1. Field of the Invention
The present invention relates to analog filter circuits, and particularly to optimal low power complex filters.
2. Description of the Related Art
Active complex (polyphase) filters are renewed as they provide solutions for image rejection in low-IF wireless applications such as Bluetooth (BT) and Zigbee receivers. Also, they can be utilized in wireless sensor network and IEEE 802.15.4 applications such as gm-C complex filters known in the prior art. These filters are often based on transconductance amplifier-C (gm-C) or active-RC techniques. In addition, several polyphase filter realizations based on the second generation current conveyors (CCIIs), current feedback amplifiers (CFAs), current amplifiers (CAs) and current mirrors can, for example, be found in other prior arts. These filters can be classified based on their synthesis method into three categories: element substitution techniques of LC prototypes, cascading of first-order complex sections, and cascading of second-order complex biquads.
Complex filters based on LC simulation often use extensive number of active devices. For example, an exemplary prior art filter employs 30 transconductance amplifiers (TCAs) to realize 5th-order filter while 32, 48, 66 TCAs were respectively incorporated to achieve 3rd, 5th, 9th-order complex responses in other prior art implementations. In fact, it is found that the most efficient design among this category requires “3.7” TCAs per pole. On the other hand, first order filters may require only two devices. However, such filters would exhibit poor stopband attenuations since they are obtained from their first-order LPF counterparts. The available complex biquad filters incorporate 12 TCAs, 4 op-amps, 8 op-amps, 4 op-amps, and 10 CCIIs, depending on the chosen design. There remains the need for more efficient biquad complex filters.
Thus, an optimal low power complex filter solving the aforementioned problems is desired.
The optimal low power complex filter, as a second order complex filter, for example, is based on current amplifiers (CAs) and may be utilized to implement a 4th order current-mode filter that can be used for intermediate frequency (IF) applications, such as, for example, low-IF Bluetooth receivers. Fabricated in a standard 0.18 μm CMOS technology, experimental results show that the present design offers improved characteristics over the existing solutions in terms of power consumption and spurious-free dynamic range (SFDR). The 4th order filter exhibits in-band SFDR of 65.8 dB while consuming only 1 mW.
These and other features of the present invention will become readily apparent upon further review of the following specification and drawings.
Unless otherwise indicated, similar reference characters denote corresponding features consistently throughout the attached drawings.
The optimal low power complex filter, as a second order complex filter, for example, is based on current amplifiers (CAs) and may be utilized to implement a 4th order current-mode filter that can be used for intermediate frequency (IF) applications, such as, for example, low-IF Bluetooth receivers. Fabricated in a standard 0.18 μm CMOS technology, experimental results show that the present design offers improved characteristics over the existing solutions in terms of power consumption and spurious-free dynamic range (SFDR). The 4th order filter exhibits in-band SFDR of 65.8 dB while consuming only 1 mW.
Optimization criteria are defined as follows. The power consumption of filters based on a given amplifier type is directly proportional to the number of active elements employed. Whereas, the power consumption of filters based on various amplifier types depends on individual power of various amplifiers as well as their numbers. However, given that the different kinds of amplifiers can be decomposed to common basic cells, then the power consumption will be directly proportional to the number of cells.
In embodiments of the optimal low power complex filer complex lossless integrators are utilized to develop complex filters based on two-integrator loop topologies. An arbitrary normal integrator with time constant τ=1/ωo can be converted to a complex integrator when every frequency dependent element in the original integrator is modified to be a function of s−jωc instead of s, (s being a Laplace transform parameter representing the complex frequency σ+jω) as shown in circuit 10a of
where input and output variables can be voltage or current signals.
