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Current-mode logic

Current-mode logic (CML), also known as source-coupled logic (SCL), is a differential digital logic family that performs logic operations by steering a constant tail current between paired transistors, rather than relying on voltage level swings, to achieve high-speed signaling with inherent common-mode noise rejection. This architecture typically features a differential pair biased by a tail current source and load resistors, producing output swings proportional to the current times resistance product, often around 800 mV differentially. CML operates at data rates exceeding 10 Gbps in advanced processes, making it suitable for point-to-point interfaces. The origins of CML are rooted in (ECL) from the 1960s, with adaptations for technologies emerging in the late 1970s and 1980s to enable nanosecond delays in NMOS VLSI circuits. Early implementations, such as those described in 1981, demonstrated speed-power products as low as 1.5 pJ using reference-biased gates for high-density integration. By the , CML gained prominence in gigahertz MOS pipelines and mixed-signal designs, evolving into MOS current-mode logic (MCML) for reduced supply voltages. CML offers several advantages over voltage-mode logics, including lower propagation delays, higher , and robustness against supply and variations due to its . However, it consumes higher static power and requires precise current sources, often mitigated by inductive peaking or adaptive in modern designs. It is widely applied in high-speed serial links like , clock-and-data recovery circuits, voltage-controlled oscillators (VCOs), and multi-gigabit interfaces such as .

Introduction

Definition and Overview

Current-mode logic (CML), also known as source-coupled logic (SCL), is a logic style that encodes states (logic 0 or 1) by steering a supplied by a tail between two complementary paths in a pair. This current-steering mechanism allows the logic to operate with small voltage swings, typically on the order of hundreds of millivolts, while maintaining a constant total current flow. The core operational paradigm relies on the pair to direct nearly all of the tail to one branch or the other based on the input voltage, thereby representing logic levels without large voltage transitions. Key components of a basic CML gate include the differential transistor pair (implemented using field-effect transistors (FETs) or bipolar junction transistors (BJTs)), load resistors (or active loads) connected to the outputs, and the tail that provides a bias-independent . The load elements convert the steered current differences into small voltage variations across the outputs, which can then drive subsequent stages. This architecture ensures balanced operation and inherent common-mode rejection, contributing to its noise resilience. In contrast to voltage-mode logic families like complementary metal-oxide-semiconductor (), where binary states are represented by switching full voltage levels (e.g., from to supply rail) and is primarily dynamic, CML emphasizes directionality with minimal voltage swing, leading to constant static dissipation but reduced switching noise and supply bouncing. CML's design is particularly suitable for high-speed digital gates in integrated circuits and board-level signaling interfaces, such as those in multi-gigabit serial data links, where its low-impedance outputs and tolerance to interconnect variations enable reliable operation at data rates exceeding 10 Gbps.

Historical Development

Current-mode logic traces its origins to (ECL), a transistor-based family developed in the 1950s for high-speed applications. ECL was invented in 1956 by Hannon S. Yourke at , initially known as current-steering logic, and first deployed in systems like the IBM 7090 and 7094 computers in the early 1960s. This logic family achieved speeds up to tens of megahertz by avoiding saturation and using small voltage swings, but its foundation limited integration density compared to emerging technologies. The evolution toward MOS-compatible current-mode logic (CML) began in the early 1980s, with initial publications on current-mode circuits, including DC analyses and layout systems for LSI chips, to address the need for high-speed circuits in VLSI processes. The foundational work on MOS current-mode logic (MCML) was presented in Z. Tang's 1988 PhD thesis at , which explored MCML circuits as a , low-swing alternative to static for reducing power and noise in integrated systems. A seminal advancing MCML for gigahertz applications appeared in 1996, introducing an adaptive pipeline technique using MCML gates that compensated for process variations while achieving 1 GHz operation in 0.5 μm . During the 1990s, CML gained traction in deep submicron processes, where ECL faced scaling challenges like increased parasitics and integration costs; for instance, B. Razavi's 1995 design of a 2.4 GHz in 0.1 μm highlighted CML's suitability for low-voltage, high-speed phase-locked loops. By the early 2000s, adaptations like subthreshold MCML emerged to enable ultra-low-power operation, with a 2008 study demonstrating robust MCML gates using novel load devices that maintained functionality at supply voltages below 0.5 V and bias currents under 1 μA, targeting wireless sensor networks. This period marked CML's shift from niche high-speed roles to broader VLSI integration, driven by scaling benefits. As of 2025, developments have integrated CML into advanced nodes like 5 nm FinFET for accelerators and 100+ Gbps , exemplified by a 2024 inductorless CML divider operating from 2.9 to 45.9 GHz in 65 nm for high-speed applications, enabling low-jitter performance in data-center interconnects.

