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Noise shaping Asynchronous SAR ADC based time to digital converter
Time-to-digital converters (TDCs) are key elements for the digitization of timing information in modern mixed-signal circuits such as digital PLLs, DLLs, ADCs, and on-chip jitter-monitoring circuits. Especially, high-resolution TDCs are increasingly employed in on-chip timing tests, such as jitter and clock skew measurements, as advanced fabrication technologies allow fine on-chip time resolutions. Its main purpose is to quantize the time interval of a pulse signal or the time interval between the rising edges of two clock signals. Similarly to ADCs, the performance of TDCs are also primarily characterized by Resolution, Sampling Rate, FOM, SNDR, Dynamic Range and DNL/INL. This work proposes and demonstrates 2nd order noise shaping Asynchronous SAR ADC based TDC architecture with highest resolution of 0.25 ps among current state of art designs with respect to post-layout simulation results. This circuit is a combination of low power/High Resolution 2nd Order Noise Shaped Asynchronous SAR ADC backend with simple Time to Amplitude converter (TAC) front-end and is implemented in 40nm CMOS technology. Additionally, special emphasis is given on the discussion on various current state of art TDC architectures.Electrical and Computer Engineerin
Modular Acquisition and Stimulation System for Timestamp-Driven Neuroscience Experiments
Dedicated systems are fundamental for neuroscience experimental protocols
that require timing determinism and synchronous stimuli generation. We
developed a data acquisition and stimuli generator system for neuroscience
research, optimized for recording timestamps from up to 6 spiking neurons and
entirely specified in a high-level Hardware Description Language (HDL). Despite
the logic complexity penalty of synthesizing from such a language, it was
possible to implement our design in a low-cost small reconfigurable device.
Under a modular framework, we explored two different memory arbitration schemes
for our system, evaluating both their logic element usage and resilience to
input activity bursts. One of them was designed with a decoupled and latency
insensitive approach, allowing for easier code reuse, while the other adopted a
centralized scheme, constructed specifically for our application. The usage of
a high-level HDL allowed straightforward and stepwise code modifications to
transform one architecture into the other. The achieved modularity is very
useful for rapidly prototyping novel electronic instrumentation systems
tailored to scientific research.Comment: Preprint submitted to ARC 2015. Extended: 16 pages, 10 figures. The
final publication is available at link.springer.co
ํต๊ณ์ ์ฃผํ์ ๊ฒ์ถ๊ธฐ ๊ธฐ๋ฐ ๊ธฐ์ค ์ฃผํ์๋ฅผ ์ฌ์ฉํ์ง ์๋ ํด๋ก ๋ฐ ๋ฐ์ดํฐ ๋ณต์ ํ๋ก์ ์ค๊ณ ๋ฐฉ๋ฒ๋ก
ํ์๋
ผ๋ฌธ(๋ฐ์ฌ) -- ์์ธ๋ํ๊ต๋ํ์ : ๊ณต๊ณผ๋ํ ์ ๊ธฐยท์ ๋ณด๊ณตํ๋ถ, 2022. 8. ์ ๋๊ท .In this thesis, a design of a high-speed, power-efficient, wide-range clock and data recovery (CDR) without a reference clock is proposed. A frequency acquisition scheme using a stochastic frequency detector (SFD) based on the Alexander phase detector (PD) is utilized for the referenceless operation. Pat-tern histogram analysis is presented to analyze the frequency acquisition behavior of the SFD and verified by simulation. Based on the information obtained by pattern histogram analysis, SFD using autocovariance is proposed. With a direct-proportional path and a digital integral path, the proposed referenceless CDR achieves frequency lock at all measurable conditions, and the measured frequency acquisition time is within 7ฮผs. The prototype chip has been fabricated in a 40-nm CMOS process and occupies an active area of 0.032 mm2. The proposed referenceless CDR achieves the BER of less than 10-12 at 32 Gb/s and exhibits an energy efficiency of 1.15 pJ/b at 32 Gb/s with a 1.0 V supply.๋ณธ ๋
