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BiCMOS

BiCMOS (bipolar complementary metal-oxide-semiconductor) is a technology that integrates junction transistors with complementary metal-oxide-semiconductor () transistors on a single , leveraging the high-speed drive capabilities and current-handling strength of devices alongside the low static power consumption, high integration density, and scalability of . This combination enables BiCMOS to achieve superior performance in applications requiring both digital logic efficiency and analog or high-frequency , such as mixed-signal circuits where pure may lack sufficient drive for large capacitive loads and bipolar-only designs consume excessive power. The development of BiCMOS traces back to the early , with initial proposals for bipolar-compatible processes emerging around 1983, including the design of BiCMOS totem-pole gates to enhance output drive. By the mid-, analog BiCMOS variants appeared for operational amplifiers, followed by digital large-scale integration (LSI) implementations driven by demands for faster, lower-power circuits; widespread commercial production began shortly thereafter, evolving into VLSI-scale applications by the late . Advancements in silicon-germanium (SiGe) transistors (HBTs) during the 1990s and 2000s further propelled BiCMOS, particularly at institutions like , enabling lattice-matched growth of SiGe on substrates for high-frequency performance while maintaining compatibility. Key advantages of BiCMOS include significantly improved switching speeds over standard —often 2-3 times faster for logic gates—while retaining 's low power dissipation and resistance to , making it ideal for battery-powered portable devices like cellular phones and laptops. In fabrication, BiCMOS extends conventional n-well processes with additional masks to form npn structures, such as n+ subcollectors and p+ bases, allowing seamless integration without major redesigns and benefiting from ongoing improvements in either base technology. For instance, in a typical BiCMOS inverter, transistors manage low-power logic switching, while elements provide rapid charging/discharging of output loads, resulting in rail-to-rail voltage swings and flexible I/O compatibility with standards like and ECL. BiCMOS finds prominent applications in high-speed static random-access memories (SRAMs), gate arrays, microprocessors, and input/output-intensive systems where drive strength is critical. In modern contexts, SiGe BiCMOS excels in radio-frequency (RF) integrated circuits for communications, including amplifiers for handsets and base stations, as well as and optical systems requiring millimeter-wave to terahertz capabilities. As of 2025, advancements include ' integration of BiCMOS with for high-speed optical interconnects in AI and datacenter applications, supporting data rates up to 1.6 Tb/s. Its cost-effectiveness compared to (GaAs) alternatives, combined with high integration for system-on-chip solutions, positions BiCMOS as a strategic technology for evolving demands in , , and high-data-rate networking.

Introduction

Definition and Fundamentals

BiCMOS is a semiconductor technology that integrates bipolar junction transistors (BJTs) and complementary metal-oxide-semiconductor (CMOS) transistors on a single integrated circuit substrate. This hybrid approach allows for the realization of circuits that exploit the complementary strengths of both transistor types in a unified manufacturing process. Bipolar junction transistors (BJTs) operate as current-controlled devices, where the base current modulates the collector current with a high current gain, typically on the order of 100, enabling strong amplification and drive capabilities. In essence, the exponential relationship between base-emitter voltage and collector current provides BJTs with robust performance in scenarios demanding high output power. Complementary metal-oxide-semiconductor (CMOS) transistors, by contrast, are voltage-controlled devices, where the gate voltage controls the channel conductance to regulate drain-source current flow. Their design ensures low power dissipation, as one transistor in a CMOS pair remains off during steady-state operation, minimizing static current and supporting dense integration with reduced energy use. The fundamental advantage of BiCMOS lies in its synergistic integration: BJTs deliver high current drive and switching speed for output buffers and analog sections, while CMOS provides efficient, low-power logic for digital processing. This combination facilitates the development of mixed-signal integrated circuits that perform both analog and digital functions effectively on a single chip.

Key Components

BiCMOS devices fundamentally integrate junction transistors (BJTs) and transistors on a single substrate to leverage their complementary strengths. The component is typically an NPN BJT, consisting of three doped regions: a heavily doped n+ emitter for efficient injection, a lightly doped p-type base to control current flow, and an n-type collector to gather carriers, often featuring a buried n+ layer to minimize collector resistance. This structure enables the NPN BJT to deliver high drive current through superior and low output resistance, making it ideal for applications requiring strong amplification and fast switching. The CMOS components include n-channel MOSFETs (NMOS) and p-channel MOSFETs (PMOS), each with a electrode over an insulating oxide layer, flanked by and regions. In NMOS transistors, the and are n+ doped regions in a p-type or well, where a positive voltage inverts the channel to allow flow; PMOS transistors reverse this, with p+ and in an n-well, enabling hole conduction under negative bias. These MOSFETs provide the foundation for low-static-power logic gates due to their high and negligible leakage current in the off state. Bipolar and CMOS transistors are co-located on the same silicon substrate in BiCMOS, sharing process steps such as n-well formation for both the BJT collector and PMOS body, with interconnects formed via metal layers to route signals between them. Parasitic effects, particularly —a low-impedance path triggered by parasitic silicon-controlled rectifiers (SCRs) formed by adjacent p-n junctions—must be mitigated through isolation techniques like deep trench isolation and guard rings to prevent unintended current crowding and device failure. This integration supports efficient mixed-signal circuits by combining bipolar drive with CMOS density.

History

Origins and Early Research

The concept of integrating and transistors in a single emerged in the late as researchers sought to harness the complementary strengths of these technologies for improved performance. Early efforts focused on creating structures that combined the high-speed switching and drive capability of transistors with the low-power characteristics of devices. A seminal proposal came in 1969, when H.C. Lin and colleagues introduced a complementary - transistor structure, demonstrating the feasibility of monolithic to enable more efficient logic and . This work laid the groundwork for ICs by addressing fabrication challenges in combining p-channel and n-channel with elements on the same substrate. In the , initial experiments advanced these ideas through practical implementations, particularly by pioneering semiconductor firms. Laboratories led early demonstrations, developing metal-gate BiCMOS operational amplifiers that integrated logic with output stages for enhanced voltage handling and speed in analog applications. This 1973 innovation by M.A. Polinsky, O.H. Schade, and J.P. Keller showcased a monolithic CMOS- process capable of producing high-performance op-amps with reduced power consumption compared to pure designs. Similar exploratory work at companies like Fairchild involved -MOS configurations to optimize integrated circuits for emerging large-scale (LSI) needs, though 's efforts were among the most documented in this pre-commercial phase. These experiments highlighted the potential for technologies in addressing the limitations of standalone or MOS processes. The drive for such integrations stemmed from the evolving demands of very-large-scale integration (VLSI) circuits during the 1970s, where scaling faced speed bottlenecks while circuits suffered high static power dissipation. Researchers aimed to create VLSI-compatible processes that leveraged for dense, low-power alongside for high-current drive in critical paths, mitigating scaling challenges like increased interconnect delays and . By the early , these foundations culminated in refined proposals, such as the 1983 totem-pole BiCMOS gate by Lin et al., which optimized output buffering for faster transitions. This paved the way for broader adoption in commercial VLSI by the mid-.