Two complex integrators can be used in cascade to develop a two integrator loop complex filter circuit 20, as shown in
The complex bandpass filter given by (2) exhibits a center frequency of ωc, pole frequency of ωo, pole quality factor of Q and bandwidth of 2ωo/Q (i.e. twice the bandwidth of the original lowpass filter). The non-inverting integrators in
It is essential for integrated continuous time filters to be associated with tunable parameters in order to achieve accurate frequency characteristics and compensate for process variations and temperature effects. The parameter ωc and ωo are functions of RC products which cannot be implemented accurately in ICs. On the other hand, Q is usually a function of resistor and/or capacitor ratios that can be implemented precisely. Therefore, it is desired to design the filters with independent control of ωc and/or ωo without changing Q. The tuning requirement of a complex filter depends on the nature of RC terms involved in ωc and ωo. For the case when ωc and ωo have same RC product terms, it is sufficient to have common tuning scheme. However, when they have different RC products separate tuning circuits would be needed. Hence, the former case requires simpler automatic tuning schemes. The image rejection ratio (IRR) of a complex filter obtained from
IRR=√{square root over ((1+4(ωc/ω0)2)2+(4/Q2)(ωc/ω0)2)}{square root over ((1+4(ωc/ω0)2)2+(4/Q2)(ωc/ω0)2)}{square root over ((1+4(ωc/ω0)2)2+(4/Q2)(ωc/ω0)2)}. (3)
Clearly, selecting higher center frequency for BT improves the IRR. On the other hand, it can be shown that the ideal image rejection ratio (IRR) of any complex filter obtained from first-order LPF is given by:
IRR=√{square root over ((1+4(ωc/ω0)2)}. (4)
This means that the complex filters obtained from their biquad counterparts inherently exhibit better IRR than two cascaded stages of first-order. As an example, the pole frequency fo may be set to 1.43 MHz for each section such that the overall bandwidth of a six stage design becomes 1 MHz. This leads to a nominal IRR per stage of 12.7 dB. Whereas, the IRR of a second-order Butterworth biquad (fo=0.5 MHz) is 43.3 dB.
TCA filters are realized by CCIIs allowing comparison with TRA and CA at device level. A TCA obtained from a CCII is also attractive because it provides better linearity than conventional TCA circuits particularly for low supply voltages. Basically, CCII is a VB whose output is sensed and conveyed to current output terminal Z. The terminal characteristics of the CCII can be described by IY=0, VX=VY, IZ=Ix or IZ=kIX when current gain is required. VM cascadable integrators can be realized using TCAs, op-amps or TRAs. In the case of adopting single output TCAs (CCII whose X terminal are loaded with passive resistors), an additional TCA per path would be required to realize the complex feedback loop. Therefore, 12 TCAs (or CCIIs) would be used: 8 TCAs to form the two complex integrators while 4 TCAs to implement the original negative feedbacks. The total number of devices can be reduced to 10 CCIIs (or TCAs) when two transconductors are replaced by two passive resistors. Adopting multi-output CCIIs further reduces active devices to 8, as shown in circuit 30 of
Hence, the filter exhibits ωc=Kc/CR3, ωo=1/C√{square root over (R2R3)}, Qo=R3/Kq√{square root over (R2R3)} and K=R3/R1. It is possible to change this filter to active-C topology, such as by replacing CCII by CCCII, for example. In this case, the passive resistors would be replaced by the internal resistance of the X terminals of the CCCII. Although active-C topologies may save silicon area they would degrade the linearity performance.
In fact, a complex VM integrator can be realized with a single device only if it has both low output impedance and input virtual ground to facilitate the addition of the feedback signals. These two features are inherently available in the op-amp and the TRA. But op-amp based filters consume relatively high power at IF ranges. Alternatively, a complex filter circuit 40 based on TRAs is developed as shown in
Thus, the filter exhibits ωc=1CRc, ωo=1/C√{square root over (R2R4)}, Qo=R3/√{square root over (R2R4)} and K=R4/R1.
On the other hand, it is more efficient to realize CM cascadable complex integrators with high output impedances rather than with low input impedances. This is because the latter case would require additional devices in order to realize the complex feedback loops. It can be observed that TCA and CA can efficiently develop the CM complex integrator of
Hence, the filter exhibits ωc=Kc/CR, ωo=1/CR, Qo=1/Kq and K=Kg.