ผ๋ฌธ์ ๊ธฐ์ค ํด๋ญ์ด ์๋ ๊ณ ์, ์ ์ ๋ ฅ, ๊ด๋์ญ์ผ๋ก ๋์ํ๋ ํด๋ญ ๋ฐ ๋ฐ์ดํฐ ๋ณต์ํ๋ก์ ์ค๊ณ๋ฅผ ์ ์ํ๋ค. ๊ธฐ์ค ํด๋ญ์ด ์๋ ๋์์ ์ํด์ ์๋ ์ฐ๋ ์์ ๊ฒ์ถ๊ธฐ์ ๊ธฐ๋ฐํ ํต๊ณ์ ์ฃผํ์ ๊ฒ์ถ๊ธฐ๋ฅผ ์ฌ์ฉํ๋ ์ฃผํ์ ํ๋ ๋ฐฉ์์ด ์ฌ์ฉ๋๋ค. ํต๊ณ์ ์ฃผํ์ ๊ฒ์ถ๊ธฐ์ ์ฃผํ์ ์ถ์ ์์์ ๋ถ์ํ๊ธฐ ์ํด ํจํด ํ์คํ ๊ทธ๋จ ๋ถ์ ๋ฐฉ๋ฒ๋ก ์ ์ ์ํ์๊ณ ์๋ฎฌ๋ ์ด์
์ ํตํด ๊ฒ์ฆํ์๋ค. ํจํด ํ์คํ ๊ทธ๋จ ๋ถ์์ ํตํด ์ป์ ์ ๋ณด๋ฅผ ๋ฐํ์ผ๋ก ์๊ธฐ๊ณต๋ถ์ฐ์ ์ด์ฉํ ํต๊ณ์ ์ฃผํ์ ๊ฒ์ถ๊ธฐ๋ฅผ ์ ์ํ๋ค. ์ง์ ๋น๋ก ๊ฒฝ๋ก์ ๋์งํธ ์ ๋ถ ๊ฒฝ๋ก๋ฅผ ํตํด ์ ์๋ ๊ธฐ์ค ํด๋ญ์ด ์๋ ํด๋ญ ๋ฐ ๋ฐ์ดํฐ ๋ณต์ํ๋ก๋ ๋ชจ๋ ์ธก์ ๊ฐ๋ฅํ ์กฐ๊ฑด์์ ์ฃผํ์ ์ ๊ธ์ ๋ฌ์ฑํ๋ ๋ฐ ์ฑ๊ณตํ์๊ณ , ๋ชจ๋ ๊ฒฝ์ฐ์์ ์ธก์ ๋ ์ฃผํ์ ์ถ์ ์๊ฐ์ 7ฮผs ์ด๋ด์ด๋ค. 40-nm CMOS ๊ณต์ ์ ์ด์ฉํ์ฌ ๋ง๋ค์ด์ง ์นฉ์ 0.032 mm2์ ๋ฉด์ ์ ์ฐจ์งํ๋ค. ์ ์ํ๋ ํด๋ญ ๋ฐ ๋ฐ์ดํฐ ๋ณต์ํ๋ก๋ 32 Gb/s์ ์๋์์ ๋นํธ์๋ฌ์จ 10-12 ์ดํ๋ก ๋์ํ์๊ณ , ์๋์ง ํจ์จ์ 32Gb/s์ ์๋์์ 1.0V ๊ณต๊ธ์ ์์ ์ฌ์ฉํ์ฌ 1.15 pJ/b์ ๋ฌ์ฑํ์๋ค.CHAPTER 1 INTRODUCTION 1
1.1 MOTIVATION 1
1.2 THESIS ORGANIZATION 13
CHAPTER 2 BACKGROUNDS 14
2.1 CLOCKING ARCHITECTURES IN SERIAL LINK INTERFACE 14
2.2 GENERAL CONSIDERATIONS FOR CLOCK AND DATA RECOVERY 24
2.2.1 OVERVIEW 24
2.2.2 JITTER 26
2.2.3 CDR JITTER CHARACTERISTICS 33
2.3 CDR ARCHITECTURES 39
2.3.1 PLL-BASED CDR โ WITH EXTERNAL REFERENCE CLOCK 39
2.3.2 DLL/PI-BASED CDR 44
2.3.3 PLL-BASED CDR โ WITHOUT EXTERNAL REFERENCE CLOCK 47
2.4 FREQUENCY ACQUISITION SCHEME 50
2.4.1 TYPICAL FREQUENCY DETECTORS 50
2.4.1.1 DIGITAL QUADRICORRELATOR FREQUENCY DETECTOR 50
2.4.1.2 ROTATIONAL FREQUENCY DETECTOR 54
2.4.2 PRIOR WORKS 56
CHAPTER 3 DESIGN OF THE REFERENCELESS CDR USING SFD 58
3.1 OVERVIEW 58
3.2 PROPOSED FREQUENCY DETECTOR 62
3.2.1 MOTIVATION 62
3.2.2 PATTERN HISTOGRAM ANALYSIS 68
3.2.3 INTRODUCTION OF AUTOCOVARIANCE TO STOCHASTIC FREQUENCY DETECTOR 75
3.3 CIRCUIT IMPLEMENTATION 83
3.3.1 IMPLEMENTATION OF THE PROPOSED REFERENCELESS CDR 83
3.3.2 CONTINUOUS-TIME LINEAR EQUALIZER (CTLE) 85
3.3.3 DIGITALLY-CONTROLLED OSCILLATOR (DCO) 87
3.4 MEASUREMENT RESULTS 89
CHAPTER 4 CONCLUSION 99
APPENDIX A DETAILED FREQUENCY ACQUISITION WAVEFORMS OF THE PROPOSED SFD 100
BIBLIOGRAPHY 108
์ด ๋ก 122๋ฐ
A Low Energy FPGA Platform for Real-Time Event-Based Control
We present a wireless sensor node suitable for event-based real-time control networks. The node achieves low-power operation thanks to tight clock synchronisation with the network master (at present we refer to a star network but extensions are envisaged). Also, the node does not employ any programmable device but rather an FPGA, thus being inherently immune to attacks based on code tampering. Experimental results on a simple laboratory apparatus are presented
The Deep Space Network. An instrument for radio navigation of deep space probes
The Deep Space Network (DSN) network configurations used to generate the navigation observables and the basic process of deep space spacecraft navigation, from data generation through flight path determination and correction are described. Special emphasis is placed on the DSN Systems which generate the navigation data: the DSN Tracking and VLBI Systems. In addition, auxiliary navigational support functions are described
Panoramic-reconstruction temporal imaging for seamless measurements of slowly-evolved femtosecond pulse dynamics
Single-shot real-time characterization of optical waveforms with