Commercial Development and Milestones

BiCMOS technology transitioned from research to commercial production in the mid-1980s, with widespread processes established by 1985 as companies sought to combine the speed of transistors with the low power and density of for high-performance integrated circuits. This shift enabled the development of practical devices for and applications, marking the end of primarily experimental efforts and the beginning of scalable production. In 1986, Japanese firms led the introduction of the first BiCMOS logic families, with Hitachi unveiling a subnanosecond BiCMOS gate-array family capable of high-speed operation suitable for VLSI designs. followed with its TD74BC standard logic series, featuring bipolar output stages for enhanced drive capability alongside CMOS inputs and control, achieving 3 ns propagation delays and 15 mA output current. These early families demonstrated BiCMOS's viability for replacing slower and logics in demanding applications. During the late 1980s, BiCMOS saw initial adoption in microprocessor designs, including RISC architectures, where it provided performance advantages over pure CMOS in high-speed computing tasks. By the 1990s, integration advanced with ECL-compatible gates, exemplified by a 5-ns 1-Mb ECL BiCMOS SRAM that supported emitter-coupled logic interfaces for ultra-fast memory access in high-performance systems. Evolution continued into the 2000s with sub-micron processes, enabling denser and more efficient circuits down to 0.25 μm scales. Key contributors included , which pioneered advanced BiCMOS integrations for mixed-signal applications, and , which developed the ABT family of bus-interface logics using submicron BiCMOS for improved speed and power efficiency starting in the late 1980s. Japanese companies like and drove early logic innovations, while the decade saw a shift toward SiGe variants of BiCMOS, enhancing RF performance for wireless communications through higher transistor frequencies up to 45 GHz.

Technical Principles

Bipolar and CMOS Transistor Integration

BiCMOS technology achieves the integration of bipolar junction transistors (BJTs) and complementary (CMOS) transistors on the same by leveraging vertical stacking of epitaxial layers, where the BJT is formed atop a CMOS-compatible base layer. This approach typically involves growing silicon-germanium (SiGe) epitaxial layers selectively on the CMOS to create the BJT's base and emitter regions, enabling a vertical NPN that utilizes the CMOS n-well as the collector. Such stacking minimizes lateral space requirements and allows the BJT to benefit from the high-density layout of CMOS while providing enhanced current drive. For device isolation, twin-tub or triple-well processes are employed, with the twin-tub configuration using separate n- and p-wells in a p- to isolate NMOS and PMOS transistors alongside the BJT's p-base, and triple-well extending this by incorporating a deep n-buried layer under the CMOS wells to reduce noise and risks in mixed-signal applications. A primary challenge in this integration lies in ensuring compatibility between the processing requirements of and devices, particularly regarding thermal budgets and profiles. fabrication often demands high-temperature steps (above 900°C) for precise in the base and emitter, which can degrade performance by causing unwanted redistribution and shifts in the channels. To mitigate this, low-thermal-budget techniques such as selective epitaxial growth of SiGe at 650–750°C are used, aligning the BJT formation with steps limited to below 800°C to preserve integrity and minimize out-diffusion from the BJT base. profiles are matched by thickening the vertical intrinsic base region in SiGe HBTs to counteract induced by residual annealing, ensuring the BJT's current gain (β > 100) remains high without compromising . These adaptations allow thermal budgets as low as those of 0.35 μm processes while maintaining figures of merit like peak (f_T > 50 GHz). At the device level, hybrid gates exemplify this integration through structures like the BiCMOS inverter, where a standard CMOS inverter pair drives the base of a bipolar emitter-follower to buffer the output stage. In this configuration, the CMOS section provides low-power logic switching with rail-to-rail swing, while the NPN emitter-follower enhances drive capability by sourcing/sinking high currents (up to 10 mA) with minimal (V_BE ≈ 0.8 V), reducing propagation delay in scenarios compared to pure CMOS. The emitter-follower is connected such that its collector ties to V_DD, emitter to the output, and base to the CMOS output via a discharge to prevent floating, achieving overall delays under 100 ps in 0.8 μm processes. This hybrid approach leverages the bipolar 's role in high-speed buffering alongside CMOS for static logic, without altering the core CMOS footprint.

Circuit Configurations

BiCMOS circuit configurations leverage the complementary strengths of and transistors to achieve enhanced performance in logic and driver stages. A fundamental example is the BiCMOS inverter, which incorporates a CMOS input stage for low-power and a bipolar output stage for high-current drive. In this design, the CMOS transistors handle the logic inversion with minimal static power dissipation, while the bipolar transistors, configured in a totem-pole arrangement, provide rapid charging and discharging of output loads by delivering substantial current without the limitations of pure CMOS outputs. The totem-pole driver configuration is particularly suited for scenarios requiring high , such as driving multiple gates or long interconnects. Here, an upper NPN pulls the output high, while a lower NPN pulls it low, enabling efficient handling of capacitive loads ranging from 10 to 100 . This setup minimizes propagation delay under heavy loading by exploiting the devices' high , allowing the circuit to maintain speed advantages over standard while avoiding the excessive power draw of full totem-pole structures. For advanced high-speed applications, ECL-compatible BiCMOS configurations integrate (ECL) elements in time-critical paths alongside CMOS logic for the majority of the circuitry. In these designs, ECL gates, which operate with small voltage swings and non-saturating transistors, accelerate signal propagation in speed-sensitive sections, such as decoders or adders, while the CMOS portions ensure low overall power consumption and high density. The components facilitate seamless level shifting between ECL's differential outputs and CMOS inputs, enabling hybrid operation without significant interface overhead. Another key advanced configuration is the BiCMOS used in arrays for rapid signal detection. This employs cross-coupled transistors to amplify small voltages on bit lines, typically around 100-200 mV, converting them into full-swing logic levels. The pair senses the voltage difference at their bases, producing amplified collector currents that drive subsequent stages, thereby achieving detection times in the sub-nanosecond range critical for high-density SRAMs. NMOS transistors assist in latching and resetting the , combining speed with controllability. The performance rationale underlying these configurations centers on selectively deploying transistors to reduce delays in critical paths, such as output drivers or sensing nodes, without the power penalty of pure bipolar logic. By confining high-current bipolar operation to load-driving or roles, while using low-power for input and non-critical logic, BiCMOS achieves up to 2-3 times faster switching under load compared to CMOS alone, with total power comparable to CMOS due to reduced static dissipation in bipolar sections. This hybrid approach, enabled by the of bipolar and CMOS devices on the same , optimizes speed-power trade-offs for complex digital systems.