Principles of Operation

Basic Circuit Structure

The basic circuit structure of a current-mode logic (CML) gate, exemplified by a or inverter, features a pair of s, typically NMOS devices and M2, with their sources tied together and connected to a tail I_{SS} provided by a operating in . The drains of M1 and M2 connect to load resistors R_D, which are coupled to the positive supply voltage V_{DD}. inputs are applied to the gates of M1 and M2, while outputs are extracted from the drains, enabling current steering rather than voltage switching for logic operation. The tail current source ensures a constant I_{SS}, typically ranging from 0.5 to 5 mA depending on the technology and performance requirements, with the tail biased to maintain for stable current delivery independent of input variations. Differential inputs steer I_{SS} between the branches: a positive differential voltage favors current flow through one (e.g., M1), increasing the voltage drop across its load and producing complementary outputs, while the common-mode input level is set to keep the pair in the . This biasing configuration minimizes supply dependence and supports high-speed operation by avoiding full rail-to-rail voltage transitions. The differential output voltage swing \Delta V_{out} is determined by \Delta V_{out} = I_{SS} \times R_D. To derive this, consider a large positive differential input that fully steers I_{SS} through M1, with negligible current through M2; the drain voltage of M1 then drops to V_{DD} - I_{SS} R_D, while the drain of M2 stays near V_{DD}, yielding a peak-to-peak differential swing of I_{SS} R_D. For smaller inputs, the swing scales with the degree of current steering, but the maximum remains supply-independent as long as the output common-mode voltage stays within the dynamic range. CML designs often align the output common-mode level (around V_{DD} - 1.3 V) for compatibility with Positive Emitter-Coupled Logic (PECL), enabling straightforward single-ended interfacing via resistors or AC coupling without complex level shifters. In general, the common-mode voltage is V_{DD} - (I_{SS} R_D / 2). Parasitic capacitances at the output nodes, including drain-to-bulk (C_{DB}) and gate-to-source (C_{GS}) components, contribute to the total load and limit by increasing the with R_D. Gate-drain capacitance (C_{GD}) exacerbates this through the , often countered by adding neutralization capacitors across the differential pair to cancel feedforward coupling. These parasitics necessitate careful sizing of R_D and widths to balance speed and power.

Logic Implementation and Signal Characteristics

In current-mode logic (CML), basic logic functions such as AND and OR are realized through current summing in the differential pull-down network. Multiple input differential pairs are connected in parallel, where the tail currents from each pair are steered based on their respective inputs, and the summed currents flow through shared load resistors to produce the output voltage . This approach allows for multi-input without stacking transistors, maintaining the constant tail current and enabling high-speed operation. For example, a two-input sums the currents from two differential pairs, with the output determined by the minimum input condition due to the steering mechanism. XOR gates in CML are implemented using additional differential pairs to achieve the required cross-coupling. Typically, this involves two pairs: one pair controlled by inputs A and its complement, and another by B and its complement, with outputs taken from the differential nodes to produce the XOR function. The steering of the tail I_SS in each pair ensures that the output current reflects the exclusive-or condition, converting to voltage via the load resistors R_D. This configuration provides both true and complementary outputs, facilitating further logic chaining. CML employs fully signaling, generating both true (Q) and complementary (Q̅) outputs from inputs. This balanced ensures that the common-mode voltage remains stable, as any common-mode variations affect both output branches equally and are rejected by subsequent stages. The stability of the common-mode voltage is maintained by the constant tail and symmetric load resistors, yielding a common-mode voltage of V_{DD} - (I_{SS} R_D / 2). High common-mode rejection arises from the nature, providing rejection ratios often exceeding 40 dB, which suppresses and effectively. Signal characteristics in CML include a low differential voltage swing, typically ranging from 100 mV to 500 mV, which reduces power dissipation and while allowing operation at high frequencies. The output voltage is given by ΔV_out = I_SS · R_D, where the small swing minimizes capacitive loading effects. This low swing, combined with the , enables high common-mode rejection, making CML suitable for noise-sensitive environments. The propagation delay τ_pd in CML gates is approximated by the time constant of the output network, τ_pd ≈ R_D · C_L, where R_D is the load and C_L is the total load at the output . To derive this, consider a step input that fully steers the tail current I_SS to one branch, causing an change in the output voltage: V_out(t) = V_CM + (ΔV_out / 2) · (1 - e^{-t / (R_D C_L)}), where V_CM is the common-mode voltage and ΔV_out = I_SS · R_D. The delay is defined as the time for the output to reach 50% of its final swing, yielding τ_pd = ln(2) · R_D · C_L ≈ 0.69 · R_D · C_L; however, for small-signal analysis and simplified modeling, the approximation τ_pd ≈ R_D · C_L captures the dominant pole and provides accurate estimates with errors below 9% in 65-nm processes. This model averages small-signal parameters between logic high and low states for precision across gate types. Waveforms in CML operation feature a differential input voltage that modulates the gate-source voltages of the input transistors, steering the tail current I_SS between the two branches of the pair. When the input is positive, I_SS flows primarily through one branch, producing a across the corresponding load and generating a negative-going output on that side, while the complementary output rises. The output waveform is then a current-to-voltage conversion via the loads, resulting in small-swing pulses with fast rise/fall times determined by the . CML gates exhibit unity voltage gain due to their differential transconductance and load , allowing direct chaining without but requiring consideration of . To drive multiple loads or maintain over longer paths, unity-gain buffers—essentially source-follower or simple differential amplifiers—are inserted, preserving the low swing and common-mode level while isolating capacitive loads. This buffering prevents delay degradation from excessive , typically limited to 4-8 loads in high-speed designs.

