This disclosure relates to methods and devices for high gain closed loop amplifiers which are compatible with a broad range of integrated and discrete semiconductor circuit technologies.
Operational transconductance amplifiers (OTAs) are key building blocks for many types of signal processing algorithms realized in CMOS IC technologies. Unfortunately, as transistor dimensions scale downwards with advancing technology developments, so too does their intrinsic voltage gain, which in turn, reduces the upper limit of the open-loop gain achievable by any OTA. Low-gain OTAs have an immediate impact on the absolute accuracy that the system can achieve. If we consider that any time domain specification is a combination of overshoot, settling time, and steady-state error, an ideal system constructed with infinite-gain OTAs can satisfy all three metrics simultaneously, however a system constructed with low-gain OTAs cannot. For the most part, low-overshoot and fast settling time specifications can be met, but the final steady-state error cannot be met. In essence, the system would fail its absolute accuracy requirements.
As OTAs realized in advanced CMOS nodes have very low DC gain, high performance systems constructed with these components will fail to meet their performance expectations. Accordingly, it would be beneficial to provide circuit designers with a methodology for designing and manufacturing ultra-high gain amplifiers.
There is described herein methods and devices for high DC gain closed loop operation amplifiers exploiting cascaded low gain stages and a controller-based compensation circuit for stability.
In accordance with a first broad aspect, there is provided an amplifier circuit comprising a plurality of cascaded circuit elements arranged in a closed-loop topology, the closed-loop topology comprising a plurality of gain stages defined by the cascaded circuit elements, and a controller provided in the closed-loop topology, the plurality of cascaded circuit elements and the controller together implementing an open-loop transfer function composed of an amplifier function and a remainder function, the gain stages corresponding to the amplifier function and the controller configured to implement the remainder function.
In accordance with another broad aspect, there is provided method for providing an amplifier circuit. The method comprises selecting a closed-loop transfer function for the amplifier circuit, the closed-loop transfer function having a corresponding open-loop transfer function composed of an amplifier function and a remainder function, determining a closed-loop topology for a plurality of cascaded circuit elements and a controller, the cascaded circuit elements defining a plurality of gain stages that correspond to the amplifier function of the open-loop transfer function, and configuring the controller to implement the remainder function of the open-loop transfer function.
Other aspects and features of the present invention will become apparent to those ordinarily skilled in the art upon review of the following description of specific embodiments of the invention in conjunction with the accompanying figures.
Embodiments of the present invention will now be described, by way of example only, with reference to the attached Figures, wherein:
The present disclosure is directed to amplifiers and more particularly to methods and devices for high DC gain closed loop operation amplifiers exploiting cascaded low gain stages which are compatible with a broad range of integrated and discrete semiconductor circuit technologies. Although the examples herein focus on operational transconductance amplifiers (OTA), the methods and devices are applicable other types of amplifiers, such as operational amplifiers and the like.
It is proposed herein to combine a reduction in the system response, i.e. a longer settling time, with the introduction of a high level of overshoot. Cascading of multiple single-stage amplifiers is much less sensitive to reductions in voltage supply levels and more suitable to small-dimensional CMOS technologies than, for example, cascoding may be. However, cascading multiple stages together to achieve large DC gains leads to stability issues when inserted into negative-feedback loop configurations. In order to counter this issue, a controller is provided to stabilize operation of the circuit in a closed-loop configuration.
A methodology for providing an amplifier circuit begins by selecting a desired closed-loop transfer function. A controller-based compensation circuit is then synthesized and placed in cascade or integrated alongside the numerous gain stages represented by, for example, undamped integrators. The gain stages may also be implemented using other simple low-gain circuit elements, such as differentiators, bandpass resonators, dampers, inverters and the like.
The closed loop transfer function has a corresponding open loop transfer function generally represented by Equations (0-A) and (0-B), where Equation (0-B) is the relationship between the open loop transfer function of the amplifier, the transfer function of the cascaded gain stages, and the transfer function of the controller when the cascaded gain stages and the controller are inserted into a closed-loop topology. Note that beta is an arbitrary factor.
