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![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 252
STUDY AND IMPLEMENTATION OF COMPARATOR IN CMOS 50NM
TECHNOLOGY
Dharmendra B. Mavani1
, Arun B. Nandurbarkar2
1
M.E Student, 2
Associate Professor, Department of Electronics & Communication, L.D.College of Engineering,
Gujarat, India
Abstract
This paper describes the comparator circuits used in FLASH Analog to digital converter (ADC). The performance of FLASH ADC is
greatly influenced by the choice of comparator. In this paper, first a single ended “Threshold Inverter Quantizer” (TIQ) is presented.
The TIQ comparator is based on a CMOS inverter cell, in which voltage transfer characteristics (VTC) are changed by systematic
transistor sizing. However, TIQ comparator is very sensitive to power supply noise. Another comparator circuit presented in this
paper is “Two stage open loop comparator”. It is implemented in 50 nm CMOS Technology. Pre-simulation of comparator is done in
LT-Spice and post layout simulation is done in Microwind 3.1.
Keywords: CMOS, Comparator, TIQ (Threshold Inverter Quantizer), LT-Spice.
-----------------------------------------------------------------------***-----------------------------------------------------------------------
1. INTRODUCTION
The comparator is a circuit that compares one analog signal
with another analog signal or a reference voltage and outputs a
binary signal based on the comparison [1,2]. Comparator is the
“Heart” of the Analog to digital converter. The comparator is
basically a 1-bit analog-to-digital converter. Fig. 1 shows
general block diagram and Fig. 2 shows symbol of
comparator.
Fig -1: Block diagram of a comparator
Fig -2: Symbol of a comparator
The comparator is a critical part of almost all kind of analog-
to-digital (ADC) converters. Depending on the type and
architecture of the comparator, the comparator can have
significant impact on the performance of the target
application. The speed and resolution of an ADC is directly
affected by the comparator input offset voltage, the delay and
input signal range. Some basic applications of comparators are
analog-to-digital conversion, function generation, signal
detection and neural networks etc.
The following study gives an overview of some of the
different comparator topologies examined during the pre-
study. Here, first TIQ comparator is described. TIQ
comparator has single ended input and reference voltages are
changed where there is a noise in the power supply voltage.
Then Two stage open loop comparator is presented in this
paper.
This paper is organized into four sections. Section 2 deals
with the design of TIQ comparator. Section 3 discuss “Two
stage open loop comparator” and section 4 gives simulation
results of the two stage open loop comparator.
2. TIQ COMPARATOR
The use of two cascading inverters as a voltage comparator is
the reason for the technique's name. The voltage comparators
compare the input voltage with internal reference voltages,
which are determined by the transistor sizes of the inverters.
Hence, we do not need the resistor ladder circuit used in a
conventional flash ADC. Comparator’s role is to convert an
input voltage (Vin) into a logic `1' or `0' by comparing a
reference voltage (Vref) with the Vin. If Vin is greater than
Vref , the output of the comparator is `1', otherwise `0'. The](https://image.slidesharecdn.com/studyandimplementationofcomparatorincmos50nm-140811024942-phpapp01/75/Study-and-implementation-of-comparator-in-cmos-50-nm-1-2048.jpg)
![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 253
TIQ comparator uses two cascading CMOS inverters as a
comparator for high speed and low power consumption as
shown in Fig. 3.
The inverter threshold (Vm) is defined as the Vin = Vout in
the Voltage Transfer Characteristics (VTC) of an inverter as
shown in Fig. 4. We can set inverter threshold voltage from
following equation:
Vm = (r(Vdd+│Vtp│)+Vtn) / (1+r)
with r = (kp/kn)1/2
Fig -3: TIQ Comparator
Fig -4: Voltage Transfer characteristic curve
Where Vtn and Vtp are the threshold voltages for NMOS and
PMOS devices, respectively.
Kn = (W/L)n . μn COX
Kp = (W/L)p . μp COX
The second inverter is used to increase voltage gain and to
prevent an unbalanced propagation delay [4]. With a fixed
length of the PMOS and NMOS devices, we can get desired
values by changing only the width of the PMOS and NMOS
transistors. We assume that both transistors are in the active
region, the gate oxide thickness (Cox) for both transistors are
same, and the lengths of both transistors (Lp and Ln) are also
the same. So, Vm is shifted depending the transistor width
ratio (Wp/Wn). That is, increasing Wp makes Vm larger, and
increasing Wn results in Vm being smaller on the VTC.