Fabrication Process

Core Manufacturing Steps

The fabrication of BiCMOS devices follows a hybrid workflow that integrates bipolar junction transistor (BJT) formation with complementary metal-oxide-semiconductor (CMOS) processing on a single silicon wafer, ensuring compatibility while adding steps for bipolar-specific structures like the collector and base regions. This process typically spans 10-14 core steps, implemented at technology nodes from 0.5 μm down to 28 nm and beyond, evolving with CMOS scaling to balance density and performance. The sequence begins with substrate preparation and progresses through doping, deposition, and patterning, with careful alignment to avoid thermal budget conflicts between CMOS and bipolar devices. The process commences with the preparation of a lightly doped p-type , which is cleaned to remove contaminants and provide a stable foundation for subsequent layers. Next, a buried n+ layer is formed by of or through an , followed by a high-temperature drive-in anneal to diffuse the dopants and reduce collector resistance in the transistor; this step is masked to protect CMOS areas. An n-type epitaxial layer, typically 4-8 μm thick and lightly doped, is then grown on the to serve as the collector and provide material for wells, ensuring low defect density for high-yield integration. Device isolation is achieved using techniques such as local oxidation of silicon (), where pad and are deposited, field regions are etched and implanted with channel-stop , and thick field (around 850 nm) is grown to separate active areas; () is used in finer nodes below 0.25 μm but is detailed separately. N-wells and p-wells are then formed via a twin-tub process: an n-type (e.g., ) is implanted for PMOS and collector regions, followed by self-aligned p-well implantation after growth, defining the CMOS tubs while accommodating structures. Gate formation follows with the growth of a thin layer (e.g., 20 nm) on the active regions after a pre-gate clean, providing the insulating barrier for channels. A layer of is deposited, doped, and etched to define the gates for NMOS, PMOS, and the future bipolar emitter, using and for precise patterning. Source and drain regions are created through sequential doping: lightly doped drain (LDD) extensions are implanted with low-dose for NMOS and for PMOS to mitigate hot-carrier effects, followed by heavier implants after spacer formation. For the bipolar component, an intrinsic region is implanted with in the designated area, followed by deposition of a thicker and in-situ doped polysilicon for the emitter junction, which is patterned to complete the NPN structure; this occurs after CMOS channel adjustments to maintain thermal compatibility. Sidewall spacers are then formed by depositing and anisotropically silicon dioxide or nitride on the gate sidewalls, enabling self-aligned heavier source/drain and extrinsic implants while protecting the edges. Self-aligned silicide contacts, often titanium or cobalt silicide, are formed on exposed silicon surfaces (source, drain, gate, and bipolar regions) through metal deposition, rapid thermal annealing, and selective etching, reducing parasitic resistances without shorting devices. Finally, pre-metal dielectric is deposited, contact holes are etched and filled with tungsten plugs, and multiple levels of metallization (e.g., aluminum or copper) are patterned for interconnections, completing the front-end and back-end processing. This modular flow allows BiCMOS to leverage CMOS infrastructure while inserting bipolar steps at compatible points, achieving gate lengths down to 28 nm in modern variants.

Specialized Techniques and Challenges

In BiCMOS fabrication, selective epitaxial growth (SEG) is employed to form high-quality regions, particularly for the collector and structures, enabling precise control over profiles and reducing parasitic capacitances compared to blanket epitaxy. This technique involves growing or SiGe layers selectively in predefined windows on the , minimizing defects at the edges and allowing with without excessive thermal exposure. For instance, SEG has been integrated into 0.35 μm SiGe BiCMOS processes to achieve transistors (HBTs) with cutoff frequencies exceeding 50 GHz while maintaining compatibility with . Shallow trench isolation (STI) is another critical technique used to electrically isolate bipolar and CMOS devices, effectively preventing latch-up phenomena that arise from parasitic thyristor structures in mixed-technology integration. By etching trenches approximately 0.3-0.4 μm deep and filling them with oxide, STI reduces inter-device spacing and parasitic capacitances, which is essential for high-density BiCMOS layouts in 0.25 μm nodes and below. This method has been shown to enhance latch-up immunity in SiGe BiCMOS technologies by isolating n-p-n and p-n-p junctions from substrate wells, achieving holding voltages well above typical supply levels of 3-5 V. Rapid thermal annealing () addresses dopant activation challenges in BiCMOS by providing short, high-temperature pulses (typically 900-1100°C for 5-10 seconds) that activate impurities in source/drain and base regions without significant , thus preserving shallow junctions required for both and CMOS performance. In advanced BiCMOS processes, replaces longer furnace anneals to mitigate transient enhanced (TED) of or , ensuring uniform activation rates above 90% while limiting thermal budget to under 1 MJ/cm². This approach has been particularly effective in SiGe HBT , where it improves peak current gain by optimizing base profiles without degrading CMOS threshold voltages. Despite these advances, BiCMOS fabrication faces significant challenges, including an increased mask count of 20-30 levels compared to 15 for equivalent processes, which complicates and elevates defect densities, often reducing initial yields by 10-20% in early production runs. The additional masks are necessitated by bipolar-specific steps like subcollector implants and epitaxial patterning, leading to higher sensitivity to variations and overlay errors in sub-micron nodes. Thermal budget conflicts pose another major hurdle, as transistors require high-temperature steps (above 900°C) for epitaxial growth and emitter formation, while demands lower temperatures (below 800°C post-gate) to avoid redistribution and threshold shifts. This mismatch necessitates careful sequencing, such as performing processing before gate definition, but can still result in 10-15% performance degradation in HBT peak due to unintended in the base. In SiGe , adaptations like reduced Ge content or spike help reconcile these constraints, yet they limit overall scalability. Defect control in epitaxial layers remains challenging, with growth conditions often inducing misfit dislocations or stacking faults at Si/SiGe interfaces, particularly when Ge concentrations exceed 20%, leading to leakage currents in bipolar devices up to 10 nA/μm². Techniques such as cyclic annealing or hard-mask optimization during SEG mitigate these, but residual defects can reduce HBT reliability under high-current stress, necessitating rigorous in-line to achieve yields above 85%. The heightened process complexity in BiCMOS elevates per-wafer manufacturing costs by 20-50% over pure as of the early 2000s, primarily due to additional equipment for and annealing, as well as lower yields from mask proliferation. For example, in 0.18 μm nodes on 200 mm wafers, costs were approximately 25-40% higher, though shifts to 300 mm wafers and finer nodes in high-volume RF applications have narrowed the gap to 20-30% by 2025.

