Overcoming the Transimpedance Limit: A Tutorial on Design of Low-Noise TIA

Li, Dan; Li, Geng; Maloberti, Franco; Svelto, F.

doi:10.1109/tcsii.2022.3173155

Cited by 12 publications

(8 citation statements)

References 30 publications

(44 reference statements)

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“…to even lower than (4), generating higher input-referred noise [8]. Potential of high ω T is completely wasted in this scenario.…”

Section: Low-bandwidth Tia With Multi-stage Amplifiermentioning

confidence: 99%

“…TIAs with multi-stage amplifiers are another way to extend the tranimpedance limit by achieving a higher gain-bandwidth product [3]. Unfortunately, typical multi-stage broadband amplifiers with several roughly equal non-dominant poles require significantly faster technologies to ensure that the overall phase shift in the TIA feedback loop is small enough to achieve good stability [8], which is difficult in high-speed designs. It is possible to add on-chip peaking inductors to allow for bandwidth extension in these multistage amplifier TIAs [9].…”

mentioning

confidence: 99%

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A 12.5 Gb/s 1.38 mW all-inverter-based optical receiver with multi-stage feedback TIA and continuous-time linear equalizer

Yan

Hong

Chang

et al. 2023

Preprint

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An optical receiver employs an all-inverter-based front-end design that provides maximum transconductance for a given power supply and allows for ultra-low power consumption. The feedback transimpedance amplifier (TIA) input stage utilizes a multi-stage amplifier to achieve a dramatic increase in feedback resistance and lower input-referred noise. Cascading an inverter-based active inductor continuous-time linear equalizer (CTLE) provides frequency peaking to compensate the input stage TIA that is intentionally designed with a reduced bandwidth to achieve adequate sensitivity at low power. Fabricated in 28 nm CMOS, the 12.5 Gb/s optical receiver achieves -10.7 dBm OMA sensitivity at 0.11 pJ/bit energy efficiency and occupies only 720 μm2 area.

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“…to even lower than (4), generating higher input-referred noise [8]. Potential of high ω T is completely wasted in this scenario.…”

Section: Low-bandwidth Tia With Multi-stage Amplifiermentioning

confidence: 99%

mentioning

confidence: 99%

A 12.5 Gb/s 1.38 mW all-inverter-based optical receiver with multi-stage feedback TIA and continuous-time linear equalizer

Yan

Hong

Chang

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

“…The first TIS stage having an inverter-based single-stage core amplifier with a fixed voltage supply (constrained by CMOS process) exhibits nearly the second-order system and offers slower roll-off [66]. This makes the design of following CTLEs much easier to recover the desired BW.…”

Section: Broadband Low-noise Designmentioning

confidence: 99%

“…Note that a single-stage core amplifier with a shunt-feedback architecture is chosen for a low-noise design instead of a multi-stage core amplifier with a shunt-feedback architecture implemented in [34] and [67]. This is because the latter approach is only efficient when the ratio of f T to the desired TIA BW is much higher (i.e., >10), which cannot be satisfied in this case [66]. The latter approach also entails significant design effort overhead associated with meeting sufficient phase margin while dealing with multiple complex poles [66], [68].…”

Section: Broadband Low-noise Designmentioning

confidence: 99%

“…This is because the latter approach is only efficient when the ratio of f T to the desired TIA BW is much higher (i.e., >10), which cannot be satisfied in this case [66]. The latter approach also entails significant design effort overhead associated with meeting sufficient phase margin while dealing with multiple complex poles [66], [68]. The noise reduction insight with considered approach can be explained as follows.…”

Section: Broadband Low-noise Designmentioning

confidence: 99%

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A 112-Gb/s —8.2-dBm Sensitivity 4-PAM Linear TIA in 16-nm CMOS With Co-Packaged Photodiodes

Patel

Sharif-Bakhtiar

Carusone

2023

IEEE J. Solid-State Circuits

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A flip-chip co-packaged linear transimpedance amplifier (TIA) in 16-nm fin field effect transistor (FinFET) CMOS demonstrating 112-Gb/s four-level pulse-amplitude modulation (4-PAM) with −8.2-dBm sensitivity is presented in support for optical receivers required in the next-generation intradata center links. A proposed three-stage TIA is comprised of a shunt-feedback stage followed by digitally programmable continuous-time linear equalizers (CTLEs) and a variable gain amplifier (VGA). Broadband low-noise design is achieved by having the first stage with much lower bandwidth (BW) followed by the proposed BW recovering CTLEs. A low-power design is supported by the inverter-based single-ended architecture with a single-ended-to-pseudo-differential conversion in the last stage. TIA's BW extension is further supported by optimizing the photodiode-to-receiver (PD-to-RX) interconnect and utilizing several inductive peaking techniques. It achieves 63-dB gain, 32-GHz BW, and an average input-referred current noise density of 16.9 pA/ √ Hz while operating at 0.9-V supply and consuming 47-mW power. Opto-electrical measurements are performed on a co-packaged prototype comprised of identical proposed TIAs in CMOS with combinations of various commercial PDs and PD-to-RX interconnect lengths confirming 112-Gb/s 4-PAM reception meeting pre-forward error correction (FEC) symbol error rate (SER) of 4.8 × 10 −4 without any post-equalization. Index Terms-100 Gb/s, 400 GbE, CMOS, co-packaged optical receiver front end, continuous-time linear equalizer (CTLE), fin field effect transistor (FinFET), gigabit Ethernet, inverter, low-noise broadband amplifier, optical communications, PAM-4, transimpedance amplifier (TIA). I. INTRODUCTIONT HE Big Bang of the Internet powering 5G, artificial intelligence (AI), machine learning (ML), video conferencing, the Internet of Things (IoT), and cloud storage applications has continuously increased the demand on the

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A 12.5 Gb/s 1.38 mW all-inverter-based optical receiver with multi-stage feedback TIA and continuous-time linear equalizer

Yan,

Hong,

Chang

et al. 2024

Analog Integr Circ Sig Process

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Overcoming the Transimpedance Limit: A Tutorial on Design of Low-Noise TIA

Cited by 12 publications

References 30 publications

A 12.5 Gb/s 1.38 mW all-inverter-based optical receiver with multi-stage feedback TIA and continuous-time linear equalizer

A 12.5 Gb/s 1.38 mW all-inverter-based optical receiver with multi-stage feedback TIA and continuous-time linear equalizer

A 112-Gb/s —8.2-dBm Sensitivity 4-PAM Linear TIA in 16-nm CMOS With Co-Packaged Photodiodes

A 12.5 Gb/s 1.38 mW all-inverter-based optical receiver with multi-stage feedback TIA and continuous-time linear equalizer

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