However, to use the CMOS inverter as a voltage comparator,
we should check the sensitivity of Vm to other parameters,
which are ignored for correct operation of the TIQ
comparator. In a mixed-signal design, the ignored parameters -
threshold voltages of both transistors, electron and hole
mobility, and power supply voltage - are not fixed at a
constant value. There are some main disadvantages of the TIQ
approach:
1. It is a single-ended structure.
2. It requires a separate reference power supply voltage for
analog part only due to poor power supply rejection ratio.
3. It has slight changes in linearity measures (DNL, INL) and
the maximum analog input signal range due to process
parameter variations. These problems can easily be handled by
front end signal conditioning circuitry.
4. It requires a S/H at the analog input to increase the
performance and to reduce the power consumption during
metastable stage.
3. TWO STAGE OPEN LOOP COMPARATOR
In previous section, we have seen comparator circuits which
generates references voltages internally based on transistor
size. Now, in this section, we will study about two stage open
loop comparator circuit which has two differential inputs. This
comparator consists input stage, differential amplifier and
output stage as shown in Fig. 5. The advantage of this circuit
is that the circuit consumes minimal number of transistor and
thus the circuit area is small [5].
Fig -5: Two stage open loop comparator](https://image.slidesharecdn.com/studyandimplementationofcomparatorincmos50nm-140811024942-phpapp01/75/Study-and-implementation-of-comparator-in-cmos-50-nm-2-2048.jpg)
![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 254
The two-stage op amp without compensation is an excellent
implementation of a high-gain, open-loop comparator [2].
Comparator requires differential input and sufficient gain to be
able to achieve the desired resolution. So, two stage op-amp
makes an excellent implementation of the comparator. A
simplifications occurs because comparator will generally be
used in an open loop mode and therefore it is not necessary to
compensate the comparator. In fact, it is preferred not to
compensate the comparator so that it has the large bandwidth
possible, which will give a faster response.
The first item of interest is the values of VOH and VOL for
the two stage comparator. Since the output stage is a current-
sink inverter, maximum output voltage can be expressed as,
The minimum output voltage is
VOL = VSS.
We can design two stage open loop comparator from
following formulas:
(W6/L6) = (2I6)/(Kp’*(VSD6(sat))2
) ;
(W7/L7) = (2I7)/(KN’*(VDS7(sat))2
) ;
(W3/L3) = (W4/L4) = (I5)/(Kp’*(VSG3-|VTP|)2
) ;
(W1/L1) =(W2/L2) = gm1
2
/(KN*I5);
(W5/L5) = (2I5)/(KN’*(VDS5(sat))2
) ;
Where, I6=I7= (|Pll|*Cll)/(λn + λp);
|Pll| = 1/(tp*(mk)1/2
) ;
I5= (2*I7*Cl)/Cll;
4. SIMULATION RESULTS
In this section, the functional and post-layout simulation
results of the two stage open loop comparator have been
presented. There are two parts of result. First, functional
simulation of comparator is done in LT-Spice software using
50 nm CMOS technology. Then, post-layout of comparator is
done in Microwind 3.1 using 50 nm CMOS technology.
4.1 Functional Simulation
Table 1 denotes the short-channel MOSFET parameters for
general analog design with a scale factor of 50 nm (scale=50e-
9
). In Fig. 5, a proposed comparator circuit is shown. The
frequency of the analog signal input is varied in the way that
the minimal propagation time delay is obtained. For the
functionality purpose as shown in Fig. 6(a), the reference
voltage, Vref is set to 0.8V and the supply voltage is 1.1V. As
illustrated in Fig. 6(a), if the input voltage is higher than 0.8V,
the output of comparator is high and vice versa. Same way, in
Fig. 6(b), Vref is set to 0.4V.