Performance and Trade-offs

Advantages in Speed and Power

BiCMOS technology provides substantial speed enhancements over pure implementations, primarily through the integration of transistors that deliver high current drive capabilities. Propagation delays for BiCMOS gates are typically 2-3 times faster than those of equivalent gates, achieving values in the range of 100-200 for logic elements such as inverters and gates in sub-micron processes. For instance, in 0.5 μm technologies, BiCMOS gates exhibit delays around 190 , compared to over 500 for counterparts under similar loading conditions. This improvement stems from the output stage's ability to rapidly charge or discharge capacitive loads, enabling high without significant slowdown, which is a limitation in pure due to its reliance on aspect ratios for drive strength. In terms of power efficiency, BiCMOS bridges the gap between and technologies by combining the low static power dissipation of logic with the dynamic performance of drivers. Static power in BiCMOS circuits remains comparable to , avoiding the continuous current draw inherent in designs, which simplifies packaging and cooling requirements. Dynamic power consumption is further optimized in configurations, where buffering reduces switching energy by approximately 30-50% relative to all- circuits at equivalent speeds, making BiCMOS suitable for very-large-scale (VLSI) with gate densities exceeding 10^6 transistors. Additional performance benefits include high noise margins inherited from CMOS input stages, which provide robust superior to pure circuits. BiCMOS also demonstrates enhanced robustness to process and temperature variations, maintaining consistent performance across manufacturing tolerances and environmental changes due to the complementary strengths of and CMOS devices. Furthermore, its scalability aligns with ongoing CMOS advancements, allowing integration into advanced nodes while preserving speed-power advantages.

Disadvantages and Limitations

BiCMOS technology, while offering hybrid performance benefits, incurs significant fabrication complexity due to the integration of bipolar junction transistors (BJTs) with (CMOS) structures. The process typically requires 3-4 additional steps beyond a standard CMOS baseline to form the BJT components, such as the epitaxial layer, buried layers, and selective implants for the collector, base, and emitter regions. This added complexity contributes to higher costs, with 0.18 μm BiCMOS wafers exhibiting approximately a 40% premium over equivalent CMOS wafers, driven by extended processing times and specialized equipment needs. A key limitation of BiCMOS is the larger area required per , particularly for the components, which demand wider base widths and deeper junctions to achieve adequate and , typically requiring more area than equivalent in cells. regions are also more vulnerable to radiation-induced effects, including total ionizing dose degradation and soft errors, where charged particles can generate excess base or charge collection in the collector, leading to parametric shifts or functional failures at lower fluence levels than in -only devices. In pure digital applications at advanced nodes below 90 nm, BiCMOS without SiGe enhancements has been largely supplanted by advanced technologies such as FinFETs for high-density logic. However, SiGe BiCMOS continues to offer advantages in mixed-signal and high-speed applications, scaling effectively to modern nodes. Trade-offs in BiCMOS include elevated leakage relative to pure , stemming from the base-emitter junctions in BJTs that introduce additional off-state , increasing static power dissipation relative to pure in mixed-signal circuits. Scaling BiCMOS below 65 nm without incorporating silicon-germanium (SiGe) enhancements proves particularly challenging, as standard BJTs suffer from reduced and increased parasitics at shorter channel lengths, limiting performance and exacerbating short-channel effects in the integrated . These constraints often necessitate SiGe heterojunctions to maintain viability, underscoring the technology's reliance on material innovations for continued relevance.

Applications

Digital and Logic Circuits

BiCMOS technology has been particularly advantageous in digital and circuits, where it combines the high drive capability of transistors with the low power consumption and density of , enabling faster switching speeds and improved performance in high-speed applications. In families, BiCMOS are designed to interface with and ECL standards, providing compatibility with legacy systems while achieving superior propagation delays compared to pure equivalents. For instance, BiCMOS utilize output stages to drive large capacitive loads efficiently, resulting in 4-5 times faster performance in large-scale circuits than alone. BiCMOS implementations in complex elements, such as and multiplexers, leverage dynamic techniques to further enhance speed. A BiCMOS dynamic full , employing steering for carry generation, has demonstrated up to six times the speed improvement over in parallel multiplier designs, making it suitable for high-performance units in systems. Similarly, BiCMOS multiplexers benefit from reduced voltage swings and buffering, allowing for quicker signal routing in paths without excessive dissipation. These advancements stem from the transistor's ability to provide high during transitions, minimizing delays in fan-out-heavy scenarios typical of digital . In memory circuits, BiCMOS excels in peripheral components that require rapid sensing and driving. For , BiCMOS sense amplifiers incorporate pairs for low-swing detection, achieving access times as low as 125 in 16 Kb arrays fabricated with 0.5 μm BiCMOS processes. This enables overall chip access times around 5 ns in experimental designs, significantly outperforming counterparts by approaching speeds while maintaining density. In peripherals, BiCMOS drivers and decoders handle interfaces with reduced access times, as seen in 1 Mbit BiCMOS s where output buffers improve soft-error immunity and during read operations. Notable applications include high-speed RISC from the late 1980s and 1990s, where BiCMOS enabled clock frequencies beyond limits. The , introduced in 1993, utilized BiCMOS circuits in its I/O buffers to improve drive capability, supporting 60-66 MHz operations. In , BiCMOS I/O buffers provide robust interfacing for signals, as demonstrated in mixed-array prototypes with 180 I/O cells supporting high-density gate arrays up to 29,000 gates. In modern as of 2023, BiCMOS continues in specialized for accelerators requiring high-speed I/O.

