New implementation of high linear LNA using derivative superposition method

ARTICLE IN PRESS Microelectronics Journal 40 (2009) 197–201

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Microelectronics Journal journal homepage: www.elsevier.com/locate/mejo

New implementation of high linear LNA using derivative superposition method$ Shuguang Han a, Baoyong Chi b,, Zhihua Wang b a b

Department of Electronic Engineering, Tsinghua University, Beijing 100084, China Institute of Microelectronics, Tsinghua University, Beijing 100084, China

a r t i c l e in fo

abstract

Article history: Received 4 October 2007 Received in revised form 16 September 2008 Accepted 16 September 2008 Available online 20 November 2008

New implementation of a high linear low-noise amplifier (LNA) using the improved derivative superposition (DS) method is proposed. The input stage is formed by two transistors connected in parallel. One transistor is biased in the strong inversion region as usual and another one is biased in the moderate inversion region instead of the weak inversion region, thus allowing a feasible source degeneration inductance at the sources of the two transistors to achieve a good input impedance matching and low noise figure (NF) while keeping high third-order input intercept point (IIP3) improvement with the DS method. The new implementation has been used in a 0.18-mm CMOS high linear LNA. The measured results show that the LNA achieves +11.92 dBm IIP3 with 9.36 dB gain, 2.25 dB NF and 7.5 mA at 1.8 V power consumption. & 2008 Elsevier Ltd. All rights reserved.

Keywords: Low-noise amplifier (LNA) RF CMOS Inter-modulation distortion Derivative superposition (DS) Third-order input intercept point (IIP3)

1. Introduction Linearity is a key performance parameter for RF circuits since nonlinearity may cause harmonic generation, gain compression, desensitization, blocking, cross modulation and inter-modulation distortion, and many other problems. For the low-noise amplifier (LNA), high linearity should be achieved without lowering other performances, such as low noise figure (NF), high gain, good impedance matching and low power consumption. The linearity of the LNA is usually specified as an input-referred third-order intercept point (IIP3). Many RF systems demand higher than +8 dBm IIP3 LNAs while keeping the other performance satisfied [1]. Considering that the power supply has been lowered along with the scaling down of the feature size in the CMOS process, the high IIP3 requirement is a big design challenge and many linearization techniques are proposed to solve the problem. The derivative superposition (DS) method [2–4], which falls under the category of feed forward, is one of the various linearization techniques. It uses two transistors connected in parallel and biased in the weak inversion region and in the strong

$ This work was supported in part by the National Natural Science Foundation of China (No. 90407006) and the Fok Ying Tung Education Foundation (No. 104028).  Corresponding author. Tel.: +86 10 62795096; fax: +86 10 62795104. E-mail address: [email protected] (B. Chi).

0026-2692/$ - see front matter & 2008 Elsevier Ltd. All rights reserved. doi:10.1016/j.mejo.2008.09.007

inversion region, respectively. The sizes and bias voltages of the two transistors are chosen such that the positive peak of the thirdorder nonlinear coefficient of the weak inversion transistor is aligned with the negative peak of that of the strong inversion transistor. This results in an extended linear range over which the third-order nonlinear coefficient is close to zero. However, the IIP3 improvement using this method is only modest at RF (3 dB, as reported in [3]). Ref. [4] boosts IIP3 in the DS method by 10 dB by reducing the source degeneration inductance and using the cascode technique to reduce the drain load impedance. However, as reported in [1], for feasible values of the source degeneration inductance, which is limited by the downbond inductance (40.5 nH), the conventional DS method provides no IIP3 improvement at all. But, with a very small source degeneration inductance, it is difficult to simultaneously achieve a good input impedance matching and low NF. Although the modified DS method [1] or new circuit topology [5] is proposed to boost IIP3, they need two source degeneration inductors and complicate the circuit design. In this paper, new implementation of a high linear LNA using the improved DS method is proposed. The input stage is formed by two transistors connected in parallel. One transistor is biased in the strong inversion region and another one is biased in the moderate inversion region, thus allowing a feasible source degeneration inductance at the sources of the two transistors while keeping high IIP3 improvement with the DS method. The new implementation has been

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used in a 0.18-mm CMOS high linear LNA. The measured results verify the feasibility of the proposed implementation in improving IIP3 of the LNA.

