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Digitally controlled oscillator

A digitally controlled oscillator (DCO) is an electronic oscillator whose output frequency is precisely adjusted by a digital input signal, often implemented using techniques such as capacitor banks, current-starved inverters, or LC tanks in integrated circuits to enable fine-grained frequency tuning without analog voltage dependencies.^[1] Unlike traditional voltage-controlled oscillators (VCOs), DCOs interface directly with digital logic, making them integral components in fully digital systems for generating stable clock signals or carrier frequencies.^[2] DCOs are widely employed in modern electronics, particularly in all-digital phase-locked loops (ADPLLs) for frequency synthesis, where they convert digital control words into corresponding oscillation frequencies to achieve high resolution and low phase noise.^[2] In wireless communication systems, such as RF transceivers, DCOs facilitate agile frequency hopping and modulation by supporting wide tuning ranges (e.g., up to ±3200 ppm) through digital interfaces like I²C or SPI, reducing susceptibility to analog noise and enabling integration in deep-submicron CMOS processes.^[1] Their architecture often incorporates ring oscillators or LC-based designs to balance power efficiency, jitter performance, and operational frequencies from MHz to multi-GHz ranges. Key advantages of DCOs include superior frequency resolution—potentially enhanced to sub-Hz levels via delta-sigma modulation—and elimination of external digital-to-analog converters (DACs), which lowers system cost and complexity in applications like system-on-chip (SoC) timing, network synchronizers, and software-defined radios.^[3] Hybrid DCO variants combine digital coarse tuning with analog fine adjustments to mitigate spurs from high-order modulators, achieving resolutions as fine as 1.4 MHz steps in 90 nm CMOS implementations while maintaining low power consumption.^[2] These features have made DCOs essential for advancing precision timing in portable devices, 5G infrastructure, and high-speed data converters.

Definition and Terminology

Basic Definition

A digitally controlled oscillator (DCO) is an electronic oscillator whose frequency is controlled by a digital input signal, such as a binary code or serial data stream, rather than an analog voltage.^[4] This digital control enables precise tuning in discrete steps, distinguishing it from analog alternatives like voltage-controlled oscillators (VCOs), which rely on continuous voltage variations.^[5] The primary function of a DCO is to generate periodic waveforms, such as sine, square, or triangle waves, with an output frequency that is proportional to the applied digital code.^[4] The frequency is typically adjusted by varying parameters like capacitance, current, or voltage digitally, often through mechanisms such as switched capacitor banks or digitally tunable current sources in the oscillator core.^[6] This results in stable, repeatable frequency steps without the drift associated with analog tuning elements. In electronic systems, DCOs serve as versatile components for generating adjustable and stable frequencies.^[7] For instance, in digital phase-locked loops (PLLs), DCOs provide the tunable oscillation needed for frequency synthesis and synchronization.^[4] A basic DCO structure involves a digital input fed into tuning logic, which modulates a frequency-determining element—such as a ring oscillator with varactors or a current-controlled oscillator—before producing the output waveform.^[6] This configuration ensures direct digital-to-frequency conversion, often integrated into integrated circuits for compact, low-power operation.^[7] A common point of confusion arises between digitally controlled oscillators (DCOs) and direct digital synthesis (DDS) techniques. DCOs employ digital control signals to tune an underlying oscillator core, which may be analog, hybrid, or fully digital (e.g., ring-based), producing continuous-time waveforms such as sawtooth or square waves directly from the oscillator circuitry.^[8] In contrast, DDS generates waveforms entirely in the digital domain using a phase accumulator, a lookup table storing waveform samples, and a digital-to-analog converter (DAC) to output the signal, enabling precise frequency synthesis but requiring post-filtering to remove spectral images.^[8] This fundamental difference means DCOs are suited for applications needing analog-like waveform purity with digital tuning stability, while DDS excels in flexible, arbitrary waveform generation at the cost of additional digital processing overhead.^[9] DCOs are also frequently distinguished from numerically controlled oscillators (NCOs), particularly in contexts like digital signal processing (DSP) and synthesizer design. NCOs are fully digital implementations that rely on a phase accumulator to increment a phase word at a fixed clock rate, generating output samples via table lookup or computation without analog elements.^[10] While DCOs often incorporate waveform generation circuits—analog, hybrid, or digital—tuned by digital inputs, such as switched capacitor banks, current sources, or delay elements in ring oscillators, NCOs operate entirely in discrete time, producing quantized outputs that may introduce aliasing unless mitigated by oversampling.^[11] This hybrid or digital nature of DCOs provides better integration with analog systems, whereas NCOs are preferred in pure digital environments like software-defined radios for their scalability and low power in CMOS processes.^[10] In phase-locked loops (PLLs), DCOs play a specialized role but remain distinct as independent frequency sources. A DCO can function as the tunable oscillator within an all-digital PLL (ADPLL), where digital feedback adjusts its frequency to synchronize with a reference, enabling applications like clock recovery in communications.^[12] However, unlike a full PLL, which includes phase detectors and loop filters for locking, a standalone DCO operates without such synchronization mechanisms, serving directly as a digitally tunable signal generator.^[13] This distinction is critical in designs where DCOs provide open-loop frequency agility, as in RF synthesizers, without the settling time overhead of PLL locking.^[12] The terminology surrounding DCOs has evolved significantly, particularly in synthesizer contexts versus modern integrated circuits (ICs). In the 1980s, "DCO" specifically denoted hybrid oscillators in polyphonic analog synthesizers, where digital counters divided a master clock to control analog waveform generators, ensuring tuning stability amid the push for multi-voice instruments like the Roland Juno series.^[10] This usage emphasized the analog core's role in producing organic tones, contrasting with emerging fully digital methods. In contemporary IC design, particularly for RF and SoCs, DCO broadly encompasses any digitally tunable oscillator, often fully integrated in deep-submicron CMOS without analog waveform shaping, reflecting a shift toward all-digital architectures in wireless applications. As of 2024, advancements include voltage-biased DCOs and dynamic element matching for enhanced performance in narrowband IoT.^[14]^[15] This broader modern interpretation sometimes leads to overlap with NCO terminology, but the original synthesizer-era definition persists in audio engineering discussions.^[10]