Variants and Implementations

MOS Current-Mode Logic

MOS Current-Mode Logic (MCML) implements current-mode logic using standard transistors, featuring an NMOS differential pair whose sources are tied to a tail for steering the bias current based on inputs. The drains of this pair connect to PMOS active loads biased to operate in the region, functioning as tunable resistors that replace passive loads in earlier designs for enhanced swing control and process compatibility. This configuration ensures flow, with the differential output voltage determined by the current split between the branches, providing low-noise, high-speed operation in CMOS environments. Transistor sizing in MCML emphasizes matching to optimize current steering and minimize offsets, with the NMOS differential pair transistors designed to have identical W/L ratios—such as 720 nm/180 nm in a —for symmetric and balanced operation. The PMOS loads are scaled with larger widths relative to lengths to achieve the desired effective R_D, while the tail NMOS , often with a longer channel like 720 nm/720 nm, sets the total bias current I_{SS} through its gate bias voltage V_{\text{bias}}, ensuring high and stable current independent of input swings. These ratios allow trade-offs between speed, power, and area, with non-minimum lengths reducing short-channel effects and improving matching. The logic threshold V_{\text{th}} in an MCML differential pair represents the input condition for balanced current steering, expressed as V_{\text{th}} = \frac{V_{\text{GS1}} + V_{\text{GS2}}}{2}, where V_{\text{GS1}} and V_{\text{GS2}} are the gate-source voltages of the NMOS pair at , ideally equal for zero input. Mismatch effects, including variations \Delta V_{\text{th}} and differences in or thickness, introduce an input-referred offset approximately \Delta V_{\text{th}} / \sqrt{2}, shifting the transfer curve and causing partial steering even at nominal inputs. This offset amplifies in cascaded gates, degrading margins; mitigation involves larger areas to reduce mismatch variance per Pelgrom's model, where standard deviation scales as $1 / \sqrt{WL}. MCML benefits from full compatibility with standard fabrication processes, utilizing only enhancement-mode transistors without the specialized junctions required for (), enabling seamless integration in fabs. This process alignment reduces costs and supports mixed-signal designs. Compared to CML variants, MCML achieves smaller die area due to the compact structure—lacking base-emitter junctions—and efficient layout, with gates occupying up to 9% less space than equivalent static blocks in near-threshold regimes while maintaining high density. Variability in MCML arises primarily from process-induced fluctuations in threshold voltage V_{\text{th}}, which disrupt precise current steering by altering the NMOS pair's conduction balance and leading to uneven I_{SS} distribution. In PVT analysis using 180 nm corners (e.g., slow-slow, fast-fast), V_{\text{th}} shifts of ±50 mV can increase bias current by up to 30% and reduce output swing by 28%, exacerbating power variations and timing skews in high-speed chains. These effects are unique to MOS implementations, as short-channel variations amplify V_{\text{th}} ; countermeasures include oversized channels for lower mismatch density and layout symmetries like common-centroid placement to equalize gradients.

