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Engineering, Technology & Applied Science Research Vol. 6, No. 6, 2016, 1294-1296 1294  
  

www.etasr.com Soltani: A Tunable Low Noise Active Bandpass Filter Using a Noise Canceling Techniqu 

 

A Tunable Low Noise Active Bandpass Filter Using  

a Noise Canceling Technique 
 

N. Soltani  
Department of Electrical Engineering, Malayer Branch 

Islamic Azad University 
 Malayer, Iran  

soltani.2000@yahoo.com 
 

 

Abstract—A monolithic tunable low noise active bandpass filter is 
presented in this study. Biasing voltages can control the center 
frequency and quality factor. By keeping the gain constant, the 
center frequency shift is 300 MHz. The quality factor can range 
from 90 to 290 at the center frequency. By using a noise 
cancelling circuit, noise is kept lower than 2.8 dB. The proposed 
filter is designed using MMIC technology with a center frequency 
of 2.4 GHz and  a power consumption of 180 mW. ED02AH 
technology is used to simulate the circuit elements. 

Keywords-Microwave Monolithic integrated circuit (MMIC;, 
Bandpass filter; quality factor; noise cancelling 

 

I. INTRODUCTION  
A good Noise Figure (NF) performance in most circuit is 

necessary. For example, a good Low Noise Amplifier (LNA) 
design becomes very important because it is one of the key 
circuit blocks in a radio receiver system. Since the LNA can be 
directly added to the first stage in the receive path, it usually 
dominates the NF and the bandwidth in the receiver, and a 
variable gain LNA can improve the dynamic range of the 
whole receiver [1]. Especially in mobile communication or 
video electronic products, an LNA with good NF performance 
wide bandwidth and larger dynamic range in its specification is 
needed. Various applications of microwave frequencies have 
found special attention in different criteria. Tunable filters in 
high frequency ranges have several advantages. They can 
reduce the complexity of a system avoiding the introduction of 
filter banks. Multi band telecommunication systems, 
radiometers, and wideband radar systems are some of the 
applications of such filters. Previous tuning methods include 
adjusting the cavity dimensions of the resonators or altering the 
resonant frequency of a ferromagnetic yttrium-iron-garnet 
element. New approaches are based on solid state varactor 
diodes [2, 3]. In this paper, a tunable low noise active bandpass 
filter using a noise canceling circuit is designed. We propose 
the design of a bandpass filter in which its NF is better than 2.8 
dB and its gain is more than 20 dB. Two DC voltages are used 
to bias varactor diode in such a way that the center frequency 
and quality factor would be controlled using these voltages [4]. 

II. FILTER STRUCTURE 
Figure 1 shows the block diagram of the desired filter. This 

filter is consisted of six parts: an amplifier, the LC tank, the 
negative conductance and the noise canceling circuit. 
Moreover, common gate and common drain structures are used 
to realize input and output impedance matching respectively. 
The resulted bandpass filter is shown in Figure 2. In this filter, 
negative conductance is added to the lossy LC tank. As a result, 
quality factor increases. In the proposed circuit, the 
feedforward noise-canceling technique [5, 6] is used. The 
circuit of the feedforward noise canceling technique is 
composed of an input transistor, a resistance, feedforward 
voltage amplifier and one adder. By using common drain and 
common source structure, the noise of input transistor is 
effectively canceled, but again in this technique the noise of the 
feedforward voltage amplifier and the adder is not canceled. 
Moreover, the noise of resistance is partly contributed in the 
signal. 

 
Fig. 1.  Block diagram of desired filter 

III. SIMULATION RESULTS 
Simulation results are shown in Figure 3 to illustrate gain, 

input and output impedance matching and noise figure 
respectively. By inspections of these figures, one can see that 
the scattering parameters S11, S22 are in the desirable situation 
and by using the noise canceling circuit, the noise figure is kept 
under 2.8dB.   

IV. FREQUENCY DISPLACEMENT  
We use the biasing voltage of varactor diodes to perform 

the frequency sweep. Vf in Figure 2 biased the varactor diode 
and the capacity would change due to the applied voltage. This 



Engineering, Technology & Applied Science Research Vol. 6, No. 6, 2016, 1294-1296 1295  
  

www.etasr.com Soltani: A Tunable Low Noise Active Bandpass Filter Using a Noise Canceling Techniqu 

 

voltage sweeps the frequency and shifts the center frequency. 
The frequency displacement is about 300 MHz. The simulation 
results and scattering parameters are illustrated in Figure 4. By 
inspections of these figures, one can see that the scattering 
parameters are in desirable situation. The stability of this filter 

has been studied by Rollett coefficient (K). This coefficient is 
always greater than one [7]. Table I shows the magnitude of Vf 
in each center frequency. Also measured quality factors and 
gain are presented. 