Historical Development

Origins and Relation to VCOs

In the pre-DCO era, voltage-controlled oscillators (VCOs) dominated electronics applications from the 1960s through the 1970s, relying on analog voltage inputs to tune oscillation frequency through mechanisms such as varactor diodes or reactance modulators that altered capacitance or reactance in response to the control signal.^[16] These designs, often built with discrete transistors, enabled electronic tuning in systems like radios and early synthesizers but were plagued by thermal drift—where temperature changes caused frequency instability—and inherent nonlinearity in the tuning response, leading to imprecise control and the need for manual adjustments.^[16]^[10] The motivation for developing digitally controlled oscillators (DCOs) arose in the late 1970s, driven by the demand for precise and stable tuning in emerging polyphonic synthesizers and digital systems, where multiple simultaneous voices required consistent pitch accuracy that analog VCOs could not reliably provide due to their sensitivity to environmental factors and component variations.^[10]^[17] This shift addressed the high costs and tuning instability of scaling VCO-based designs for polyphony, paving the way for more reliable integration with digital circuitry in musical instruments and communication devices.^[17] Early DCO implementations adopted a hybrid approach, augmenting traditional VCO cores with digital elements such as counters or frequency dividers to generate stepped control voltages or currents, thereby linearizing the tuning curve and mitigating the analog shortcomings of pure VCOs.^[10] This digitally augmented method improved stability by discretizing the control input, often derived from a master clock, to produce predictable frequency steps rather than continuous analog variations.^[17] The key transition from VCOs to DCOs involved replacing continuous analog control—where frequency is proportional to the input voltage—with discrete digital steps, significantly reducing sensitivity to temperature fluctuations, component aging, and nonlinearity while enhancing compatibility with digital processing environments.^[17]^[10] This evolution marked a foundational step toward fully digital oscillation techniques, prioritizing precision over the organic variability of analog methods.^[16]

