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Όλ¬Έ (λ°μ¬)-- μμΈλνκ΅ λνμ : μ κΈ°Β·μ»΄ν¨ν°κ³΅νλΆ, 2017. 2. κΉμ¬ν.A PVT-insensitive-bandwidth PLL and a chirp frequency synthesizer PLL are proposed using a constant-relative-gain digitally-controlled oscillator (DCO), a constant-gain time-to-digital converter (TDC), and a simple digital loop filter (DLF) without an explicit calibration or additional circuit components.
A digital LC-PLL that realizes a PVT-insensitive loop bandwidth (BW) by using the constant-relative-gain LC-DCO and constant-gain TDC is proposed. In other words, based on ratiometric circuit designs, the LC-DCO can make a fixed percent change to its frequency for a unit change in its digital input and the TDC can maintain a fixed range and resolution measured in reference unit intervals (UIs) across PVT variations. With such LC-DCO and TDC, the proposed PLL can realize a bandwidth which is a constant fraction of the reference frequency even with a simple proportional-integral digital loop filter without any explicit calibration loops. The prototype digital LC-PLL fabricated in a 28-nm CMOS demonstrates a frequency range of 8.38~9.34 GHz and 652-fs,rms integrated jitter from 10-kHz to 1-GHz at 8.84-GHz while dissipating 15.2-mW and occupying 0.24-mm^2. Also, the PLL across three different die samples and supply voltage ranging from 1.0 to 1.2V demonstrates a nearly constant BW at 822-kHz with the variation of Β±4.25-% only.
A chirp frequency synthesizer PLL (FS-PLL) that is capable of precise triangular frequency modulation using type-III digital LC-PLL architecture for X-band FMCW imaging radar is proposed. By employing a phase-modulating two-point modulation (TPM), constant-gain TDC, and a simple second-order DLF with polarity-alternating frequency ramp estimator, the PLL achieves a gain self-tracking TPM realizing a frequency chirp with fast chirp slope (=chirp BW/chirp period) without increasing frequency errors around the turn-around points, degrading the effective resolution achievable. A prototype chirp FS-PLL fabricated in a 65nm CMOS demonstrates that the PLL can generate a precise triangular chirp profile centered at 8.9-GHz with 940-MHz bandwidth and 28.8-us period with only 1.9-MHz,rms frequency error including the turn-around points and 14.8-mW power dissipation. The achieved 32.63-MHz/us chirp slope is higher than that of FMCW FS-PLLs previously reported by 2.6x.CHAPTER 1 INTRODUCTION 1
1.1 MOTIVATION 1
1.2 THESIS ORGANIZATION 5
CHAPTER 2 CONVENTIONAL PHASE-LOCKED LOOP 7
2.1 CHARGE-PUMP PLL 7
2.1.1 OPERATING PRINCIPLE 7
2.1.2 LOOP DYNAMICS 9
2.2 DIGITAL PLL 10
2.2.1 OPERATING PRINCIPLE 11
2.2.2 LOOP DYNAMICS 12
CHAPTER 3 VARIATIONS ON PHASE-LOCKED LOOP 14
3.1 OSCILLATOR GAIN VARIATION 14
3.1.1 RING VOLTAGE-CONTROLLED OSCILLATOR 15
3.1.2 LC VOLTAGE-CONTROLLED OSCILLATOR 17
3.1.3 LC DIGITALLY-CONTROLLED OSCILLATOR 19
3.2 PHASE DETECTOR GAIN VARIATION 20
3.2.1 LINEAR PHASE DETECTOR 20
3.2.2 LINEAR TIME-TO-DIGITAL CONVERTER 21
CHAPTER 4 PROPOSED DCO AND TDC FOR CALIBRATION-FREE PLL 23
4.1 DIGTALLY-CONTROLLED OSCILLATOR (DCO) 25
4.1.1 OVERVIEW 24
4.1.2 CONSTANT-RELATIVE-GAIN DCO 26
4.2 TIME-TO-DIGITAL CONVERTER (TDC) 28
4.2.1 OVERVIEW 28
4.2.2 CONSTANT-GAIN TDC 30
CHAPTER 5 PVT-INSENSITIVE-BANDWIDTH PLL 35
5.1 OVERVIEW 36
5.2 PRIOR WORKS 37
5.3 PROPOSED PVT-INSENSITIVE-BANDWIDTH PLL 39
5.4 CIRCUIT IMPLEMENTATION 41
5.4.1 CAPACITOR-TUNED LC-DCO 41
5.4.2 TRANSFORMER-TUNED LC-DCO 45
5.4.3 OVERSAMPLING-BASED CONSTANT-GAIN TDC 49
5.4.4 PHASE DIGITAL-TO-ANALOG CONVERTER 52
5.4.5 DIGITAL LOOP FILTER 54
5.4.6 FREQUENCY DIVIDER 55
5.4.7 BANG-BANG PHASE-FREQUENCY DETECTOR 56
5.5 CELL-BASED DESIGN FLOW 57
5.6 MEASUREMENT RESULTS 58
CHAPTER 6 CHIRP FREQUENCY SYNTHESIZER PLL 66
6.1 OVERVIEW 67
6.2 PRIOR WORKS 71
6.3 PROPOSED CHIRP FREQUENCY SYNTHESIZER PLL 75
6.4 CIRCUIT IMPLEMENTATION 83
6.4.1 SECOND-ORDER DIGITAL LOOP FILTER 83
6.4.2 PHASE MODULATOR 84
6.4.3 CONSTANT-GAIN TDC 85
6.4.4 VRACTOR-BASED LC-DCO 87
6.4.5 OVERALL CLOCK CHAIN 90
6.5 MEASUREMENT RESULTS 91
6.6 SIGNAL-TO-NOISE RATIO OF RADAR 98
CHAPTER 7 CONCLUSION 100
BIBLIOGRAPHY 102
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