Instruction


FACTA UNIVERSITATIS   

Series: Electronics and Energetics Vol. 30, N
o
 4, December 2017, pp. 549 - 556 

DOI: 10.2298/FUEE1704549S 

HIGH-BANDWIDTH BUFFER AMPLIFIER FOR LIQUID 

CRYSTAL DISPLAY APPLICATIONS

  

Saeed Sadoni, Abdalhossein Rezai 

ACECR Institute of Higher Education, Isfahan Branch, Isfahan, Iran 

Abstract. In this paper, a novel high-bandwidth and low-power buffer amplifier is presented 

for the liquid crystal display applications. This buffer amplifier consists of a folded cascade 

differential amplifier in the input and a class-AB amplifier in the output, which are designed 

carefully. The proposed buffer amplifier utilizes a high-performance feedback circuit to 

increase the bandwidth. It also utilizes a comparator circuit to avoid wasting power. The 

designed circuit has been simulated in 180nm technology using HSPICE 2008.3. The 

simulation results show that the bandwidth, power consumption and power supply of the 

designed circuit are 1.14MHz, 1.64mW and 1.8V, respectively. 

Key words: buffer amplifier, liquid crystal displays, low-power amplifier, high-

bandwidth amplifier 

1. INTRODUCTION 

The increasing development of electronics made living in nowadays almost impossible 

without electronic devices such as cell phone, television, and tablet. Progress in demands 

of human nature has forced science to grow up in this field [1, 2]. Display is a common 

factor among these devices, which helps so much in improving the progress of them. The 

main reason for users and market attractiveness of progress in this field is that the display 

devices directly interface with the users.  

There are several improvements in this field, which can be categorized in two groups: 

(a) improvement in the circuit components, and (b) improvement in the hardware of 

displays. Buffer amplifiers are main part of the screens. They directly affect power 

consumption, settling time, speed, bandwidth and other parameters [3-5]. 

Developments in integrated circuit technology, particularly circuits related to displays 

and their improvements, indicate that there is a need to have a high-quality and high-speed 

circuit under low voltage source and low power consumption [3-5]. Recently, the technology 

and consumer tendency are portable devices such as cell phone and tablet. In this process, 

many attempts have been done to improve the circuits to achieve the objectives that 

                                                           
Received November 4, 2016; received in revised form February 20, 2017 

Corresponding author: Abdalhossein Rezai  

ACECR Institute of Higher Education, Isfahan Branch, Isfahan 84175-443, Iran 

(E-mail: rezaie@acecr.ac.ir) 



550 S. SADONI, A. REZAI 

generally focus on parameters such as the slew rate, voltage swing, bandwidth, maximum 

load current and low power consumption [3-5]. 

There are many attempts to increase the performance of displays such as [6-10]. In [6], 

the designed circuit works well in terms of charging and discharging speed of large 

capacitors, but it has low bandwidth. In [7] and [8], the designed circuits have a good 

bandwidth, but they do not have the ability to charge large capacitors well. In [9] developed 

circuit works well in terms of charging and discharging speed for relatively large capacitors, 

but it has a relatively high power consumption. The developed circuit in [10] works well in 

terms of charging and discharging speed of large capacitors. The power consumption is also 

relatively good, but it has low bandwidth.  

This paper presents a novel and efficient buffer amplifier. The proposed circuit consists 

of four parts, which are designed carefully. The proposed circuit has been simulated using 

HSPICE. The simulation results show that the proposed circuit provides an improvement in 

terms of bandwidth, slew rate and power consumption compared to other buffer amplifiers.  

The remaining of this paper is organized as follows: general description of the proposed 

buffer amplifier circuit is described in section 2. Circuit design techniques are discussed in 

section 3. In section 4, the simulation results of the proposed buffer amplifier are compared 

with other buffer amplifiers. Finally, section 5 concludes this paper.  

2. BUFFER AMPLIFIER 

The buffer amplifiers generally consist of several parts: an input amplifier, an 

intermediate amplifier, a feedback network and output stage for drives capacitive loads 

[11]. As it is presented in Figure 1, the first block is a differential amplifier.  The folded 

cascade amplifier is a commonly used amplifier in this stage; it is because in this amplifier 

due to differential inputs and outputs, the noise is eliminated. So, it has a better swing 

compared to telescopic amplifier. In the next block, in the output stage of class AB, the 

output circuit in [11] is utilized. Since two comparators are used behind the output 

transistors, the output efficiency is considerably increased, which prevents the static 

power dissipation. Figure 2 shows a schematic of the output circuit [11]. 

Feedback

Network 

Input 

Amp.
Out Stage

 

Fig. 1 A simplified buffer circuit schematic 



 High-bandwidth Buffer Amplifier for Liquid Crystal Display Applications 551 

 

Fig. 2 The circuit of the output stage 

In the third part, a feedback circuit is used. As it is shown in (1), using this feedback 

network, the bandwidth of the buffer amplifier is increased. Figure 3 shows a schematic of 

feedback network [8]. 