Key Innovations and Milestones

The development of digitally controlled oscillators (DCOs) began in the 1970s with early concepts for digital tuning of LC oscillators appearing in patent literature and initial implementations aimed at improving stability over analog voltage-controlled oscillators (VCOs). One of the first practical applications emerged in laboratory equipment for generating stable signals, addressing tuning drift issues common in early electronic test gear. A notable milestone was the ARP Pro Soloist synthesizer in 1972, which incorporated digital control mechanisms for preset tuning, marking an early commercial use of DCO principles to achieve reliable pitch accuracy without constant manual adjustment.^[18] The 1980s synth boom propelled DCO adoption in musical instruments, driven by the need for temperature-stable polyphony in analog designs. Roland pioneered widespread use with the Juno-6 in 1982, featuring capacitor-switched DCOs that ensured consistent tuning across six voices. These innovations enabled affordable polyphonic synthesizers with minimal detuning, a significant leap from VCO-based predecessors. Oberheim integrated similar DCO designs in its Matrix series starting in the mid-1980s.^[19]^[20] By the 1990s, DCO technology shifted toward fully digital implementations within microcontrollers and digital signal processors (DSPs), enabling precise frequency synthesis in compact, programmable systems. This era saw the proliferation of single-chip DSPs, which incorporated all-digital DCOs for real-time signal generation and clocking, supporting emerging applications in embedded systems and early digital communications.^[21] In the late 1990s and 2000s, DCOs evolved significantly in radio-frequency (RF) applications, particularly within all-digital phase-locked loops (ADPLLs) for wireless communications. This transition facilitated integration in deep-submicron CMOS processes, improving frequency resolution and reducing phase noise for mobile and broadband systems.^[22] Advancements in the 2000s and 2010s focused on high-performance variants for wireless technologies, including MEMS-based DCOs that offered superior resilience over quartz crystals. SiTime's 2024 innovations integrated MEMS DCOs into phase-locked loops (PLLs) for AI datacenters and edge devices, achieving 10x better performance in size and jitter for next-generation timing. High-frequency DCOs emerged for 5G and software-defined radios, exemplified by a 2013 design reaching GHz ranges in portable form factors with low power consumption, facilitating mobile broadband deployments.^[23]^[24] Up to 2025, DCOs have seen integration in advanced communications infrastructure, including 5G enhancements for low-latency networks, while vintage synthesizer revivals underscore their enduring value for stability. Modern clones, such as Behringer's 2025 prototypes of 1980s polysynths, retain DCO architectures to replicate classic tones with improved reliability, appealing to producers seeking analog warmth without tuning issues.^[25]

Principles of Operation

Core Mechanisms

A digitally controlled oscillator (DCO) processes its input as a binary code or serial data stream loaded into a counter or register, which generates timing signals to modulate the oscillation period. These control signals, often in the form of pulse-width modulation (PWM) or switched current sources, directly influence the analog tuning elements to set the output frequency. In all-digital phase-locked loops (ADPLLs), the digital control bits (DCB) from the loop filter are synchronously retimed to minimize jitter before application to the oscillator core.^[12] For divider-based DCOs, the output frequency relates to the digital control word through the equation