Analog and RF Systems

BiCMOS technology excels in analog circuit design by leveraging bipolar transistors for high current drive and speed alongside CMOS for low power and , enabling with superior performance in switched-capacitor and high-frequency applications. For instance, a fully BiCMOS achieves a gain-bandwidth product exceeding 3 GHz, suitable for systems requiring rapid settling times. Similarly, class-AB BiCMOS op-amps provide high slew rates over 100 V/μs while consuming less than 1 mW, outperforming pure CMOS designs in speed-power trade-offs for amplification. These attributes make BiCMOS op-amps ideal for high-linearity analog building blocks in mixed-signal environments. In , BiCMOS facilitates high-speed, high-resolution (ADCs) and digital-to-analog converters (DACs) with enhanced and . A representative example is a 16-bit pipelined BiCMOS ADC operating at 100 to 160 MS/s, delivering a (SFDR) of 100 , which supports applications demanding accurate signal representation without excessive . For 12-bit systems, BiCMOS enables sampling rates around 100 MS/s in compact layouts, as demonstrated in current-mode sample-and-hold amplifiers integrated with DAC control, achieving low distortion factors below -70 dB for broadband signals. Such converters benefit from bipolar precision in residue amplification and CMOS efficiency in digital logic, reducing overall power to under 200 mW for medium-resolution designs. For radio-frequency (RF) systems, BiCMOS supports low-noise amplifiers (LNAs), mixers, and power amplifiers optimized for wireless standards like and , handling frequencies up to 10 GHz with high linearity. A BiCMOS LNA-mixer pair for cellular CDMA/ exhibits an input (IIP3) above 0 dBm and under 2 dB at 1.9 GHz, minimizing in front-ends. Power amplifiers in BiCMOS achieve output powers of 20 dBm with efficiencies over 30% across 2.4 GHz and 5 GHz bands for IEEE 802.11a/b/g, integrating seamlessly with CMOS circuitry for compact transceivers. These components exploit gain for RF signal handling while using CMOS for control, enabling robust performance in short-range wireless modules. In mixed-signal applications, BiCMOS integrates data converters and phase-locked loops (PLLs) for communication , as well as interfaces in automotive and peripheral systems. PLLs in BiCMOS achieve below -110 /Hz at 1 MHz offset for frequencies up to 16 GHz, supporting clock synthesis in wireless backhaul and data links. This integration allows for unified chips handling analog-to-digital conversion alongside digital processing in USB interfaces, where BiCMOS provides the necessary analog precision for high-speed data transmission. In automotive contexts, BiCMOS mixed-signal circuits drive engine control units with reliable sensor interfacing and , ensuring operation under harsh environmental conditions.

Modern Developments

SiGe BiCMOS Enhancements

SiGe BiCMOS technology advances conventional BiCMOS processes by integrating silicon-germanium heterojunction bipolar transistors (HBTs) in place of traditional silicon bipolar junction transistors (BJTs), primarily through selective or non-selective epitaxial growth of SiGe layers in the base region to form a graded bandgap structure that enhances carrier transport. This epitaxial approach typically involves depositing three key layers—collector, intrinsic SiGe base, and emitter—directly on silicon substrates, enabling monolithic compatibility with fabrication flows while minimizing thermal budget impacts on the devices. Pioneered by in the early , this integration shifted focus toward RF communications, with initial production of SiGe HBT-compatible BiCMOS processes beginning around 1996, allowing vertical scaling of the bipolar profile (e.g., thinner bases and optimized doping) without requiring a complete technology redesign. These SiGe HBTs deliver significant performance improvements, including cutoff frequencies (f_T) up to 505 GHz and maximum oscillation frequencies (f_MAX) up to 720 GHz, as demonstrated in experimental devices from that also achieved a (BV_CEO) of 1.6 V and delays of 1.34 ps. The enhanced structure provides a superior gain-bandwidth product compared to silicon-only BJTs, supporting operation beyond 100 GHz with reduced base transit times and higher current densities. For millimeter-wave applications, SiGe BiCMOS exhibits lower noise figures, such as 5.2 dB in D-band low-noise amplifiers, enabling high-linearity RF front-ends with minimal power penalties. Compatibility with advanced CMOS nodes has been a cornerstone of SiGe BiCMOS evolution, with successful integrations reported in 130 nm, 90 nm, and down to 55 nm processes, where the HBT module is added post- without disrupting digital scaling or yield. This modular approach facilitates hybrid analog-digital systems, leveraging for logic while SiGe HBTs handle high-speed analog and RF functions, as seen in platforms targeting f_T/f_MAX beyond 300/500 GHz in production environments.

Current and Future Trends

As of 2025, SiGe BiCMOS technology maintains a dominant position in high-frequency mixed-signal applications, particularly in infrastructure. It is widely adopted in base stations for millimeter-wave transceivers and power amplifiers, enabling efficient radio-over-fiber receivers and high-gain amplifiers operating up to 30 GHz, which support the dense arrays required for deployment. In automotive systems at 77 GHz, SiGe BiCMOS provides low-noise amplifiers and high-power handling transistors essential for long-range sensing, with platforms in volume production achieving noise figures below 1.3 at 40 GHz. Optical transceivers also leverage SiGe BiCMOS for transimpedance amplifiers and clock- circuits, supporting rates up to 800 Gb/s in next-generation networks for s. The for BiCMOS in mixed-signal is experiencing robust growth, driven by demand in accelerators where high-speed analog-digital is critical; for instance, -enabled BiCMOS solutions are projected to form a $2 billion serviceable addressable by 2030, fueled by expansion (combined BiCMOS and foundry estimate). In 2025, advanced BiCMOS for 800 Gb/s interconnects, while Tower Semiconductor's platforms support 800 Gb/s optical networks. Emerging trends in BiCMOS emphasize deeper integration with advanced CMOS architectures to sustain performance at shrinking nodes. SiGe BiCMOS is being combined with FinFET CMOS processes, as demonstrated in deep sub-micron process flows that incorporate both technologies for enhanced logic and analog functionality. Hybrid approaches with III-V materials, such as InP or GaAs on silicon substrates, are advancing for frequencies beyond 100 GHz, enabling heterogeneous integration for mmWave and sub-THz modules with improved power output and efficiency over pure silicon solutions. Meanwhile, the use of BiCMOS in pure digital circuits is declining, as advanced CMOS scaling—now reaching GAA structures—provides sufficient speed and density for most logic applications without the added complexity and cost of bipolar integration. Looking ahead, BiCMOS is poised to play a pivotal role in networks through SiGe variants optimized for D-band (110-170 GHz) phased arrays and power amplifiers, supporting terabit-per-second data rates with capabilities in 130 nm processes. In quantum sensing, BiCMOS enables compact transmitters and detectors for magnetometers, achieving low-power microwave control for high-sensitivity field measurements in portable devices. For edge , BiCMOS facilitates efficient mixed-signal processing in endpoints, such as interconnects that reduce and power in AI clusters, though challenges persist in optimizing power consumption for battery-constrained sensors. Overall, while power efficiency remains a key hurdle for widespread adoption—requiring innovations in low-voltage designs—BiCMOS's hybrid strengths position it for growth in these high-impact domains.