BW(new) = BW (old)(1+AB) (1) 

 

Fig. 3 The feedback network schematic  



552 S. SADONI, A. REZAI 

3. CIRCUIT DESIGN 

To implement the proposed buffer amplifier circuit, the design must begin by designing 

circuit of folded cascade differential amplifier. Then, the common mode feedback circuit 

should be added. Moreover, the gm constant circuit and the level shifter should be designed 

and added. To design the circuit, gm/Id method is used as shown in [11]. 

Circuit design is done using the graph of gm/Id in relation with Vov [11]. In gm/Id design 

methodology, the circuit is designed using a curve dependent on the utilized technology. 

So, the possibility to choose appropriate dimensions of transistors is provided more 

efficiently. This curve is independent of the dimensions, and it is relevant to all areas of 

the transistors. In addition, it can be used to design the dimensions of all transistors in the 

utilized technology. It should be noted that this ratio is directly related to the coefficient 

of carrier mobility in transistors. According to differences in the n-type transistors, the p-

type transistors are used. Thus, in designing swing with respect to transistor and the 

utilized technology, vov must be considered differently. 

Figure 4 shows the gm/Id -vov according to [11] for n-type transistors. 

 

Fig. 4  The simulation results for gm/Id to vov for n-type transistors 

In this circuit, swing voltage is 1.2Volt. With this limitation, over drive voltages are 

selected as shown in (2) and (3):  

Vovn=0.13Volt 
(2)                        

Vovp=0.17Volt (3) 

                                             

 Using the same way, p-type transistors and feedback circuit are designed. In the 

feedback circuit design, one thing is necessary: the low current branches should be 

considered. So, the power consumption of the entire circuit does not increase. Feedback 

circuit is shown in Figure 5. 

 



 High-bandwidth Buffer Amplifier for Liquid Crystal Display Applications 553 

 

Fig. 5 The utilized circuit for the feedback in the proposed buffer amplifier 

The general circuit of the proposed buffer amplifier without output stage is shown in 

figure 6. that utilizes two circuits as shown in Figures 2 and 3.  

It should be noted that figure 2 depicts output power stage. To ensure the other driving 

devices MO1 and MO2 to stay off during static operation and to save power consumption, 

the DC currents of MC1 and MC4 are designed to be slightly lower than the nominal 

currents of MC2 and MC3, respectively. The above specification is fulfilled by the 

following design conditions: 

n

MC

p

MC

bias
L

W
L

W

L

W

bias
L

W
L

W

)(

)()(

)(

)(
21




  

(4) 

p

MC

n

MC

bias
L

W
L

W

L

W

bias
L

W
L

W

)(

)()(

)(

)(
34




 

                                                                   

(5) 

 

 



554 S. SADONI, A. REZAI 

 

Fig. 6 The general circuit of the proposed buffer amplifier 



 High-bandwidth Buffer Amplifier for Liquid Crystal Display Applications 555 

4.  SIMULATION RESULTS 

The designed circuit that is shown in figure 6 is simulated in 180nm technology using 

HSPICE 2008.3 with 1.8 volt power supply. The simulation results for the slew rate and 

bandwidth are shown in Fig. 7 and Fig. 8, respectively.  

 

Fig. 7 The simulation results for the slew rate of the proposed circuit 

 

Fig. 8 The simulation results for the bandwidth of the proposed circuit 

Table 1 summarizes the simulation results of the proposed buffer amplifier in HSPICE 

in comparison with other buffer amplifiers [6-10]. 

Based on our simulation results, which are shown in table 1, the developed circuit 

provides an improvement in comparison with [6-10] in terms of bandwidth, power 

consumption and slew rate. 



556 S. SADONI, A. REZAI 

Table 1 The comparative table for amplifiers 

Reference Power 

consumption 

(mw) 

Maximum 

capacitive load 

(pF) 

CMOS 

technology 

(nm) 

Supply 

voltage 

(v) 

Bandwidth 

(MHz) 

Slew 

rate 

(v/µs) 

[6] 1 680 600 4 0.1      -- 

[7] -- 15 350 2 2.3      -- 

[8] -- 200 500    3.3 -- -- 

[9] -- 20000 130 -- 1        0.083 

[10]      6.47 1000 500 5 0.503 5.7 

This paper      1.64 1000 180    1.8 1.14   378 

5. CONCLUSION 

Low-power and high-bandwidth design are trends in the circuit design [4-5]. In this 

paper, a novel buffer amplifier has been proposed to be used in the liquid crystal display 

applications. The proposed buffer amplifier is composed of four parts, which have been 

designed carefully. The proposed circuit has been simulated using HSPICE. The simulation 

results showed that the proposed circuit provides an improvement in terms of bandwidth, 

power consumption and slew rate compared to [6-10]. Therefore, the proposed buffer 

amplifier architecture has a huge potential to be an efficient architecture for hardware 

implementation of buffer amplifier. 

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