sub-picosecond resolution is essential for investigating various ultrafast
optical dynamics. However, the finite temporal recording length of current
techniques hinders comprehensive understanding of many intriguing ultrafast
optical phenomena that evolve over a time scale much longer than their fine
temporal details. Inspired by the space-time duality and by stitching of
multiple microscopic images to achieve a larger field of view in the spatial
domain, here a panoramic-reconstruction temporal imaging (PARTI) system is
devised to scale up the temporal recording length without sacrificing the
resolution. As a proof-of-concept demonstration, the PARTI system is applied to
study the dynamic waveforms of slowly-evolved dissipative Kerr solitons in an
ultrahigh-Q microresonator. Two 1.5-ns-long comprehensive evolution portraits
are reconstructed with 740-fs resolution and dissipative Kerr soliton
transition dynamics, in which a multiplet soliton state evolves into stable
singlet soliton state, are depicted
System architecture study of an orbital GPS user terminal
The generic RF and applications processing requirements for a GPS orbital navigator are considered. A line of demarcation between dedicated analog hardware, and software/processor implementation, maximizing the latter is discussed. A modular approach to R/PA design which permits several varieties of receiver to be constructed from basic components is described. It is a basic conclusion that software signal processing of the output of the baseband correlator is the best choice of transition from analog to digital signal processing. High performance sets requiring multiple channels are developed from a generic design by replicating the RF processing segment, and modifying the applications software to provide enhanced state propagation and estimation
The S2 VLBI Correlator: A Correlator for Space VLBI and Geodetic Signal Processing
We describe the design of a correlator system for ground and space-based
VLBI. The correlator contains unique signal processing functions: flexible LO
frequency switching for bandwidth synthesis; 1 ms dump intervals, multi-rate
digital signal-processing techniques to allow correlation of signals at
different sample rates; and a digital filter for very high resolution
cross-power spectra. It also includes autocorrelation, tone extraction, pulsar
gating, signal-statistics accumulation.Comment: 44 pages, 13 figure
D2.1 - Report on Selected TRNG and PUF Principles
This report represents the final version of Deliverable 2.1 of the HECTOR work package WP2. It is a result of discussions and work on Task 2.1 of all HECTOR partners involved in WP2. The aim of the Deliverable 2.1 is to select principles of random number generators (RNGs) and physical unclonable functions (PUFs) that fulfill strict technology, design and security criteria. For example, the selected RNGs must be suitable for implementation in logic devices according to the German AIS20/31 standard. Correspondingly, the selected PUFs must be suitable for applying similar security approach. A standard PUF evaluation approach does not exist, yet, but it should be proposed in the framework of the project. Selected RNGs and PUFs should be then thoroughly evaluated from the point of view of security and the most suitable principles should be implemented in logic devices, such as Field Programmable Logic Arrays (FPGAs) and Application Specific Integrated Circuits (ASICs) during the next phases of the project
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