Unlike the cascadable CM integrator based on CCII, developing its counterpart based on CA is more involved. Basically, there are two alternatives. The first option is through applying the input current at the X-terminal and connecting a shunt integrating capacitor at the output terminal Z to perform integration. Then, the voltage of the capacitor is converted again to an output current using voltage to current converter. A more efficient realization is obtained via converting the lossy CM passive integrator to a lossless cascadable topology with the help of dual output CA. Utilizing a third output current terminal, the desired complex integrator circuit 60 is developed as shown in
Thus, the filter exhibits ωc=Ko/CR, ωo=1/CR, Q0=1/Kq, and K=Kg, where ωc is a center frequency, ωo is a pole frequency, Qo is a pole quality factor, Hp (s) is a transfer function of the complex filter, Kg, Kq, and Kc are gains of the complex filter, C is a capacitance in the complex filter, R is a resistance in the complex filter, and s is a Laplace transform parameter representing the complex frequency jω.
The current consumption of a single output CCII can be expressed as the biasing current of the VB plus the standby current (ISB) of the output current terminal Z and hence each of other Z terminals would require additional ISB. Typically, the buffer current is around 5 to 10 times the value of ISB. The current consumption of a CFA (CCII plus VB) would be 2ICCII−ISB. Therefore, the total currents of the filters of
In addition, it can be seen from equations (5) to (8) that the ωo of all five filters can be tuned independently without disturbing Qo and gain. But the CM filters of
Considering non-ideal high frequency operation, it can be seen that there are two parasitic poles associated with the filter of
Fully differential realization is another major issue related to the power consumption. Fully differential architectures enhance the performance in terms of supply noise rejection, dynamic range, and harmonic distortion. A fully differential CCII can be used to develop a differential current integrator circuit 80a as shown in
This relation is rearranged to obtain the differential and common-mode components as shown in (10) below. Mismatches are designated by Δβ=βp−βn, Δα=αp−αn, ΔC=Cp−Cn, and ΔR=Rp−Rn where β, α, R and C are the averages of the two ideally matched components. These relations can be used with (10) to obtain (11) as shown below.
By neglecting second-order terms, (11) reduces to (12) shown below.
Since the mismatch factors can be positive or negative, the signs of the individual terms are of no particular importance. When the terms have signs such that the individual contributions add, they produce the worst-case common-mode rejection ratio (CMRR) of:
On the other hand, a differential CA-based integrator circuit 80b is shown in
The current consumption of this topology would be 2CCII+4ISB. Assuming perfect current transfer, the output is pure differential given by Iop−Ion=2(Ip−In)/(sCR). In presence of mismatches, the TF of the integrator circuit 80b of
This relation can be rearranged to obtain the differential and common-mode components as shown in (15) shown below where εp=1−αup and εn=1−αun. Considering various statistical mismatches including εp=ε+Δε/2 and εn=ε−Δε/2, (15) reduces to (16) shown below when neglecting second-order terms. Therefore, the CMRR2 of the integrator 80b of
Assuming αn=αp=α and neglecting ε, CMRR2 becomes:
Clearly, there is one less mismatch contribution (beta-mismatch is absent) in (18) compared to (13). Thus, the circuit 80b of
With respect to the two main parameters related to the dynamic range of the two filters of
When Kq is greater than or equal one, this relation can be rewritten as:
Similarly, for the two CCIIs on the right of
On the other hand, the signal limitations of the filter of
Similarly, for the two CAs 83 on the right of
By careful inspection of (20) through (23), the following significant conclusions are deduced. For the cases where R<Kq|VVB/ICF|, the two filters exhibit same signal swing. Assuming typical values of |VVB|=1 V obtained from a supply voltage of 1.8 V, |ICF|=1 mA and Kq=1.42 (Butterworth response), indicates that R must be selected to be less than 1.42 kΩ in order for the filter of
The second parameter that decides on the dynamic range of a filter is noise. The internal thermal noise of a CCII can be modeled as voltage and current sources at the Y-terminal denoted by VnY, and InY as well as current sources of InX at the X terminal and LnZi at every Zi terminal. Whereas, the internal thermal noise of a CA can be characterized with voltage and current sources at the input-terminal denoted by VnX, and InX as well as current sources of InZi at every Zi terminal. Noise of a passive resistor can be modeled as a voltage source whose spectral density function is VnR2=4kTR where k is Boltzmann's constant, T is absolute temperature, and R is the resistance size.