Table -1: MOSFET model parameters for 50nm CMOS
Technology
(a)
(b)
Fig -6: Output of a comparator (a) Vref = 0.8V (b) Vrf = 0.4V
Short-Channel MOSFET parameters
VDD=1.1V and a scale factor of 50 nm
Parameter NMOS PMOS
Bias Current, ID 10µA 10µA
VDS,sat and VSD,sat 50 mV 50 mV
VGS and VSG 350 mV 350 mV
VTHN and VTHP 280 mV 280 mV
vsatn and vsatp 110 × 103
m/s 90 × 103
m/s
Tox 14Å 14Å
C’ox 25 f F/µm2
25 f F/µm2](https://image.slidesharecdn.com/studyandimplementationofcomparatorincmos50nm-140811024942-phpapp01/75/Study-and-implementation-of-comparator-in-cmos-50-nm-3-2048.jpg)
![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 255
4.2 Layout of Comparator
Since, the design automation for analog and mixed signal
circuits has not evolved as much as its digital counterpart;
thereby designers are often forced to do the full-custom
designs. Thus it is still a designer's experience that produces
effective transistor sizing and layout strategies. A fully
systematic approach for producing an optimal analog layout is
something that is still under development. The layout of the
Comparator is done with the primary objective of reducing the
area overhead to an optimum level, while maintaining a
simplistic approach. Fig. 7 shows layout of proposed
comparator using 50 nm with 0.7V power supply. For the
functionality purpose as shown in Fig. 8, the reference
voltage, Vref is set to 0.5V. As illustrated in Fig. 8, if the input
voltage is higher than 0.5V, the output of comparator is high
and vice versa [9].
Fig -7: Layout view of a comparator
Fig -8: Output of a comparator
5. CONCLUSIONS
In this paper, a comparator circuit is proposed. There are some
disadvantages of TIQ comparator in some applications as
stated in section 2. Two stage open loop comparator is
presented using 50nm CMOS technology. This architecture
can be extended to medium-to-high resolution applications
because the simplicity of the circuit. Comparator is a main part
of flash ADC. As a future work, we can design low power
flash ADC using this comparator design.
REFERENCES
[1]. R. J. Baker, H. W. Li and D.E Boyce, CMOS Circuit
Design, Layout And Simulation, New York, IEEE Press,
2008.
[2]. Phillip E. Allen and Douglas R. Holberg, CMOS Analog
Circuit Design, Oxford University Press, Inc. 2002.
[3]. Sung-mo Kang, Yusuf Leblebici, “CMOS Digital
Integrated Circuits: Analysis and Design”, third edition, Tata
McGraw-Hill edition 2003.
[4]. Dhrubajyoti Basu, Sagar Mukherjee, Dipankar Saha,
Sayan Chatterjee, C. K. Sarkar, ”An Optimized Analog
Layout for a Low Power 3-bit Flash Type ADC modified with
the CMOS Inverter based Comparator Designs”, IEEE
Conference on Circuits, Power and Computing Technologies,
2013.
[5]. Pradeep Kumar, Amit Kolhe, "Design & Implementation
of Low Power 3-bit Flash ADC in 0.18µm CMOS",
International Journal of Soft Computing and Engineering
(IJSCE), ISSN: 2231-2307, Volume-1, Issue-5, November
2011.
[6]. Sagar Mukherjee, Dipankar Saha, Posiba Mostafa, Sayan
Chatterjee, C. K. Sarkar, "A 4-bit Asynchronous Binary
Search ADC for Low Power, High Speed Applications,
International Symposium on Electronic System Design, 2012.
[7]. Sandner, C., et al. (2008). “A 6-bit, 1.2-GSps low-power
flash-ADC in 0.13 lm digital CMOS”,IEEE Journal of Solid-
StateCircuits, 40(7), 1499–1504.](https://image.slidesharecdn.com/studyandimplementationofcomparatorincmos50nm-140811024942-phpapp01/75/Study-and-implementation-of-comparator-in-cmos-50-nm-4-2048.jpg)
![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 256
[8]. Sudakar S. Chauhan, S. Manabala, S.C. Bose, and R.
Chandel, "A New Approach To Design Low Power CMOS
Flash A/D Converter", International Journal of VLSI design &
Communication Systems (VLSICS), Vol.2, No.2, June 2011,
p.100.
