2017
DOI: 10.1109/tcsi.2017.2715885
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Time Domain Processing Techniques Using Ring Oscillator-Based Filter Structures

Abstract: The ability to process time-encoded signals with high fidelity is becoming increasingly important for the time domain (TD) circuit techniques that are used at the advanced nanometer technology nodes. This paper proposes a compact oscillator-based subsystem that performs precise filtering of asynchronous pulse-width modulation encoded signals and makes extensive use of digital logic, enabling low-voltage operation. First- and second-order primitives are introduced that can be used as TD memory or to enable anal… Show more

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Cited by 32 publications
(16 citation statements)
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“…Finally, AFEs that rely on a conversion of the signal amplitude to the frequency domain, time/frequency based AFEs, show large efficiency in terms of occupation area (Tu et al, 2017;Jeon et al, 2019). Herein, voltage-controlled oscillators (VCOs) based circuits, which transforms the input signal amplitude into different oscillation frequencies, have recently proven to be an efficient low-power alternative to conventional AFEs (Jiang et al, 2017) and low-frequency filters (Leene and Constandinou, 2017). In these topologies, an AC-coupled input transconductance, G m , converts the input voltage to current, which is translated to phase by a current-controlled oscillator (CCO) and, finally, converted to the digital domain by a quantizer.…”
Section: Neural Recording Afesmentioning
confidence: 99%
“…Finally, AFEs that rely on a conversion of the signal amplitude to the frequency domain, time/frequency based AFEs, show large efficiency in terms of occupation area (Tu et al, 2017;Jeon et al, 2019). Herein, voltage-controlled oscillators (VCOs) based circuits, which transforms the input signal amplitude into different oscillation frequencies, have recently proven to be an efficient low-power alternative to conventional AFEs (Jiang et al, 2017) and low-frequency filters (Leene and Constandinou, 2017). In these topologies, an AC-coupled input transconductance, G m , converts the input voltage to current, which is translated to phase by a current-controlled oscillator (CCO) and, finally, converted to the digital domain by a quantizer.…”
Section: Neural Recording Afesmentioning
confidence: 99%
“…As a basis for oscillator based circuits, Equation 1 formulates the small-signal phase response φ(t) of a CCO in terms of the oscillation frequency f osc , the static bias current I bias , and the small-signal current input i ∆ [13]. This simply tells us that the total amount of charge injected over time is accumulated and scaled by an integration factor.…”
Section: Oscillator Based ∆σ Conversionmentioning
confidence: 99%
“…Clearly the phase difference is also being detected using an XOR gate however this circuit also generates overflow and underflow events as UP and DN signals. These are generated by combining a double-edge sensitive flip-flop with time-domain processing to perform level detection [13]. The principle of operation here is that the Q 5 will always track whichever oscillator in the differential structure is leading.…”
Section: Circuit Implementationmentioning
confidence: 99%
“…Even for such a scaled technology, time-domain design is a very promising design method since it offers a better trade-off between dynamic range and power consumption. The advantage of time-domain systems is that they use high-speed MOS devices, which means they have a shorter time delay and so process time with more precision [4][5][6].…”
Section: Introductionmentioning
confidence: 99%