Closed Loop TF=Open Loop TF/(1+beta*Open Loop TF) (0-A)
Open Loop TF=Cascaded Gain Stages TF*Controller TF (0-B)
Once the closed-loop transfer function is selected, a closed loop topology is determined for a plurality of cascaded circuit elements and a controller. The cascaded circuit elements implement the cascaded gain stages transfer function. The controller may then be configured to implement the controller transfer function, also referred to as a remainder function, as will be explained in more detail below.
In this manner the design methodology allows very high gain and bandwidth amplifier structures to be constructed that have specific closed-loop behavior. The amplifier open-loop response is not limited to a single-pole response and a phase margin metric, but rather one that provides the desired closed-loop response. Accordingly, the design approach involves a cascade of circuit elements in a complex feedforward/feedback arrangement which can be automated by a computer-aided design method. Whilst any number of circuit elements can be placed in cascade, sensitivities to process variations will typically limit this number.
The method for providing an amplifier circuit will be described in more detail using an OTA as an example. The method begins with a desired closed-loop transfer function, T(s). Assuming an OTA is embedded in a single-loop feedback structure with feedback β, the OTA open-loop transfer function can be expressed by Equation (1) The OTA closed-loop transfer function takes on the overall form given by Equation (2), where di is the i-th coefficient of both the numerator and denominator polynomials. The general form of Equation (2) is referred to as a pole-zero canonical type transfer function owing to its transfer function depending only on the coefficients of its pole polynomial. In equation (3), A(s) is represented as a product of K integrator functions (1/sK) multiplied by the remainder function, R(s). Comparing Equation (1) with Equation (3), and substituting Equation (2) and rearranging, leads to the remainder function R(s) being defined by Equation (4).
For realization purposes, N≥2K−1, where K is the number of gain stages of the amplifier and N is the order of the amplifier, otherwise the order of the denominator will be less than that of the numerator, which would lead to an impractical result. This sets an upper limit on the number of integrators that can be used to form the OTA. For reasons to be given shortly, an OTA with the largest DC gain is one realized with a maximum number of integrators. For instance, an OTA described by a 5th-order transfer function could be realized using 3 integrators and a 2nd-order biquadratic function in cascade, as depicted by the block diagram shown in
The circuit that realizes the remainder function is what control theorists refer to as a controller. The controller is used to stabilize the closed-loop configuration. Herein, we shall refer to this method of OTA stabilization as a controller-based compensation method. It should be noted that any filter synthesis method, such as cascade of bilinear/biquads, follow-the-leader feedback filter methods, etc., can be used to synthesize the open loop transfer function of the OTA provided it can handle an input-output transfer function with multiple poles at DC. In the past, one would not expect to synthesize a transfer function with poles at DC.
Another means in which to realize the OTA open-loop transfer function A(s) is through a state-space formulation involving the parameters {A,b,c,d} expressed in general terms as Equations (5A) and (5B) where X is an N-dimensional vector describing the states of the system, u and y are the scalar input and output signals respectively, and A, b, cT and d are (N×N), (N×1), (1×N), and (1×1) constant coefficient matrices respectively. The overall transfer function can be described in terms of the state-space parameters by Equation (6) where I is the identity matrix. The advantages of a state-space formulation over the previous cascade approach is that it can directly lead to a realization with a greater number of integrators in cascade, specifically N−1 integrators, and an implicit controller function distributed among the various integrators. Following the observable canonical state-space form, the OTA transfer function described by Equations (3) and (4), can be written as Equations (7A) and (7B) respectively.
Now referring to
To illustrate the procedure more clearly, consider the requirement for an OTA to be used in a unity-gain closed-loop configuration having a unit step response with a 5th-order Gaussian response given by Equation (8).