Subthreshold and Low-Power Variants

Subthreshold current-mode logic (STSCL), also known as subthreshold source-coupled logic, adapts conventional current-mode logic circuits for ultra-low-power operation by biasing transistors in the weak inversion regime, where the gate-source voltage V_{GS} is below the V_{th}. This enables gate currents as low as 10-100 , significantly reducing static power dissipation while maintaining signaling. In subthreshold operation, the drain-source current I_{DS} of a follows an relationship derived from the EKV charge-based model: I_{DS} = I_0 \exp\left(\frac{V_{GS} - V_{th}}{n V_T}\right) \left(1 - \exp\left(-\frac{V_{DS}}{V_T}\right)\right), where I_0 is the specific current (technology-dependent, typically ~1 μA for minimum ), n is the factor (1.3-2), and V_T = kT/[q](/page/Q) \approx 26 at is the thermal voltage. For V_{DS} \gg V_T (), the equation simplifies to I_{DS} \approx I_0 \exp\left((V_{GS} - V_{th})/(n V_T)\right). In an STSCL pair, a tail bias I_{SS} (picoamperes range) is steered between the two branches based on the input voltage \Delta V = V_{GS1} - V_{GS2}. The branch are: I_1 = \frac{I_{SS}}{1 + \exp\left(-\frac{\Delta V}{n V_T}\right)}, \quad I_2 = \frac{I_{SS} \exp\left(-\frac{\Delta V}{n V_T}\right)}{1 + \exp\left(-\frac{\Delta V}{n V_T}\right)}. This splitting ensures high steering efficiency, where for |\Delta V| > 4 n V_T, over 99% of I_{SS} is directed to one branch, enabling reliable logic switching with minimal input swing (~100-200 ). The output voltage swing V_{sw} = I_{SS} R_L (with load R_L) must exceed $4 n V_T (~200-300 ) to propagate signals effectively to the next stage. Power reduction in STSCL leverages the low I_{SS} for static savings, augmented by techniques like dynamic biasing, where I_{SS} is adjusted via a variable to match demands, linearly scaling and . Duty intermittently activates circuits during phases, minimizing by exploiting the low standby leakage (subthreshold current dominates but remains in picoamperes). at the gate level, as in PG-STSCL, inserts sleep transistors to cut I_{SS} entirely during idle periods, addressing residual leakage without performance overhead upon wakeup. These methods yield energy efficiencies orders of magnitude better than standard in standby, ideal for always-on sensors. Despite these benefits, STSCL trades speed for power: operating frequencies drop from GHz in nominal CML to MHz (e.g., 1-10 MHz at 0.5-0.8 V), limited by the low transconductance g_m = I_{SS}/(n V_T). It also exhibits heightened sensitivity to noise, process mismatch, and temperature variations, as the exponential current dependence amplifies small perturbations (e.g., 1 mV input noise can cause ~10% current error), necessitating careful sizing and calibration. STSCL was proposed in the mid-2000s for ultra-low-power digital systems, with seminal work introducing novel PMOS loads for enhanced low-current performance. It has since evolved for and wearable applications, incorporating power-gated variants and integration in mixed-signal designs, though specific 28 nm implementations remain focused on broader subthreshold optimizations rather than STSCL-exclusive advances.