f_\text{out} = f_\text{ref} \times \frac{N}{2^k},

where f_\text{ref} is the reference clock frequency, N is the integer digital control word (ranging from 0 to $2^k - 1), and k is the bit resolution of the control word, enabling precise fractional tuning relative to the reference. This formulation arises from the proportional scaling of the division ratio or tuning parameter by the normalized control value N / 2^k. Early capacitor-switched designs in 1980s synthesizers, such as those in the Korg Poly-800, employed similar countdown principles for stable pitch control.^[10] Tuning in DCOs relies on digital-to-analog conversion mechanisms to adjust the oscillator's resonant or timing characteristics. In LC-based DCOs, binary-weighted or thermometer-coded capacitor banks switch discrete capacitance values into the tank circuit, altering the resonance frequency f_\text{out} \approx \frac{1}{2\pi \sqrt{[LC](/page/LC)_\text{eff}}}, where C_\text{eff} varies with the control word. For relaxation-type DCOs, a current digital-to-analog converter (DAC) sets the charging current for a timing capacitor, modifying the oscillation period T_\text{out}, thus controlling the frequency via switched current steering.^[26]^[27] Phase stability in DCOs is enhanced through feedback loops, such as those in ADPLLs, where a time-to-digital converter (TDC) detects phase errors to fine-tune the control word, reducing accumulated timing deviations. Quantization inherent to the k-bit resolution produces discrete frequency steps, with the minimum resolvable frequency increment given by \Delta f = \frac{f_\text{out}}{2^k}, limiting continuous tuning but enabling deterministic behavior. Dithering techniques or high-resolution banks can mitigate spurs from this quantization noise.^[12] Waveform generation occurs in the analog core of the DCO, typically an op-amp integrator circuit that ramps a capacitor to produce fundamental shapes like sawtooth waves, with reset triggered by the digital counter overflow for synchronization. This hybrid approach ensures the output remains analog while inheriting digital timing precision, resulting in low phase jitter when clocked appropriately. In Walsh-Hadamard transform-based designs, the core sums digitally derived square waves via op-amp adders to approximate complex waveforms.^[10]

Implementation Variants

Hybrid analog DCOs integrate digital frequency control with analog waveform generation to achieve precise tuning while retaining analog signal characteristics. In these designs, a digital counter divides a master clock to produce a precise timing signal that resets an analog integrator circuit, effectively controlling the oscillator frequency without relying solely on voltage scaling. For instance, the Roland Juno series employs a programmable divider (using an Intel 8253 counter) to generate a square wave from an 8 MHz master clock, which triggers an op-amp integrator charging a capacitor to form a sawtooth wave, mimicking an RC-differentiator for stable pitch control across octaves.^[28] Alternatively, varactor diodes in the oscillator's tank circuit can be tuned by digital potentiometers, allowing binary-weighted capacitance adjustments for fine frequency resolution in hybrid RF applications.^[29] All-digital DCOs eliminate analog elements by relying entirely on digital hardware for frequency synthesis, offering high integration and immunity to analog imperfections. These architectures typically feature a phase accumulator—a high-bit-width adder and register—that increments by a digital tuning word each clock cycle, with overflows marking waveform periods; the accumulated phase then addresses a sine lookup table to generate discrete amplitude values for the output waveform.^[30] Optimized for hardware, such as in ASICs or FPGAs, they use counters and adders for efficient phase generation, enabling instantaneous frequency changes by updating the tuning word and supporting applications requiring compact, low-voltage operation. The output frequency is directly proportional to this digital input word. PLL-integrated DCOs embed the oscillator within a phase-locked loop for enhanced stability and noise rejection, commonly using ring oscillators or LC tanks tuned by digital varactors. In ring oscillator variants, delay stages are digitally controlled via switched capacitors or current sources to adjust propagation delay, while LC implementations employ binary-weighted capacitor banks as varactors for tank resonance tuning. For example, SiTime's MEMS-based DCOs provide fine frequency resolution down to ppb levels and spread-spectrum options in PLL-integrated architectures for clock generation up to 220 MHz.^[31] High-frequency variants extend DCO operation into the GHz regime through specialized tuning mechanisms like current-controlled delay lines or inductive elements, enabling portable, high-resolution synthesis. Current-controlled delay lines adjust oscillator frequency by varying bias currents in inverter chains, achieving fine steps via digital-to-analog conversion of control words. A 2013 portable DCO design utilizes a digital ring oscillator with novel shunt-capacitive loads that are electrically disconnected when disabled, supporting GHz frequencies with at least one octave tuning range and portability across CMOS processes, as demonstrated for applications including nuclear magnetic resonance systems.^[32] Software DCOs implement oscillator functionality through algorithms on programmable platforms like FPGAs or microcontrollers, prioritizing reconfigurability and low power for embedded systems. These typically emulate NCO behavior by digitally accumulating phase and generating samples via lookup tables or direct computation, integrated into software-defined radio pipelines for dynamic frequency agility. In FPGA realizations, optimized Verilog or VHDL modules handle phase accumulation and waveform output with minimal resource overhead, enabling duty-cycled operation to reduce power consumption below 1 mW in battery-constrained SDR transceivers.^[33]