2. Circuit description Fig. 1 shows the principle of the DS method [2–4]. Two transistors are connected in parallel and their sources are degenerated by the same inductance L. One transistor, MA, works in the strong inversion region as usual and another one, MB, works in the moderate inversion region instead of the weak inversion region. Fig. 2 shows the DC I–V curve of the transistors, the vertical axis is ln(ID) and sqrt(ID), respectively. The DC I–V curve could be divided into three regions: weak inversion, moderate inversion and strong inversion. The transistor shows different I–V characteristics in different regions. The I–V curve in the weak inversion region shows exponential characteristics, while the I–V curve in the strong inversion region shows square-law characteristics. The transition region between these two regions is the so-called moderate inversion region. From Fig. 2, it could be seen that the transistor works in the moderate inversion region when VGS is between 0.3 and 0.5 V. Fig. 3 shows the third-order nonlinear coefficient G3A and G3B of MA and MB versus the voltage source VGS. By setting the voltage source VBD to 0.3 V, MA is designed to work in the strong inversion region and MB is designed to work in the moderate

Fig. 1. Principle of the DS method.

inversion region. G3 is defined as 3

G3 ¼

1 q ID 6 qV 3GS

and controls the third-order inter-modulation distortion (IMD3) at low signal levels, thus determines IIP3. It could be seen that the third-order nonlinear coefficient G3A of the transistor in the strong inversion region is negative and the third-order nonlinear coefficient G3B of the transistor in the moderate inversion region is positive. The negative G3A is aligned with the positive G3B, but they have a similar mirror-image curvature, the resulting composite G3 will be close to zero and the theoretical IIP3 will be significantly improved in a relatively wide range of the gate biases. Fig. 4 shows the schematic of the whole LNA. The input stage is the same with Fig. 1, only the ESD protection circuit and the gate series inductance are added. The gate series inductance is to resonate with the gate-source capacitance of the input transistors to provide a real resistance for the input impedance matching purpose. MA and MB are biased by the off-chip bias voltages, VA and VB, to work in the strong inversion region and the moderate inversion region, respectively, so that their third-order nonlinear coefficients G3A and G3B reach the negative peak and positive peak. MA and MB could also be biased on-chip with a welldesigned bias circuit. Since Fig. 3 shows that the theoretical IIP3 will be significantly improved in a relatively wide range of gate biases (about 70 mV), the accuracy requirements on VA and VB are not high, so it should not be very challenging to design the onchip bias circuit. In our work, the off-chip biases are applied for the prototyping purpose.

Fig. 3. The third-order nonlinear coefficient G3A and G3B of MA and MB versus the voltage source VGS.

Fig. 2. The DC I–V curve of the transistors, the vertical axis is ln(ID) and sqrt(ID).

ARTICLE IN PRESS S. Han et al. / Microelectronics Journal 40 (2009) 197–201

After the biases VA and VB are fixed, the size of MA is chosen based on the normal noise/power optimization procedure of the inductance source-degenerated common-source LNA. Then the size of MB is adjusted to make the composite G3 close to zero in a relatively wide range of gate biases. The cascode transistor is added to reduce the drain load impedance of the composite input transistors at the second harmonic frequency, so that the effect of the second-order harmonic response on IIP3 is reduced to a great extent [4]. Another goal is to improve the isolation between the input and output of the LNA. On-chip inductance Ld is resonated with the output node parasitic capacitance and on-chip capacitance Cd to provide the load for the LNA and also provide the output impedance matching. The source degeneration inductance, provided by the bondwire, is about 1.6 nH to generate a real resistance at the input of the LNA, thus allowing simultaneously the input impedance matching and the noise matching. This inductance requirement is feasible for the normal package. So the low source degeneration inductance requirement in Ref. [4] has been cancelled by making one of the parallel transistors work in the moderate inversion region instead of the weak inversion region.

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3. Simulated results The LNA has been implemented in the 0.18-mm CMOS process. Fig. 5 gives out the simulated S-parameters with Agilent ADS when VA ¼ 0.77 V and VB ¼ 0.47 V. The figure shows that the LNA has achieved good input impedance matching and output

Fig. 6. The simulated stability factor k of the LNA as well as D factor.

Fig. 4. Schematic of the whole LNA using the DS method.

Fig. 5. The simulated S parameters with Agilent ADS when VA ¼ 0.77 V and VB ¼ 0.47 V.

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impedance matching with a 1.3 GHz operating frequency, and it could provide 12.3 dB power gain and 21.7 dB reverse isolation. Since MB works in the moderate inversion region, the gate voltage

variation of MB has little effects on the S-parameter performance of the LNA. Fig. 6 gives out the simulated stability factor k of the LNA as well as D factor (D ¼ |S11S22S12S21|). It could be seen that k is greater than 1 and D factor is smaller than 1, so the LNA is unconditionally stable. Fig. 7 gives out the simulated effective small-signal transconductance Gm of the LNA and the contribution of MA and MB. Gm is mainly dependent on MA, and MB has little contribution to Gm since MB works in the moderate inversion region. Here VGS is the gate voltage of MA, and the gate voltage of MB is lower than VGS by 0.3 V.