[9]. E. Sicard, S. M. Aziz, Microwind application notes for 90-
nm, 65-nm, 45-nm and 32-nm technologies,
http://www.microwind.org.](https://image.slidesharecdn.com/studyandimplementationofcomparatorincmos50nm-140811024942-phpapp01/75/Study-and-implementation-of-comparator-in-cmos-50-nm-5-2048.jpg)
Uploaded byeSAT Publishing House
Study and implementation of comparator in cmos 50 nm
This document discusses the design and implementation of two types of comparators used in flash analog-to-digital converters (ADC) with a focus on a single-ended threshold inverter quantizer (TIQ) and a two-stage open-loop comparator using 50nm CMOS technology. It highlights the performance implications of each comparator, their configurations, and provides simulation results from LT-spice and Microwind software. The paper concludes that the two-stage open-loop comparator is simpler and can be extended for medium-to-high resolution applications.
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Study and implementation of comparator in cmos 50 nm
- 1. IJRET: International Journalof Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 __________________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 252 STUDY AND IMPLEMENTATION OF COMPARATOR IN CMOS 50NM TECHNOLOGY Dharmendra B. Mavani1 , Arun B. Nandurbarkar2 1 M.E Student, 2 Associate Professor, Department of Electronics & Communication, L.D.College of Engineering, Gujarat, India Abstract This paper describes the comparator circuits used in FLASH Analog to digital converter (ADC). The performance of FLASH ADC is greatly influenced by the choice of comparator. In this paper, first a single ended “Threshold Inverter Quantizer” (TIQ) is presented. The TIQ comparator is based on a CMOS inverter cell, in which voltage transfer characteristics (VTC) are changed by systematic transistor sizing. However, TIQ comparator is very sensitive to power supply noise. Another comparator circuit presented in this paper is “Two stage open loop comparator”. It is implemented in 50 nm CMOS Technology. Pre-simulation of comparator is done in LT-Spice and post layout simulation is done in Microwind 3.1. Keywords: CMOS, Comparator, TIQ (Threshold Inverter Quantizer), LT-Spice. -----------------------------------------------------------------------***----------------------------------------------------------------------- 1. INTRODUCTION The comparator is a circuit that compares one analog signal with another analog signal or a reference voltage and outputs a binary signal based on the comparison [1,2]. Comparator is the “Heart” of the Analog to digital converter. The comparator is basically a 1-bit analog-to-digital converter. Fig. 1 shows general block diagram and Fig. 2 shows symbol of comparator. Fig -1: Block diagram of a comparator Fig -2: Symbol of a comparator The comparator is a critical part of almost all kind of analog- to-digital (ADC) converters. Depending on the type and architecture of the comparator, the comparator can have significant impact on the performance of the target application. The speed and resolution of an ADC is directly affected by the comparator input offset voltage, the delay and input signal range. Some basic applications of comparators are analog-to-digital conversion, function generation, signal detection and neural networks etc. The following study gives an overview of some of the different comparator topologies examined during the pre- study. Here, first TIQ comparator is described. TIQ comparator has single ended input and reference voltages are changed where there is a noise in the power supply voltage. Then Two stage open loop comparator is presented in this paper. This paper is organized into four sections. Section 2 deals with the design of TIQ comparator. Section 3 discuss “Two stage open loop comparator” and section 4 gives simulation results of the two stage open loop comparator. 2. TIQ COMPARATOR The use of two cascading inverters as a voltage comparator is the reason for the technique's name. The voltage comparators compare the input voltage with internal reference voltages, which are determined by the transistor sizes of the inverters. Hence, we do not need the resistor ladder circuit used in a conventional flash ADC. Comparator’s role is to convert an input voltage (Vin) into a logic `1' or `0' by comparing a reference voltage (Vref) with the Vin. If Vin is greater than Vref , the output of the comparator is `1', otherwise `0'. The