Applications

In Audio Synthesis

In audio synthesis, digitally controlled oscillators (DCOs) serve as the foundational tunable carriers for generating periodic waveforms, such as sawtooth and pulse waves, which form the basis of subtractive synthesis pipelines. These waveforms are subsequently shaped by low-pass filters to remove unwanted high frequencies and modulated by amplitude envelopes to define attack, decay, sustain, and release characteristics, enabling the creation of dynamic timbres in synthesizers.^[34] A key advantage of DCOs in polyphonic instruments lies in their digital control mechanism, which maintains precise frequency synchronization across multiple voices without requiring individual analog tuning circuits for each oscillator, a common challenge in 1980s digital-analog hybrid synthesizers. This stability allows for reliable chord voicings and layered harmonies, reducing detuning issues that plagued voltage-controlled oscillators (VCOs) in polyphonic designs.^[35] The Roland Juno series, introduced in 1982 with models like the Juno-6 and Juno-60, exemplifies early DCO implementation in consumer synthesizers, employing 16-bit programmable counters derived from the Intel 8253 chip to achieve fine frequency steps as small as 0.2 cents at lower registers, ensuring intonation accuracy down to approximately 15 Hz. Modern revivals, such as Behringer's DeepMind 12 (2017) and the 2023 Neptune-80 prototype, replicate this architecture with enhanced digital precision for even greater long-term stability, preserving the Juno's characteristic warmth while mitigating aging component drift.^[28]^[36] Sonically, DCOs offer superior tuning consistency compared to traditional VCOs, producing clean, phase-locked outputs ideal for ensemble playing, though their digitally derived clock signals can impart a more uniform timbre lacking the subtle analog drift that adds organic expressiveness to VCO-generated sounds. In higher registers, while the analog waveshaping core retains rich harmonic content without the aliasing artifacts typical of fully digital oscillators, the fixed step resolution may introduce minor quantization in pitch bends.^[11] The evolution of DCO principles has extended into fully digital realms through virtual analog synthesizers, where software implementations emulate hybrid DCO behavior within digital audio workstations (DAWs) as of 2025, such as Cherry Audio's DCO-106 plugin, which models the Juno's oscillator response for polyphonic sound design with negligible hardware dependencies.

In Digital Systems and Communications

In digital systems, digitally controlled oscillators (DCOs) play a crucial role in clock generation for microcontrollers and system-on-chips (SoCs), enabling programmable frequencies through integration with all-digital phase-locked loops (ADPLLs) and frequency-locked loops (FLLs). These DCOs, often implemented as current-controlled oscillators (CCOs) tuned by multi-bit digital words, provide precise frequency steps without analog voltage control, facilitating scalable clock synthesis in CMOS processes. For instance, a 10-bit DCO in 180 nm CMOS achieves a tuning range from 90 kHz to 3.7 MHz with 1024 discrete frequencies, consuming 105 µW at 1 MHz, suitable for low-power digital clocking in embedded systems.^[27] In ADPLLs, the DCO serves as the core frequency generator, replacing traditional voltage-controlled oscillators to enable fully synthesizable designs that minimize analog noise and support integration in deep-submicron technologies.^[37] In communications, DCOs generate variable carrier frequencies for software-defined radios (SDRs) and 5G base stations, where high-resolution tuning supports dynamic modulation and upconversion in transceivers. A 4-bit DCO designed for SDR applications offers a wide tuning range with fast settling times, allowing reconfiguration of RF signals via digital control in resource-constrained platforms.^[38] For 5G, GHz-range DCOs enable over-an-octave tuning (20–60 GHz) in composite architectures, providing low phase noise for mm-wave upconversion and beamforming in base stations.^[39] High-frequency DCOs operating at 26.56 GHz, with power consumption under 2 mW, further support multi-gigabit wireless links by integrating digital calibration for linearity and noise reduction.^[40] Integration examples highlight DCO advancements in precision timing. SiTime's Endura SiT3541 MEMS-based DCO, introduced in 2020, delivers ultra-low jitter (70 fs RMS typical) for Ethernet clocks in networking SoCs, enabling sub-picosecond phase synchronization essential for high-speed data recovery in serial links.^[41] These devices support programmable pull ranges up to ±3200 ppm via digital interfaces like I²C, outperforming traditional VCXOs in jitter performance and integration density.^[3] By 2025, DCOs facilitate adaptive sampling in AI edge devices, where low-jitter clocks ensure precise timing for real-time inference in resource-limited environments like IoT sensors.^[3] Performance requirements emphasize sub-picosecond jitter (e.g., 220 fs RMS) for data recovery in serial links, achieved through DCOs in bang-bang digital PLLs that suppress phase noise in high-speed transceivers.

