show how the ability to design chaotic circuits with prescribed statistical features is fundamental for the reduction of Electromagnetic Interference (EMI) due to timing signals, such as the clock signals widely employed in digital circuits. In fact, due to their periodic nature and to the presence of sharp edges, the power of such signals is concentrated at those frequencies corresponding to the multiples of the timing signal period. This can obviously produce serious concerns in terms of EMI. For simple clock signals, an appreciable EMI reduction can be achieved by means of a simple quasi-stationary frequency modulation (FM) directed at intentionally perturbing a normally narrowband signal, thus spreading the energy associate to each harmonic over a large bandwidth in order to reduce the peak value. More specifically here we review some different solutions to show that modulations which employ a random signal are the most suitable for EMI reduction. Furthermore, we present some analytic expressions linking the power density spectrum of a FM timing signal to the features of the modulation a PAM signal generated by a one-dimensional chaotic map, both in the case of slow (quasi-stationary) modulation and for the opposite case of fast modulation. We also show how the case of fast modulation offers further advantages with respect to slow modulation, in terms of EMI reduction. Theoretical results are also compared with measurement from two different prototypes of low EMI Spread Spectrum Clock Generators (SSCGs) in CMOS technology which employ a fast modulation. The first one is designed in an established technology, and a low frequency (f0 = 100MHz) has been chosen because considered suitable for proving the obtained theoretical results. The second one is the scaling of the first to a more advanced technology, and it has been designed in order to operate at a much higher frequency, namely f0 = 2.5GHz. The EMI reduction, for the two prototypes, has been measured respectively in 18 dB and 16 dB. In both prototype the random modulating signal is given by the output of an ADC-based Random Bit Generator, obtained through a chaotic map, which is described in details in chapter 8.
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Utilizza questo identificativo per citare o creare un link a questo documento: http://hdl.handle.net/11392/533577
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