- 2. IJRET: International Journalof Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 __________________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 253 TIQ comparator uses two cascading CMOS inverters as a comparator for high speed and low power consumption as shown in Fig. 3. The inverter threshold (Vm) is defined as the Vin = Vout in the Voltage Transfer Characteristics (VTC) of an inverter as shown in Fig. 4. We can set inverter threshold voltage from following equation: Vm = (r(Vdd+│Vtp│)+Vtn) / (1+r) with r = (kp/kn)1/2 Fig -3: TIQ Comparator Fig -4: Voltage Transfer characteristic curve Where Vtn and Vtp are the threshold voltages for NMOS and PMOS devices, respectively. Kn = (W/L)n . μn COX Kp = (W/L)p . μp COX The second inverter is used to increase voltage gain and to prevent an unbalanced propagation delay [4]. With a fixed length of the PMOS and NMOS devices, we can get desired values by changing only the width of the PMOS and NMOS transistors. We assume that both transistors are in the active region, the gate oxide thickness (Cox) for both transistors are same, and the lengths of both transistors (Lp and Ln) are also the same. So, Vm is shifted depending the transistor width ratio (Wp/Wn). That is, increasing Wp makes Vm larger, and increasing Wn results in Vm being smaller on the VTC. However, to use the CMOS inverter as a voltage comparator, we should check the sensitivity of Vm to other parameters, which are ignored for correct operation of the TIQ comparator. In a mixed-signal design, the ignored parameters - threshold voltages of both transistors, electron and hole mobility, and power supply voltage - are not fixed at a constant value. There are some main disadvantages of the TIQ approach: 1. It is a single-ended structure. 2. It requires a separate reference power supply voltage for analog part only due to poor power supply rejection ratio. 3. It has slight changes in linearity measures (DNL, INL) and the maximum analog input signal range due to process parameter variations. These problems can easily be handled by front end signal conditioning circuitry. 4. It requires a S/H at the analog input to increase the performance and to reduce the power consumption during metastable stage. 3. TWO STAGE OPEN LOOP COMPARATOR In previous section, we have seen comparator circuits which generates references voltages internally based on transistor size. Now, in this section, we will study about two stage open loop comparator circuit which has two differential inputs. This comparator consists input stage, differential amplifier and output stage as shown in Fig. 5. The advantage of this circuit is that the circuit consumes minimal number of transistor and thus the circuit area is small [5]. Fig -5: Two stage open loop comparator
- 3. IJRET: International Journalof Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 __________________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 254 The two-stage op amp without compensation is an excellent implementation of a high-gain, open-loop comparator [2]. Comparator requires differential input and sufficient gain to be able to achieve the desired resolution. So, two stage op-amp makes an excellent implementation of the comparator. A simplifications occurs because comparator will generally be used in an open loop mode and therefore it is not necessary to compensate the comparator. In fact, it is preferred not to compensate the comparator so that it has the large bandwidth possible, which will give a faster response. The first item of interest is the values of VOH and VOL for the two stage comparator. Since the output stage is a current- sink inverter, maximum output voltage can be expressed as, The minimum output voltage is VOL = VSS. We can design two stage open loop comparator from following formulas: (W6/L6) = (2I6)/(Kp’*(VSD6(sat))2 ) ; (W7/L7) = (2I7)/(KN’*(VDS7(sat))2 ) ; (W3/L3) = (W4/L4) = (I5)/(Kp’*(VSG3-|VTP|)2 ) ; (W1/L1) =(W2/L2) = gm1 2 /(KN*I5); (W5/L5) = (2I5)/(KN’*(VDS5(sat))2 ) ; Where, I6=I7= (|Pll|*Cll)/(λn + λp); |Pll| = 1/(tp*(mk)1/2 ) ; I5= (2*I7*Cl)/Cll; 4. SIMULATION RESULTS In this section, the functional and post-layout simulation results of the two stage open loop comparator have been presented. There are two parts of result. First, functional simulation of comparator is done in LT-Spice software using 50 nm CMOS technology. Then, post-layout of comparator is done in Microwind 3.1 using 50 nm CMOS technology. 