4. Measured results

Fig. 7. The simulated effective small-signal transconductance Gm of the LNA and the contribution of MA and MB.

Fig. 8. The microphotograph of the presented LNA.

The LNA has been implemented in the 0.18-mm CMOS process. Fig. 8 shows its microphotograph. The die area is about 0.6 mm2, most of which is occupied by the on-chip inductance, PADs and ESD protection circuits. The bare die is directly bondwired into a PCB and all the measured results are calibrated with another identical PCB without the die bondwired. The measurements show that the power gain of the 1.35 GHz LNA is about 9.36 dB with an NF of 2.25 dB. Fig. 9 shows the measured power gain and NF versus frequency with an Agilent noise figure analyzer. The gain is lower than the simulated |S21| by about 3 dB and NF is higher than the simulated one by about 1.2 dB. The reason may be due to the inaccuracy in RF component models and the package parasitic effects which could not be predicted correctly since our package is completed by hand. Two-tone test is used to obtain the IIP3 of the LNA. Two RF tones located in 1.35 GHz750 kHz are input into the LNA, and the two tones have the same power. Fig. 10 gives the measured IIP3 of the LNA at different gate voltages VB of MB, here the gate voltage VA of MA is fixed at 0.767 V. It could be seen that the IIP3 of the LNA achieves the highest value (11.92 dBm) when MB works in the moderate inversion region, which is much higher than the case when MB works in the weak inversion region and in the strong inversion region. Consider that the power supply of the LNA is only 1.8 V, and the IIP3 of 11.92 dBm is very superior.

Fig. 9. The measured power gain and NF versus frequency with an Agilent noise figure analyzer.

ARTICLE IN PRESS S. Han et al. / Microelectronics Journal 40 (2009) 197–201

60

VB = 0.281 V

VB = 0.467 V 50 40 30 20 10 0 IIP3 = 11.92 dBm -10 -20 -30 -40 -50 -60 -70 -80 -90 -100 -25 -20 -15 -10 -5 0 5 10 15 20 Pin (dBm)

20 IIP3 = 4.17 dBm

-20

Pout (dBm)

Pout (dBm)

40

0

-40 -60 -80 -25 -20 -15 -10 -5 0 5 Pin (dBm)

201

10 15 20

VB = 0.767 V

80 60 Pout (dBm)

40 20 0

IIP3 = 2.84 dBm

-20 -40 -60 -80 -25 -20 -15 -10 -5 0 5 Pin (dBm)

10 15 20

Fig. 10. The measured IIP3 of the LNA (VA ¼ 0.767 V). Table 1 Comparison of state-of-the-art highly linear CMOS LNA Work

Technology (mm)

Freq. (GHz)

Power gain (dB)

NF (dB)

IIP3 (dBm)

PDC (mA atV)

FOM

[1] [6] [4] [7] [5] [8] This work

0.25 0.25 0.35 0.35 0.35 0.18 0.18

0.9 2.2 0.9 0.9 0.9 2 1.35

15.5 14.9 10 2.5 1* 6.7* 9.36

1.65 3 2.85 2.8 2.95 1.4 2.25

+22 +16.1 +15.6 +18 +21 +13.3 +11.92

9.3 at2.6 9.4 at 2.5 7.82 at 2.7 15 at 3 9 at 2.5 8 at 1.8 7.5 at 1.8

452.8 118.4 17.1 2.5 4.1 34.9 19.8

Note: * means that the gain is deduced from the IIP3 measured figures.

The LNA draws 7.5 mA current from a 1.8 V power supply. If we define the figure of merit (FOM) of the LNA as follows: FOM ¼

Gain  IIP3 ðmWÞ  f ðGHzÞ ðF  1Þ  PDC ðmWÞ

where F is the noise factor; a summary of the measured results of the LNA is provided in Table 1 along with a comparison with the state-of-the-art high linear CMOS LNA.

5. Conclusion New implementation of a high linear LNA using the conventional DS method is proposed. By making one transistor work in the moderate inversion region instead of the weak inversion region, a feasible source degeneration inductance is allowed to achieve a good input impedance matching and low NF while keeping high IIP3 improvement with the DS method. The LNA has been implemented in the 0.18-mm CMOS process and the measured results verify the feasibility of the proposed implementation.

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