References

  1. [1]
    [PDF] BICMOS Technology and Fabrication
    BiCMOS can take advantage of any advances in CMOS and/or bipolar technology, greatly accelerating the learning curve normally associated with new technologies.Missing: fundamentals | Show results with:fundamentals
  2. [2]
    [PDF] Introduction - Higher Education | Pearson
    The BiCMOS technology that combines the low-power dissi- pation and high packing density of CMOS with the high-speed and high- output drive of bipolar devices ...
  3. [3]
    [PDF] Fully Integrated CMOS Power Amplifier - UC Berkeley EECS
    Dec 6, 2006 · And because of this fact, this technology allows CMOS logic to be integrated with heterojunction bipolar transistors, and is so called BiCMOS, ...
  4. [4]
    https://ieeexplore.ieee.org/document/9318746
  5. [5]
    BiCMOS, a technology for high-speed/high-density ICs - IEEE Xplore
    The advantages of the BiCMOS technology for systems applications are demonstrated. The results clearly show that BiCMOS is the choice for filling the gap ...
  6. [6]
    [PDF] Bipolar Transistor
    When they are used, a small number of BJTs are integrated into a high-density complementary MOS. (CMOS) chip. Integration of BJT and CMOS is known as the BiCMOS.
  7. [7]
    [PDF] MOS Transistor
    A transistor is a device that presents a high input resistance to the signal source, drawing little input power, and a low resistance to the output circuit, ...
  8. [8]
    https://www.chu.berkeley.edu/wp-content/uploads/2020/01/Chenming-Hu_ch6-1.pdf
  9. [9]
    [PDF] An Overview of BiCMOS - Semitracks
    Jul 2, 2012 · The bipolar transistors in a BiCMOS circuit exhibit a higher transconductance than with CMOS. This leads to superior amplifica- tion properties.
  10. [10]
    [PDF] BiCMOS LOGIC CIRCUIS - WordPress.com
    In comparison, bipolar junction transistors (BJTs) have more current driving capability, and hence, can overcome such speed bottlenecks using less silicon area.
  11. [11]
    [PDF] UNIT-I Introduction to IC Technology-MOS, PMOS, NMOS, CMOS ...
    The diagram given below shows the cross section of the BiCMOS process which uses an npn transistor. Page 16. BASIC ELECTRICAL PROPERITIES: 1. Linear Region:.
  12. [12]
    Introduction to BiCMOS | SpringerLink
    BiCMOS technology combines Bipolar and CMOS transistors in a single integrated circuit. By retaining the benefits of Bipolar and CMOS, BiCMOS is able to ...
  13. [13]
    The Ultimate Guide to: BiCMOS - AnySilicon
    BiCMOS emerged in 1983 as a result of the constant research and development of new technologies driven by the need for greater performance which fabricated CMOS ...
  14. [14]
    Fabrication and Evaluation of BiCMOS Logic Gates for VLSI - J-Stage
    ... family”, Proc. 1986 IEEE CICC, p. 63 (1986). (7) P. Hickman, et al.: “A high performance 6,000 gate BiCMOS logic array”, Proc. 1986 IEEE CICC. p. 562 (1986).Missing: first | Show results with:first<|separator|>
  15. [15]
    [PDF] Japanese semiconductor industry service : volume II, 1986-1989
    Toshiba—BICMOS standard logic series (TD74BC); bipolar output parts and CMOS input and logic control functions; 3ns propagation delays;. 15mA current at 20 ...
  16. [16]
    [PDF] The History of the Microprocessor - Bell System Memorial
    Early in the 1980s, the combi- nation of C, UNIX, and university research gave rise to a new architecture paradigm, RISC. New industry players, such as MIPS ...
  17. [17]
    A 5-ns 1-Mb ECL BiCMOS SRAM | IEEE Journals & Magazine
    Oct 31, 1990 · A 1-Mword*1-b ECL (emitter coupled logic) 10 K I/O (input/output) compatible ... Date of Publication: 31 October 1990. ISSN Information ...
  18. [18]
    Future trends in BiCMOS technology - ScienceDirect.com
    It follows that BiCMOS technology will extend the use of TTL & ECL interfaces into the deep sub-micron regime. Both digital and digital-analog systems will ...
  19. [19]
    [PDF] "Advanced BiCMOS Technology ABT Logic Characterization ...
    With this in mind, TI developed a family of bus-interface devices – ABT – utilizing advanced. BiCMOS technology. The goal of the ABT family of devices is to ...
  20. [20]
    [PDF] Foundation of rf CMOS and SiGe BiCMOS technologies - HSISL
    All generations of BiCMOS technology are compatible with an associated IBM CMOS technology in devices, metallization (interconnects), and ASIC design system.
  21. [21]
    [PDF] BJTs in integrated circuits: Vertical NPN
    BiCMOS: CMOS + p-base and buried-layer. The n-pocket can be an n-well. The buried-layer a buried-well of a triple-well CMOS. Same as (b) but with the.
  22. [22]
    High-performance flexible BiCMOS electronics based on single ...
    Sep 26, 2017 · BiCMOS technology, which is a combination of bipolar technology and CMOS technology, was developed to achieve complementary advantages from both ...
  23. [23]
    Epitaxial growth of SiGe layers for BiCMOS applications
    Essentially a `SiGe drift-transistor' profile[5]is employed for thermal budget compatibility with the 0.35 μm CMOS. An a-Si layer is used as a hard mask for ...
  24. [24]
    A Flexible 0.18 <formula formulatype="inline"><tex Notation="TeX">$\mu{\rm m}$</tex> </formula> BiCMOS Technology Suitable for Various Applications
    Insufficient relevant content. The provided content snippet does not contain detailed information on BiCMOS integration using low-thermal-budget SiGe HBT and CMOS compatibility. It only includes a title and partial metadata from IEEE Xplore, lacking substantive text or specifics about the technology.
  25. [25]
    Impact study of the process thermal budget of advanced CMOS ...
    The as-deposited BiCMOS055 vertical doping profile is exposed to the thermal budgets from existing CMOS040, CMOS028, CMOS028FDSOI and CMOS014FDSOI technologies ...
  26. [26]
    Two proposed BiCMOS inverters with enhanced performance
    The first BiCMOS inverter is known as the totem-pole gate or the conventional BiCMOS inverter; it is shown in Fig. 1 (a). The usage of bipolar devices at the ...
  27. [27]
    Mos circuit with bipolar emitter-follower output - Google Patents
    The inverter stage may have multiple inputs to form a gate. The emitter-follower stage employs a bipolar transistor with an MOS transistor as the load impedance ...
  28. [28]
    BiCMOS, a technology for high-speed/high-density ICs