Advantages and Challenges

Benefits

Digitally controlled oscillators (DCOs) offer superior tuning precision and stability compared to traditional voltage-controlled oscillators (VCOs), primarily due to their digital control mechanisms that minimize environmental sensitivities such as temperature variations and voltage fluctuations. For instance, DCOs can achieve frequency stability as low as ±25 ppm/°C over a wide temperature range (-40°C to 85°C), significantly reducing drift that plagues analog VCOs, which often exhibit drifts exceeding 100 ppm due to thermal effects.^[42]^[43] This enhanced stability makes DCOs particularly suitable for multi-channel systems, where maintaining consistent frequency across multiple channels is essential without frequent retuning.^[3] DCOs excel in integration and scalability, leveraging CMOS-compatible designs that facilitate seamless incorporation into integrated circuits (ICs), thereby reducing overall component count and board space requirements. Unlike VCOs, which rely on analog components prone to noise coupling, DCOs eliminate the need for digital-to-analog converters (DACs), enabling direct digital interfacing and automation via microcontrollers for precise control.^[3]^[44] This compatibility with standard CMOS processes supports scalable production in modern electronics, from consumer devices to high-density systems. In terms of power consumption and cost, DCOs provide notable efficiencies by avoiding complex analog voltage regulators and associated circuitry, resulting in lower overall power draw—often in the range of microWatts for low-frequency applications—and enabling cost-effective mass production.^[45]^[44] DCOs demonstrate remarkable flexibility, supporting a broad frequency range from Hz to GHz through software reconfiguration, which allows dynamic adjustments without hardware modifications or extensive recalibration—contrasting with the rigid tuning of analog oscillators.^[3]^[46] Modern implementations further enhance this with high resolution, such as up to 32 bits in digitally tuned systems, enabling fine frequency steps on the order of kHz at GHz carriers for applications requiring sub-ppm accuracy.^[47]^[3]

Limitations and Design Issues

One major limitation of digitally controlled oscillators (DCOs) is quantization noise, arising from the discrete frequency steps imposed by digital control mechanisms such as capacitor banks or varactor arrays. These steps lead to frequency errors and spurious tones in the output spectrum, degrading signal purity. The noise power can be modeled as \sigma_f^2 = \frac{(\Delta f)^2}{12}, where \Delta f represents the frequency step size, following the variance of a uniform distribution over the quantization interval.^[48] Phase noise and jitter pose additional challenges in DCOs, primarily due to digital switching transients that introduce spurious components and timing variations. Hybrid DCO designs, which combine analog and digital elements, often exhibit higher phase noise compared to fully digital implementations, with typical performance targets around -100 dBc/Hz at a 1 kHz offset to meet communication standards.^[49] Linearity issues further complicate DCO design, particularly non-monotonic tuning behavior in switched capacitor banks, where frequency steps may overlap or reverse at segment boundaries, causing inconsistencies in control response. This non-linearity is commonly addressed through dithering techniques or sigma-delta modulation to average out irregularities and achieve finer, more uniform resolution.^[50] Speed limitations are critical in high-frequency applications, where digital control signals must settle rapidly to avoid phase perturbations; for GHz-range operations, settling times below 1 ns are often required to maintain accuracy during frequency hopping or modulation. Ring oscillator-based DCOs, while compact, suffer from power consumption spikes during switching, exacerbating thermal and efficiency issues at elevated frequencies.^[51] In audio synthesis contexts, aliasing manifests as harmonic distortion from the sharp edges of digitally generated waveforms, a prevalent issue in 1980s-era DCO implementations within synthesizers that lacked sufficient oversampling. Modern designs mitigate this through oversampling strategies, which push aliasing artifacts beyond the audible band and improve spectral cleanliness.^[10]