Performance Characteristics

Advantages in Speed and Noise

Current-mode logic (CML) achieves high-speed operation primarily through its small differential voltage swing, typically around 800 mV, which is determined by the product of the tail current I_{SS} and load R_D (\Delta V = I_{SS} R_D). This reduced swing minimizes the associated with charging parasitic capacitances, enabling bandwidths exceeding 10 GHz in applications such as frequency dividers and serial I/O interfaces. For instance, CML-based circuits have demonstrated operation at 10 Gb/s with low propagation delays. The propagation delay of a CML stage is given by t_d = 0.69 R_D (C_{par}), where C_{par} represents the total parasitic capacitance at the output node, making the delay largely independent of the supply voltage V_{DD} as long as the bias current remains constant. This characteristic allows CML to maintain consistent high-speed performance across varying supply conditions, unlike voltage-mode logics where delay scales with V_{DD}. The maximum operating frequency is fundamentally limited by the bandwidth of the differential pair, approximately f_{max} \approx 1/(2\pi R_D C_{par}), further emphasizing the role of optimized load and parasitics in achieving multi-GHz speeds. In terms of noise resilience, CML's fully architecture inherently rejects common-mode noise, including and supply-induced variations, providing robust in noisy environments. This differential operation yields a high (PSRR), typically greater than 35 dB, which suppresses power/ground effects far better than single-ended alternatives. Compared to static CMOS logic, CML circumvents the speed limitations of rail-to-rail switching, where transistors approach triode regions near the supply rails, leading to reduced drive strength and increased delay; instead, CML transistors remain in , enabling significantly higher in optimized designs. Relative to bipolar (ECL), MOS-based CML delivers comparable high-speed performance with significantly lower static power dissipation while leveraging process scalability for easier integration. CML also supports precise on-chip via parallel termination with resistors tied to V_{DD}, which maintains constant input/output impedance (e.g., 50 Ω) and minimizes reflections in high-speed interconnects. Eye diagrams of CML transceivers exhibit low deterministic , underscoring the clean signaling and minimal timing uncertainty.

Limitations and Power Considerations

One of the primary limitations of current-mode logic (CML) is its static power consumption, which arises from the constant bias current I_{SS} required for operation, resulting in power dissipation given by P = I_{SS} \times V_{DD}. This always-on current leads to significantly higher static power compared to logic, where power is predominantly dynamic and scales with switching activity. For high-speed applications, typical CML gates consume 1-10 mW, such as several mW per equivalent in a divide-by-4 operating at multi-GHz frequencies. In contrast, CMOS gates exhibit negligible static power under similar conditions, making CML less suitable for battery-constrained or ultra-low-power systems without modifications. CML circuits also exhibit supply sensitivity, where variations in V_{DD} cause common-mode voltage shifts that can degrade and performance. These shifts arise because the differential output common-mode level tracks V_{DD} changes, potentially leading to improper biasing or increased noise susceptibility in cascaded stages. To mitigate this, precise or on-chip supply is often necessary, adding design complexity. Additionally, CML's differential architecture increases silicon area and manufacturing costs compared to single-ended equivalents. Termination resistors, typically 50 Ω per differential line to V_{CC}, further contribute to area overhead and parasitic effects in integrated implementations. Mitigation strategies for these limitations include adaptive biasing techniques to dynamically adjust I_{SS} based on operating conditions, reducing static power without sacrificing speed. Hybrid designs combining CMOS for low-activity logic blocks with CML for high-speed paths balance power and performance, minimizing overall dissipation. Power-delay product (PDP) analysis, defined as PDP = P \times \tau_{pd}, provides a key metric for optimization, where \tau_{pd} is propagation delay; studies show CML PDP can be competitive with CMOS at GHz speeds when bias currents are tuned for minimum energy per operation. Power-gating schemes, such as inserting sleep transistors to cut off I_{SS} during idle periods, further address static power in MOS current-mode logic variants. In dense integrated circuits, the constant current in CML contributes to self-heating effects, exacerbating thermal gradients and reliability issues due to elevated junction temperatures. This risk is pronounced in high-density layouts, where localized heat from multiple gates accumulates, potentially increasing leakage and variability. Effective thermal management, such as substrate engineering or heat-spreading interconnects, is essential to maintain performance in such environments.