    Insufficient relevant content. The provided content snippet from https://ieeexplore.ieee.org/document/63377 does not contain specific information on ECL-like designs in BiCMOS technology, operational principles for high-speed logic, or integration with CMOS circuits. It only includes a title and partial metadata without substantive details.
  29. [29]
    Chapter 10 A Perspective on BiCMOS Trendsl
    Speed critical paths are implemented in ECL for maximum performance, while the bulk of the chip is CMOS or BiCMOS thereby conserving power and area.
  30. [30]
    5.2.1 BiCMOS Process Flow - IuE
    The BiCMOS process starts with a P-type wafer, forms a buried N+ layer, grows an epitaxial layer, fabricates N-wells, and then a deep N+ subcollector.
  31. [31]
    Chapter 3 BiCMOS Process Technology
    typical submicron BiCMOS process flow is presented in a later section. The process. Page 3. BiCMOS Process Technology. 65 flow is described in cross-sectional ...
  32. [32]
    An industrial 0.35 /spl mu/m SiGe BiCMOS technology for 5 GHz ...
    The selective epitaxial growth is improved with the use of an innovative oxy-nitride interpoly layer which increases the growth rate. The HBT features a current ...
  33. [33]
    Bipolar process integration for a 0.25 /spl mu/m BiCMOS SRAM ...
    This paper describes bipolar process integration issues for a 0.25 /spl mu/m BiCMOS SRAM technology which uses shallow trench isolation.
  34. [34]
    The effect of deep trench isolation, trench isolation and sub-collector ...
    This paper demonstrates the independent and combined effect of deep trench (DT) isolation, trench isolation (TI), and sub-collector on shallow trench isolation.
  35. [35]
    Modeling arsenic activation and diffusion during furnace and rapid ...
    It is shown that for advanced CMOS and BiCMOS technologies the activation of impurities is governed by the rapid annealing steps through the release of charged ...
  36. [36]
    [PDF] VLSI FABRICATION TECHNOLOGY - Oxford University Press
    VLSI fabrication involves scaling down device size, using silicon wafers, and doping to create diodes, transistors, and resistors. Basic steps are described.
  37. [37]
    Issue Image no(s) - Electron Devices Meeting, 1995., International
    Total mask count for this 2-p0ly, 3-metal process was reduced from 35 to 25 in comparison with the conventional. BiCMOS process. Page 2. NOTES. 652-IEDM 95.
  38. [38]
    0.13 m SiGe BiCMOS Technology Fully Dedicated to mm-Wave ...
    The interconnect lines are formed using a damascene process and made of six copper levels for which the two highest are 3- m-thick (M5T and M6T). Finally, a 2 ...
  39. [39]
    Bipolar NPN ICEO leakage due to PETEOS deposition - IEEE Xplore
    These defects prevented epitaxial growth of the base region. The defects and ICEO leakage were eliminated by modifying the process conditions during the ...
  40. [40]
    [PDF] The CMOS Advantage
    The bottom line is that CMOS has an inherently lower manufacturing cost than SiGe BiCMOS by over 30%. So why pursue SiGe? The rationalization for SiGe ...
  41. [41]
    Future Trends In BiCMOS Technology - IEEE Xplore
    BiCMOS provides CMOS power and densities at Bipolar speeds. At a given technology level, BiCMOS out performs CMOS by a factor of 1.5 - 2.OX.
  42. [42]
    A 512 kb/5 ns BiCMOS RAM with 1 kG/150 ps logic gate array
    A 512 kb/5 ns BiCMOS RAM with 1 kG/150 ps logic gate array. Abstract: An ... The logic gate has 150-ps propagation delay with 4-mW power dissipation. A ...
  43. [43]
    https://ieeexplore.ieee.org/document/48219/
  44. [44]
    A 190 ps 0.5 mu m mixed BiCMOS/CMOS channelless gate array ...
    A 190 ps 0.5 mu m mixed BiCMOS/CMOS channelless gate array family ... The propagation delay time of the two-input NAND ... The propagation delay time of ...
  45. [45]
    (PDF) A 90nm SiGe BiCMOS Technology for mm-wave and high ...
    Aug 19, 2015 · We present the electrical characteristics of the first 90nm SiGe BiCMOS technology developed for production in IBM's large volume 200mm fabrication line.
  46. [46]
    New full-voltage-swing BiCMOS buffers | IEEE Journals & Magazine
    The circuits are simulated and compared to BiCMOS and CMOS buffers. ... They provide high speed and low delay to load sensitivity and high noise margins.
  47. [47]
    A Compact, Wideband, and Temperature Robust 67–90-GHz SiGe ...
    Mar 29, 2019 · A compact bias circuit is employed to achieve temperature robustness, while the layout is optimized for wideband and highly efficient operation.Missing: variations | Show results with:variations
  48. [48]
    BiCMOS Technology Explained: The Best of Bipolar & CMOS Circuits
    Core Components and Structure ... BiCMOS combines bipolar junction and metal-oxide-semiconductor transistors on one chip. This allows for advanced circuit designs ...
  49. [49]
    [PDF] BiCMOS vs CMOS Final - Microwave Journal
    Sep 14, 2010 · Silicon-‐based BiCMOS can leverage the world's silicon foundry capacity and respond to the market demand for ongoing integration of wireless ...<|control11|><|separator|>
  50. [50]
    [PDF] A Comparison of LinBiCMOS and CMOS Process Technologies in ...
    This application report compares LinBiCMOS and pure CMOS technologies for the design of high-speed low voltage differential signaling (LVDS) interface ...Missing: key | Show results with:key
  51. [51]
    CMOS vs. Bipolar in Analog Chip Design - All About Circuits
    At reasonably high (3 V and above) supply voltages, CMOS and bipolar devices end up about equal in size. Bipolar Transistors Are Better For Low-Voltage Design.
  52. [52]
    Total Ionizing Dose Effects in Bipolar and BiCMOS Devices
    Jul 11, 2005 · Bipolar and BiCMOS device samples were tested exhibiting significant degradation and failures at different irradiation levels. Linear technology ...Missing: soft | Show results with:soft
  53. [53]
    [PDF] SiGe BiCMOS for Analog, High-Speed Digital and Millimetre-Wave ...
    This paper explores the application of. SiGe BiCMOS technology to mm-wave transceivers with analog and digital signal processing. A review of 10-.
  54. [54]
    SiGe slips into main fabs - ScienceDirect.com
    CMOS silicon's speed can be boosted by shrinking transistor dimension from 130nm to firstly 90nm then 65nm and 45nm, but only at great expense and difficulty, ...
  55. [55]
    [PDF] SiGe HBTs and BiCMOS Technology for Present and Future ... - HAL