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[40]
A low-power 26.56-GHz LC-based DCO for multi-gigabit ...
This paper presents the design of a 26.56-GHz digitally controlled VCO (DCO). The circuit is powered at 1.2 V and consumes 1.94 mW.
[41]
A first multigigahertz digitally controlled oscillator for wireless ...
Aug 5, 2025 · A novel digitally controlled oscillator (DCO) architecture for multigigahertz wireless RF applications, such as short-range wireless ...
[42]
Designing and building a low-cost portable FT-NMR spectrometer in ...
This allows the portable FT-NMR spectrometer to work at low field (with a static permanent magnet) or at high frequency (with a superconducting magnet). 4.
[43]
A 25-ppm/°C, 9-bit linear 11–53 MHz Tunable, 5 μA ... - IEEE Xplore
The frequency stability is ±25-ppm/°C for the temperature range between -40 to 85 °C in off-chip resistor mode. This oscillator is implemented in 90nm CMOS ...
[44]
The Relationship Between Temperature and Stability
Sep 5, 2023 · The effects from shifts in temperature are more difficult to manage and causes frequency drift in tens of ppm, worsening for extreme ...Missing: DCO | Show results with:DCO
[45]
[PDF] Low Power CMOS Digitally Controlled Oscillator
With wide spread CMOS technology, use of digital integrated circuits has increased many folds for reasons of size, cost, flexibility and repeatability. Phase- ...
[46]
Digitally Controlled Oscillator with High Timing Resolution and Low ...
Feb 16, 2021 · This paper presents a digitally controlled oscillator (DCO) with a low-complexity circuit structure that combines multiple delay circuits to achieve a high ...
[47]
DIGITAL CONTROLLED OSCILLATOR (DCO) FOR ALL DIGITAL ...
Aug 6, 2025 · This paper presents a review of various CMOS DCO schemes implemented in ADPLL and relationship between the DCO parameters with ADPLL performance.
[48]
A low-phase noise 12 GHz digitally controlled oscillator in 65 nm ...
The low-power design achieves a phase noise performance of better than -112.3 dBc/Hz at a 1 MHz offset. In summary, the DCO achieves a best in class figure of ...Missing: advantages | Show results with:advantages
[49]
All-digital frequency synthesis with DCO gain calculation
For the BLUETOOTH application with the oscillating frequency in the RF band of 2.4 GHz and a frequency resolution of 1 kHz, at least 22 bits of DFC resolution ...
[50]
Quantization Effects in All-Digital Phase-Locked Loops - IEEE Xplore
Dec 31, 2007 · ... digitally controlled oscillator (DCO). The delta-sigma modulator ... A method for the estimation of all the quantization noise contributors is ...
[51]
04632907.pdf - IEEE Xplore
Ducommun Technologies (DCO) has served the aerospace, defense ... GHz, a PLL embedding the PCCS achieves phase noise around -100 dBc/Hz at 1-kHz offset.<|separator|>
[52]
A Digitally Controlled Injection-Locked Oscillator With Fine ...
Any misalignment will result in a non-linear and limited frequency tuning range and step size. The proper alignment is attained by setting the τc1 coarse ...Missing: diode thermal
[53]
A Low-Power Fast Settling 5.4—8.4 GHz Digitally Controlled ...
Based on a complementary -Gm LC cross-coupled topology, the DCO employs a 2-bit capacitor bank for course tuning as well as a varactor along with a 5-bit ...