Applications

High-Speed Interconnects and Interfaces

Current-mode logic (CML) serves as a fundamental signaling scheme in high-speed serial links, offering a current-steering differential approach akin to (LVDS) but with enhanced performance for multi-gigabit transmission over printed circuit boards and cables. Unlike voltage-based methods, CML maintains constant current flow while switching the differential pair, enabling low-voltage swings (typically 200-800 mV) that reduce and support data rates ranging from 312 Mbps to over 28 Gbps per lane. This makes CML ideal for point-to-point, unidirectional interconnects in environments requiring robust , such as backplanes and external interfaces. In various communication standards, CML underpins transmitters and receivers for reliable data transfer. For instance, the (TMDS) protocol in DVI and interfaces employs CML drivers to achieve video data rates up to 1.65 Gbps per channel across twisted-pair cables, with DC-coupled outputs terminated to 3.3 V. Similarly, III, a high-speed interface for automotive and industrial camera systems from , utilizes CML for its 4 Gbps serial output over a single differential pair, enabling compact, low-EMI links for megapixel video. In PCIe Gen4 (16 GT/s) and Gen5 (32 GT/s) ecosystems, CML forms the electrical interface in retimers and switches, such as Broadcom's PEX series, where it facilitates and protocol compliance across multi-lane configurations to extend reach in server and storage interconnects. CML interconnects typically incorporate on-chip or external termination networks consisting of 50 Ω to the supply on each leg of the pair (yielding a 100 Ω impedance) or a single 100 Ω across the inputs, ensuring matched transmission lines and minimizing reflections in high-frequency paths. This termination scheme is critical for maintaining eye diagram quality at gigabit speeds, as seen in applications like optical transceivers for 100G Ethernet, where QSFP28 modules from vendors like 10Gtek use CML-compatible electrical inputs to drive modulators over multimode or single-mode , supporting aggregate throughputs up to 100 Gbps via four 25 Gbps lanes. The adoption of CML in high-speed interconnects traces back to the 1990s, when it gained traction as a low-power alternative to (ECL) for signaling in early telecommunication gear, such as prototypes. By the 2000s, advancements in integration propelled CML into multi-gigabit , and into the 2020s, it supports multi-lane architectures in standards like 400G Ethernet and PCIe 6.0, with aggregate bandwidths exceeding 100 Gbps through parallel lanes and equalization techniques.

Integrated Circuits and Mixed-Signal Systems

Current-mode logic (CML) is extensively employed in on-chip applications within integrated circuits, particularly for high-speed components such as frequency dividers and phase detectors in phase-locked loops (PLLs). In PLLs, CML-based frequency dividers operate at multi-gigahertz frequencies, enabling efficient division of the (VCO) output to match the reference clock for phase detection, which is essential for clock generation in RF and systems. For instance, a CML divide-by-2 stage in a 60 GHz PLL synthesizer achieves operation up to 45 GHz while maintaining low . Phase detectors in these PLLs often incorporate CML elements, such as current sources gated by flip-flops, to provide precise charge-pump currents with a linear range of ±2π radians, minimizing in feedback loops. Additionally, CML serializers and deserializers () facilitate on-chip data , converting parallel data streams to serial formats at rates exceeding 10 Gb/s, which reduces interconnect complexity in system-on-chip () designs. In mixed-signal systems, CML integrates seamlessly with analog-to-digital converters (ADCs) and digital-to-analog converters (DACs), particularly in current-to-voltage conversion stages that enhance and reduce . By processing signals in the current domain, CML avoids voltage swings that introduce nonlinearities, allowing direct digitization of current inputs without intermediate voltage conversion, which conserves power and area compared to traditional voltage-mode approaches. In current-steering DACs, CML buffers at the output stage maintain sources, suppressing energy and distortion by up to 10 dB in high-resolution conversions. This makes CML ideal for precision in mixed-signal ICs, where it interfaces digital logic with analog sections to achieve (ENOB) greater than 10 in pipelined ADCs operating at sampling rates over 1 GS/s. Practical examples of CML integration include RF synthesizers and 5G mmWave transceivers, where it supports wideband operation in frequency-agile systems. In RF synthesizers, CML dividers provide octet-phase outputs with locking ranges exceeding 20 GHz, enabling low-phase-noise generation for wireless standards. For mmWave transceivers, CML-based PLLs and dividers handle signals up to 40 GHz in the 28-39 GHz bands, optimizing power efficiency in arrays. Hybrid implementations combine CML with logic for digital control, leveraging CML's speed for analog interfaces while using for low-power computation, often in SiGe BiCMOS processes that enhance gain and . These hybrids operate with low supply headroom of 1-2 V, accommodating stacked transistors without exceeding breakdown voltages in scaled nodes. CML's compatibility with SiGe and BiCMOS technologies further enables integration of high-speed HBTs with , achieving high transimpedance gains at mmWave frequencies. As of 2025, CML has emerged in control logic, particularly for cryogenic environments where it maintains performance at temperatures below 4 K. In cryogenic control ICs, CML clock distribution paths deliver precise timing signals for manipulation, supporting data rates up to 40 Gb/s in readout chains without cryogenic degradation. This application addresses the wiring bottleneck in quantum processors by enabling logic at millikelvin temperatures, with CML gates exhibiting speed improvements of 20-30% over room-temperature equivalents due to reduced thermal noise. Such advancements facilitate scalable control electronics for superconducting s, integrating CML with cryo-CMOS for hybrid classical-quantum interfaces.

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