    Jan 7, 2021 · Section II is devoted to technology and gives an overview of SiGe HBT development and BiCMOS process integration at the Euro- pean level.<|control11|><|separator|>
  56. [56]
    BiCMOS, a technology for high-speed/high-density ICs - IEEE Xplore
    A BICMOS technology, on the other hand, combines high precision with favorable gain and bandwidth.
  57. [57]
    BiCMOS dynamic full adder circuit for high-speed parallel multipliers
    With the BiCMOS dynamic full adder circuit, an 8 × 8 multiplier designed based on a 2μm BiCMOS technology shows a six times improvement in speed as compared to ...Missing: multiplexers | Show results with:multiplexers
  58. [58]
    [PDF] A 125-ps Access, 4GHz, 16KB BICMOS SRAM - ResearchGate
    Abstract—A 128Kbit BiCMOS SRAM with a typical access time of 125ps was developed with 0.13um IBM Silicon Germanium BiCMOS technology[1]. The fast access time ...
  59. [59]
    An experimental 5 ns BiCMOS SRAM with a high-speed architecture
    An input buffer/level translator, a current sense amplifier, and a high ... access time along with the 0.6-μm BiCMOS technology. The chip is organized ...
  60. [60]
    An experimental 1-Mbit BiCMOS DRAM | IEEE Journals & Magazine
    Three developments are proposed for high-performance DRAMs: a bipolar complementary MOS (BiCMOS) DRAM device structure featuring high soft-error immunity ...
  61. [61]
    Interesting BiCMOS circuits in the Pentium, reverse-engineered
    Jan 23, 2025 · Most of these transistors are NMOS and PMOS transistors, but there is a bipolar transistor near the upper right, the large box-like structure. ...
  62. [62]
    BiCMOS - Wikipedia
    BiCMOS is a semiconductor technology that integrates two semiconductor technologies, those of the bipolar junction transistor and the CMOS
  63. [63]
    A 0.8 mu m 29000 gate BICMOS-ECL mixed array ... - IEEE Xplore
    The I/O area is made up of 180 I/O cells, 180 I/O ... All address and data input buffers are 2:1 MUXs. ... Gate BiCMOS-ECL Mixed Array", ASIC. Seminar & Exhibit, ...<|separator|>
  64. [64]
    https://ieeexplore.ieee.org/document/10119045
  65. [65]
    A class-AB high-speed low-power operational amplifier in BiCMOS technology
    Insufficient relevant content. The provided content only includes a title and metadata without substantive details about the BiCMOS operational amplifier's performance metrics (speed, power, gain) or advantages for analog applications. No specific examples or comparisons to CMOS are available.
  66. [66]
    A 16-Bit 100 to 160 MS/s SiGe BiCMOS Pipelined ADC With 100 dBFS SFDR
    - **Resolution**: 16-bit
  67. [67]
    Highly linear SiGe BiCMOS LNA and mixer for cellular CDMA/AMPS applications
    Insufficient relevant content. The provided content only includes a title and a partial URL, with no detailed information on the BiCMOS LNA and mixer (e.g., frequency, linearity, noise figure, or applications in CDMA/AMPS). No full text or specific data is available from the given input.
  68. [68]
    [PDF] RF BiCMOS Power Amplifier Design For IEEE 802.11a/b/g ...
    A highly Integrated SiGe BiCMOS Class F Power Amplifier for Bluetooth Application · Computer Science, Engineering. 2006 International Symposium on VLSI Design…
  69. [69]
    https://www.semanticscholar.org/paper/RF-BiCMOS-Power-Amplifier-Design-For-IEEE-802.11a-b-Chen-Jou/7cd5e63488cc1e570dc9e141c4f9b786ebff183a
  70. [70]
    BiCMOS Technology: Fabrication Process and Applications
    Aug 8, 2023 · BiCMOS technology is an integration technology that combines bipolar and CMOS (Complementary Metal Oxide Semiconductor) devices on a single chip.
  71. [71]
    High-performance SiGe HBTs for next generation BiCMOS technology
    Oct 10, 2018 · This paper addresses fabrication aspects of SiGe heterojunction bipolar transistors which record high-speed performance.
  72. [72]
    https://iopscience.iop.org/article/10.1088/1361-6641/aade64
  73. [73]
    https://ieeexplore.ieee.org/document/7838335
  74. [74]
    [PDF] A D-Band Low-Noise-Amplifier in SiGe BiCMOS with Broadband ...
    Realized in a SiGe BiCMOS technology, the LNA achieves 28 dB gain with 127-168 GHz 3-dB bandwidth, NF down to 5.2dB and. > 2dBm output compression point with ...
  75. [75]
    [PDF] Millimeter-Wave Wireless-Optical Receiver Circuit Design for 5G ...
    Sep 11, 2025 · First, a high-speed analog Radio-over-Fiber (RoF) receiver in 130 nm SiGe BiCMOS ... 5G base stations employ large antenna arrays (e.g., 64 ...
  76. [76]
    Fujikura Technical Review | Research and Development
    A Power Amplifier for Millimeter-Wave 5G Base Stations Covering 24–30 GHz ... The PA fabricated in a 130-nm SiGe BiCMOS process demonstrates a maximum gain ...
  77. [77]
    SiGe BiCMOS Terabit Platform - Tower Semiconductor
    ... applications such as 24GHz and 77GHz automotive radar and 5G mm-wave. The ... transceiver components such as Trans-impedance amplifiers (TIAs), laser ...
  78. [78]
    Driving the Future of AI Datacenters with STMicroelectronics' Silicon ...
    Sep 23, 2025 · We anticipate that the combined foundry business of BiCMOS and SiPho would reach 2B$ SAM by 2030, thanks to the continuous growth of data center ...
  79. [79]
    Deep Sub-Micron Process Integration - PT International LLC
    The course covers fundamental manufacturing technologies and typical CMOS, BiCMOS,,Bipolar FinFet process flows used to guide IC fabrication; Current Issues in ...<|separator|>
  80. [80]
    Heterogeneous III-V/CMOS Technologies for Beyond 5G RF Front ...
    Jan 10, 2020 · This demonstration shows the potential for enabling a hybrid III-V/CMOS technology for 5G and mm-wave applications. To achieve higher ...Missing: BiCMOS | Show results with:BiCMOS
  81. [81]
    PD-SOI CMOS and SiGe BiCMOS Technologies for 5G and 6G ...
    In this paper, we review the development of PD-SOI CMOS and SiGe BiCMOS technologies addressing 5G RF Integrated Circuits (RFICs) and their evolutions for 6G.
  82. [82]
    A Four-Channel BiCMOS Transmitter for a Quantum Magnetometer ...
    Jan 19, 2024 · We present custom-designed chip-integrated microwave (MW) electronics for a miniaturized, low-cost, and highly scalable quantum magnetometer based on NV ...
  83. [83]
    2024 Outside System Connectivity - IEEE IRDS
    It must be determined whether the optical transceiver should be integrated at the package level to provide these advantages. Also, the new transceivers must be.