  

 
Fig. 2.  The circuit of low noise active bandpass filter 

 
  

 

 

 
Fig. 3.  Simulation results (a) gain parameter; (b) scattering parameters 

S11, S22 ;(c) noise figure 

 

 

 

 
Fig. 4.  Frequency displacement, scattering parameter S11 and S22 and 

stability factor of the low noise bandpass filter 

(a) 

Noise Cancelling Circuit 

(b) 

(c) 



Engineering, Technology & Applied Science Research Vol. 6, No. 6, 2016, 1294-1296 1296  
  

www.etasr.com Soltani: A Tunable Low Noise Active Bandpass Filter Using a Noise Canceling Techniqu 

 

TABLE I.  VALUE OF VF, FERECUENCY VARIATION, GAIN AND QUALITY 
FACTOR OF THE BANDPASS FILTER  

Vf1(V) f0 (GHz) Gain (dB) Q 
4.2 2.219 10.02 43 
4.4 2.475 16.23 58 
5 2.413 13.05 53 

5.2 2.477 10.00 48 
5.5 2.515 8.76 19 

V. INCREASING THE QUALITY FACTOR  
By using Va that is shown in Figure 2, in a constant 

frequency, considerable improvement of gain and quality factor 
would be possible. This voltage is responsible to control the 
quality factor. As shown in Figure 5 changing this voltage at 
2.4 GHz gives considerable increment of quality factor from 90 
to 290. We ignored the frequency shift of 50 MHz and the 
stability factor is also in desirable situation. Va, gain, and 
quality factor of each filter are shown in Table II. 

 

 
Fig. 5.  Quality factor increment and stability factor at 2.4 GHz 

TABLE II.  VALUE OF VA, GAIN AND QUALITY FACTOR OF BANDPASS 
FILTER 

Va1 (v) Gain (dB) Q 
1 13.30 296 
2 14.02 219 
3 15.11 177 
4 15.85 153 
5 16.34 131 
6 18.00 118 
7 20.12 105 
8 22.78 96 

VI. STATISTICAL RESULTS 
In this section we simultaneously exerted 5% tolerance on 

the measure of 3 elements including resistor, capacitor, and 
transistor width in the low noise bandpass filter. These 
variations were completely random. Figure 6 shows the 
simulation results of the combination of ten different situations.  

 

 
Fig. 6.  Scattering parameters as a result of 5% tolerance 

VII. CONCLUCION 
A tunable low noise active bandpass filter using 

feedforward noise canceling technique is presented. 
Controlling the center frequency and quality factor is 
investigated using two biasing voltages. The center frequency 
shift is 300 MHz and Considerable improvement of quality 
factors is achieved (from 90 to 290). Future work should focus 
on the estimation of the desired biasing voltages of varactor 
diodes using a neural network to obtain the specific quality 
factor and center frequency. Also, on using active inductor to 
decrease the chip area. Other noise filters technologies such as 
BICMOS or RFCMOS should be evaluated in the same structure. 

REFERENCES 
[1] I. Mehr, S. Rose, S. Nesterenko, D. Paterson, R. Schreier, H. L’Bahy, S. 

Kidambi, M. Elliott, S. Puckett, “A dual- conversion tuner for multi-
standard terrestrial and cable reception”, IEEE VLSI Circuits Symp Dig  
pp. 340-343, 2005 

[2] C . Musoll-Anguiano, I . Llamas-Garro, Z . Brito-Brito, L. Pradelll, A. 
Corona-Chavez, “Characterizing a Tune All Bandstop Filter”, IEEE 
MTT-S International Microwave Workshop  Series on Signal Integrity 
and High-Speed Interconnects, pp. 55-58, 2009. 

[3] A. R. Brown, G. M. Rebeiz, “A Varactor Tuned RF Filter”, IEEE 
Transactions on Microwave Theory and Techniques, Vol. 46, No. 7, pp. 
1157-1160, 2000  

[4] A. Alahyari, A. Habibzadeh, M. Dousti,  “Tunable Active Dual-Band 
Bandpass Filter Design Using MMIC Technology”, International Journal 
of Engineering & Technology, Vol. 11, No. 1, pp. 11-16, 2011  

[5] F. Bruccoleri, E. A. M. Klumperink, B. Nauta, “Wide-band CMOS low-
noise amplifier exploiting thermal noise canceling”, IEEE Journal of 
Solid-State Circuits, Vol. 39, No. 2, pp. 275-282, 2004 

[6] W. Keping, W. Zhigong, “A broadband noise-canceling CMOS 
differential LNA for 50–860MHz TV tuner”, International Conference 
on Microwave and Millimeter Wave Technology, 20-22 Dec. 2007 

[7] M. Dousti, P. Langari, "A Tunable Active Recursive Filter For 
Communication Systems in SiGe BiCMOS”, AICT 2009. International 
Conference on Application of Information and Communication 
Technologies, 14-16 Oct. 2009