It can be observed that the TFs due to the resistors noise sources of the I-path (VnRIa, VnRIb, VnRQa, and VnRQb) are same for both filters. Hence their noise contributions will be equivalent. Also, it can be shown that TFs due to VnYIa, VnYIb, VnYQa and VnYQb in
In fact, the VBs incorporated in the CCII not only limit the input/output signal swing but also the circuit bandwidth. An op-amp based VB, for example, limits the bandwidth of the CCII to the unity-gain frequency of the op-amp (BW=gm1/CC) where gm1 is transconductance of the input stage and CC is the compensation capacitor. The location of the introduced dominant pole depends on the minimum value of stable closed-loop gain or equivalently the maximum value of the feedback factor. Thus, the largest CC is required for the case demanding stable closed loop gain as low as unity. In order to compensate for the large CC, gm1 must be increased often through increasing the power consumption.
On the other hand, a simpler input stage is required in the CA design leading to improved frequency response and/or reduced power consumption. A class-AB low-power CA circuit 100 is shown in
It has been shown that the CCII and CA based filters exhibit similar noise performance. However, the CA based filter exhibits better signal swings, provides higher common-mode rejection, and can support higher bandwidths. Therefore, it is expected that the CA-based filter would provide better dynamic range while consuming lower power and hence it may be more desirable or advantageous.
Noise can be, in some cases, the main limitation of a CM approach. This section describes the noise performance of the complex filter of
where VnMi are the equivalent input noise source of MOSFETs given by vnMi2=8kT/(3gmi) and where gm is the transconductance of the transistor. The matched transistors M1-M2 and M4-M5 have same noise. This noise source can be reduced by selecting a large gm1 whereas the noise spectral density functions of InX and InZ can be expressed as:
InX2=(gm10)2VnM102+(gm11)2VnM112 (25)
InZ2=(gm12)2VnM122+(gm13)2VnM132. (26)
A 4th-order complex filter for implementing the channel-select filter in a low-IF BT receiver was realized by cascading two sections of the filter of
where D(s) is given by (31) below. The output spectral density of the first polyphase stage (I2no
D(s)=s4C4R4+s3(2C3R3Kq)+s2(2C2R2+C2R2Kq2+2C2R2Kc2)+s(2CRKqKc2+2CRKq)+(Kq2Kc2+Kc4−2Kc2+1) (31)
In order to determine the noise contribution of the first stage to the output noise of the I path, the transfer function HIQ(s)=IoI/(II+IQ) is calculated for real input II and IQ (II=IQ is assumed at the end of the analysis since the noise of the I and Q paths are equal) leading to HIQ of the transfer function HIQ(s):
where DIQ(s) is given by (33) shown below and HIQ(s) is the transfer function of the electronic filter circuit, DIQ(s) is the denominator portion of the transfer function, C is the capacitive portion of said RC circuits, R is the resistive portion of said RC circuits, K1 and K2 are gains of the electronic filter circuit, and s is a Laplace transform parameter representing the complex frequency jω.
DIQ(s)=s4C4R4+s32C3R3K1+s2(2C2R2K22+C2R2K12+2C2R2)+s(2CRK1K22+2CRK1)+(1+K12K22−2K22+K24) (33)
Therefore, the total output noise spectral density is calculated by
Ino
A fully differential 4th-order complex filter for implementing the channel-select filter for a low-IF BT receiver was realized by cascading two sections of the filter of
Selecting IB=5 μA and ISB=2 μA leads to a total biasing current of 0.58 mA for the whole filter. Two fully differential CAs and four resistors are used to generate the required input currents from voltage generators. Also, the various current outputs are changed to voltages which are measured with the use of voltage buffers. The signal magnitude response is shown in plot 1100 of
This work systematically shows that the relatively more power efficient complex filters are those obtained from CM structures based on the TCAs and CAs. While embodiments of complex filters can be realized with same CMOS topologies (for example same CCII), it is analytically shown that CA-based filter provides a relatively better dynamic range than its TCA or (CCII) counterpart. The merits and demerits of various possible complex filter realizations are demonstrated, together with results about signal limitations, noise, and common-mode rejection are reported. Embodiments of a 4th-order complex filter, such as based on the filter section of
It is to be understood that the present invention is not limited to the embodiments described above, but encompasses any and all embodiments within the scope of the following claims.
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