Time Domain Processing Techniques Using Ring Oscillator-Based Filter Structures

Leene, Lieuwe B.; Constandinou, Timothy G.

doi:10.1109/tcsi.2017.2715885

Cited by 32 publications

(16 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…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%

Recording Strategies for High Channel Count, Densely Spaced Microelectrode Arrays

Perez-Prieto

Delgado‐Restituto

2021

Front. Neurosci.

View full text Add to dashboard Cite

Neuroscience research into how complex brain functions are implemented at an extra-cellular level requires in vivo neural recording interfaces, including microelectrodes and read-out circuitry, with increased observability and spatial resolution. The trend in neural recording interfaces toward employing high-channel-count probes or 2D microelectrodes arrays with densely spaced recording sites for recording large neuronal populations makes it harder to save on resources. The low-noise, low-power requirement specifications of the analog front-end usually requires large silicon occupation, making the problem even more challenging. One common approach to alleviating this consumption area burden relies on time-division multiplexing techniques in which read-out electronics are shared, either partially or totally, between channels while preserving the spatial and temporal resolution of the recordings. In this approach, shared elements have to operate over a shorter time slot per channel and active area is thus traded off against larger operating frequencies and signal bandwidths. As a result, power consumption is only mildly affected, although other performance metrics such as in-band noise or crosstalk may be degraded, particularly if the whole read-out circuit is multiplexed at the analog front-end input. In this article, we review the different implementation alternatives reported for time-division multiplexing neural recording systems, analyze their advantages and drawbacks, and suggest strategies for improving performance.

show abstract

Section: Neural Recording Afesmentioning

confidence: 99%

Recording Strategies for High Channel Count, Densely Spaced Microelectrode Arrays

Perez-Prieto

Delgado‐Restituto

2021

Front. Neurosci.

View full text Add to dashboard Cite

show abstract

“…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%

A 3rd Order Time Domain Delta Sigma Modulator with Extended-Phase Detection

Leene

Constandinou

2019

2019 IEEE International Symposium on Circuits and Systems (ISCAS)

Self Cite

View full text Add to dashboard Cite

This paper presents a novel analogue to digital converter using an oscillator-based loop filter for high-dynamic range bio-sensing applications. This is the first third-order feedforward ∆Σ modulator that strictly uses time domain integration for quantisation noise shaping. Furthermore we propose a new asynchronous extended-phase detection technique that increases the resolution of the 4 bit phase quantiser by another 5 bits to significantly improve both dynamic range and reduce the noiseshaping requirements. Preliminary simulation results show that this type of loop-filter can virtually prevent integrator saturation and achieves a peak 88 dB SNDR for kHz signals. The proposed system has been implemented using a 180 nm CMOS technology occupying 0.102 mm 2 and consumes 13.7 µW of power to digitise the 15 kHz signal bandwidth using a 2 MHz sampling clock.

show abstract

“…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%

A 3rd-Order FIR Filter Implementation Based on Time-Mode Signal Processing

Panetas-Felouris

Vlassis

2022

Electronics

View full text Add to dashboard Cite

This paper presents the hardware implementation of a 3rd-order low-pass finite impulse response (FIR) filter based on time-mode signal processing circuits. The filter topology consists of a set of novel building blocks that perform the necessary functions in time-mode including z−1 operation, time addition and time multiplication. The proposed time-mode low-pass FIR filter was designed in a 28 nm Samsung fully-depleted silicon-on-insulator FD-SOI process under 1 V supply voltage with 5 MHz sampling frequency. Simulation results validate the theoretical analysis. The FIR filter achieves a signal-to-noise-plus-distortion ratio (SNDR) of 38.6 dB at the input frequency of 50 KHz consuming around 200 μW.

show abstract

Time Domain Processing Techniques Using Ring Oscillator-Based Filter Structures

Cited by 32 publications

References 34 publications

Recording Strategies for High Channel Count, Densely Spaced Microelectrode Arrays

Recording Strategies for High Channel Count, Densely Spaced Microelectrode Arrays

A 3rd Order Time Domain Delta Sigma Modulator with Extended-Phase Detection

A 3rd-Order FIR Filter Implementation Based on Time-Mode Signal Processing

Contact Info

Product

Resources

About