4.1 Functional Simulation Table 1 denotes the short-channel MOSFET parameters for general analog design with a scale factor of 50 nm (scale=50e- 9 ). In Fig. 5, a proposed comparator circuit is shown. The frequency of the analog signal input is varied in the way that the minimal propagation time delay is obtained. For the functionality purpose as shown in Fig. 6(a), the reference voltage, Vref is set to 0.8V and the supply voltage is 1.1V. As illustrated in Fig. 6(a), if the input voltage is higher than 0.8V, the output of comparator is high and vice versa. Same way, in Fig. 6(b), Vref is set to 0.4V. Table -1: MOSFET model parameters for 50nm CMOS Technology (a) (b) Fig -6: Output of a comparator (a) Vref = 0.8V (b) Vrf = 0.4V Short-Channel MOSFET parameters VDD=1.1V and a scale factor of 50 nm Parameter NMOS PMOS Bias Current, ID 10µA 10µA VDS,sat and VSD,sat 50 mV 50 mV VGS and VSG 350 mV 350 mV VTHN and VTHP 280 mV 280 mV vsatn and vsatp 110 × 103 m/s 90 × 103 m/s Tox 14Å 14Å C’ox 25 f F/µm2 25 f F/µm2
- 4. IJRET: International Journalof Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 __________________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 255 4.2 Layout of Comparator Since, the design automation for analog and mixed signal circuits has not evolved as much as its digital counterpart; thereby designers are often forced to do the full-custom designs. Thus it is still a designer's experience that produces effective transistor sizing and layout strategies. A fully systematic approach for producing an optimal analog layout is something that is still under development. The layout of the Comparator is done with the primary objective of reducing the area overhead to an optimum level, while maintaining a simplistic approach. Fig. 7 shows layout of proposed comparator using 50 nm with 0.7V power supply. For the functionality purpose as shown in Fig. 8, the reference voltage, Vref is set to 0.5V. As illustrated in Fig. 8, if the input voltage is higher than 0.5V, the output of comparator is high and vice versa [9]. Fig -7: Layout view of a comparator Fig -8: Output of a comparator 5. CONCLUSIONS In this paper, a comparator circuit is proposed. There are some disadvantages of TIQ comparator in some applications as stated in section 2. Two stage open loop comparator is presented using 50nm CMOS technology. This architecture can be extended to medium-to-high resolution applications because the simplicity of the circuit. Comparator is a main part of flash ADC. As a future work, we can design low power flash ADC using this comparator design. REFERENCES [1]. R. J. Baker, H. W. Li and D.E Boyce, CMOS Circuit Design, Layout And Simulation, New York, IEEE Press, 2008. [2]. Phillip E. Allen and Douglas R. Holberg, CMOS Analog Circuit Design, Oxford University Press, Inc. 2002. [3]. Sung-mo Kang, Yusuf Leblebici, “CMOS Digital Integrated Circuits: Analysis and Design”, third edition, Tata McGraw-Hill edition 2003. [4]. Dhrubajyoti Basu, Sagar Mukherjee, Dipankar Saha, Sayan Chatterjee, C. K. Sarkar, ”An Optimized Analog Layout for a Low Power 3-bit Flash Type ADC modified with the CMOS Inverter based Comparator Designs”, IEEE Conference on Circuits, Power and Computing Technologies, 2013. [5]. Pradeep Kumar, Amit Kolhe, "Design & Implementation of Low Power 3-bit Flash ADC in 0.18µm CMOS", International Journal of Soft Computing and Engineering (IJSCE), ISSN: 2231-2307, Volume-1, Issue-5, November 2011. [6]. Sagar Mukherjee, Dipankar Saha, Posiba Mostafa, Sayan Chatterjee, C. K. Sarkar, "A 4-bit Asynchronous Binary Search ADC for Low Power, High Speed Applications, International Symposium on Electronic System Design, 2012. [7]. Sandner, C., et al. (2008). “A 6-bit, 1.2-GSps low-power flash-ADC in 0.13 lm digital CMOS”,IEEE Journal of Solid- StateCircuits, 40(7), 1499–1504.
- 5. IJRET: International Journalof Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 __________________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 256 [8]. Sudakar S. Chauhan, S. Manabala, S.C. Bose, and R. Chandel, "A New Approach To Design Low Power CMOS Flash A/D Converter", International Journal of VLSI design & Communication Systems (VLSICS), Vol.2, No.2, June 2011, p.100. [9]. E. Sicard, S. M. Aziz, Microwind application notes for 90- nm, 65-nm, 45-nm and 32-nm technologies, http://www.microwind.org.