A high‐performance CMOS four‐stage amplifier

Advancements in integrated circuits technology, force designers to adopt methods and approaches with posed limitations. Nowadays, multistage amplifiers are widely in demand due to high‐gain performance while avoiding placing transistors vertically in contrast with cascode structures. In this work, a four‐stage amplifier is investigated and frequency is compensated via a compensation network that includes two Miller capacitors at the outputs of differential blocks. So, using two Miller capacitors and sharing these capacitors common in four Miller loops, provide an opportunity to achieve acceptable frequency response regarding gain‐bandwidth product and phase margin. The proposed amplifier is modeled symbolically and simulated with the HSPICE circuit simulator with the help of 0.18 μm CMOS technology. According to the simulation results, the proposed approaches show superior performance compared with previously existing methods. Additionally, the sensitivity of the proposed amplifier against load and compensation capacitors expresses a stable and relatively fixed frequency response. Such a high gain amplifier with more than 180 dB as DC gain and 88° phase margin, is in great demand for realizing modulators and data converters.

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Four‐stage CMOS operational transconductance amplifier: Compensated via double differential blocks

Roohbakhsh¹,

Sanaee

Aghaee

2022

“…Logically, more nodes in amplifier leads to more complicated compensation network. [18][19][20][21][22][23][24][25][26] So, design simplicity attracts attention since complex structures are less reliable for many reasons such as fabrication mismatches and heavy theoretical calculations. In this regard, in this paper a five stage transconductance amplifier with related compensation network is proposed, described and simulated.…”

Section: Introductionmentioning

confidence: 99%

Five‐stage CMOS OTAfrequency compensated via nested differential feedback

Zanjani

Sadrnia

Biabanifard

2022

Nowadays cascode structures or vertical arrangements of MOSFETs can not satisfy demands regarding high gain amplifiers. As a direct result, the only promising choice turns to Multi-stage amplifiers via cascading gain stages. The challenge here is stability issues which shows itself by different frequency compensation. All problem starts with increasing number of nodes and consequent poles. The poles degenerate phase of system and need to be controlled. In this work, a five-stage amplifier is targeted for a new and efficient frequency compensation technique. The major contribution of proposed approach is using only two Miller capacitors with considerable small values (10 pF) compared to load capacitor (500 pF). This achieved via exploiting two differential active stages which intensify Miller effect and provide capability to share Miller capacitor at multiple loops simultaneously. The proposed amplifier with corresponding frequency compensation is described symbolically while a circuit level implementation is performed via HSPICE circuit simulator and TSMC 0.18 μm CMOS technology. Based on simulation results, the proposed amplifier expresses a DC gain of 195 dB, a gain bandwidth product of 15.2 MHz, a phase margin of 90 , and a power dissipation of 570 μW.

“…However, the above operators do not consider these correlations. (2) The simple replacement of circuit parameters with corresponding ranges and the use of high operators give rise to very wide sentences variation and polynomials, which have been taken too carefully 10‐13 . For example, for one parameter in some sentences the maximum range is set, whereas for the same parameter in other sentences the minimum value is set.…”

Section: Introductionmentioning

confidence: 99%

Four‐stage CMOS amplifier design based on symbolic calculations: Stack comparison approach

Bahadoran

Reza-Alikhani

2021

This paper presents a simple simplification method to design a multistage amplifier. The simplification procedure is based on a defined criterion which mainly related to ignoring negligible terms. In order to verify the validity and accuracy of the exploited method, a complex four‐stage CMOS amplifier is considered. Simplified transfer function and circuit simulator output are compared. According to simulation results obtained from HSPICE circuit simulator and TSMC 0.18 μm CMOS technology, the proposed approach expresses a bitter performance by 1% error. The aim is to propose a preprocessing algorithm. This helps main algorithm to deal with simpler inputs. In this way, a preprocessing algorithm is investigated which reduces CPU time and needed memory to simplify heavy symbolical transfer functions. Since target is analog and mix mode circuit, some circuit‐based assumptions are considered.