Next, to enable a realization as a cascade of four undamped integrators, the numerator of T(s) is modified to include a portion of the denominator polynomial in the numerator as described earlier, resulting in Equation (9).
The additional left-half plane (LHP) zeros generally alter the desired step response by introducing overshoot and ringing. This is clearly visible in the plot of the step response for each transfer function as shown in
Assuming the step response achieves the desired closed-loop performance levels under realistic gain conditions, the resulting state-space realization would appear as that depicted in
The magnitude response of an undamped integrator is shown in
In comparison, any practical integrator will behave exactly like an undamped integrator for frequencies bounded between the low-frequency pole, p1, and the high-frequency zero, z1. In some embodiments, what is used is an integrator with the lowest parasitic pole and the highest parasitic zero. There are two general types of integrators typically implemented in a CMOS technology, the shunt-C and the Miller-C. These are depicted in
Here we see the shunt-C integrator has a pole at 1/(rO,1C1) and a DC gain of gm,1rO,1. In contrast, the transfer function of the Miller-C integrator of
As long as the high-frequency zero z1 can be placed at least two orders of magnitude greater than the unity gain frequency ωt, its presence will have little effect. Since the frequency at which the Miller-C integrator reaches unity gain is approximately gm,1/C1 and the parasitic zero is gm,2/C1, then this condition is simply met by ensuring gm,2>100 gm,1. As a result, the Miller-C integrator will generally result in a larger DC gain and a lower parasitic pole.
For frequencies above the pole frequency p1 and below the zero z1, the transfer function of the Miller-C integrator can be approximated by Equation (12). This reveals that any coefficient of the state-space realization is set by the unity-gain frequency ωt=gm,1/C1 of the corresponding Miller-C integrator.
For simplicity purposes, assume that each Miller-C integrator will be constructed with identical gm and rO, except that the transconductance associated with the zero term will be set at 100 gm so that it is at least 100 times away from the unity gain frequency ωt of the integrator. Thus, one can write from Equation (11), assuming ωm=gm/C, Equations (13A) to (13C) respectively. Armed with the above, the frequency response behavior of an N-th order OTA can be approximated by Equation (14) where R(s)) is the remainder function defined by Equation (4) with K=N−1.
Referring to Table II there are listed the pole and zero locations for a modified Gaussian transfer function for orders 2 to 5. The DC gain of the OTA corresponds to the individual gains of N−1 Miller-C integrator stages, which can be made extremely high, as given by Equation (15).
ADC=AON-1 (15)
There are N co-incident RHP zeros at z1 and N−1 co-incident low-frequency poles at pi, all resulting from the parasitic elements of the Miller-C integrator. By design, the zeros are purposely placed at least two orders of magnitude higher than the unity-gain frequency of a single stage Miller-C integrator. In regards to the remainder function R(s), there are N−2 LHP zeros located slightly below ωt and a single pole at a slightly higher frequency than the unity-gain frequency at a11ωt. Collectively, the pole-zero combination forces the OTA roll-off to a slope of −20 dB/decade at the unity gain cross-over frequency.
The 3-dB bandwidth of the OTA can be approximated by Equation (16) where the factor √{square root over ((½N-1)−1)} accounts for the bandwidth reduction caused by the co-incident poles. As a point of reference, this factor is equal to I, 0.64, 0.51 and 0.43 for N equal to 2, 3, 4, 5, respectively.
GBP≈ADC×ω−3 dB≈AON-2ωt (17)
The gain-bandwidth product (GBP) reveals some very interesting properties associated with these ultra-high gain OTAs. Multiplying Equation (15) with Equation (16), one obtains Equation (17). Increasing the number of integrators in cascade can increase the GBP above the unity-gain frequency of the Miller-C integrator. While GBP is an interesting side effect, the real benefit of the proposed ultra-high gain amplifiers over current prior art OTA structures is that a much larger gain is available over its unity-gain bandwidth.
A SPICE-like simulation of the magnitude and phase behavior of the proposed OTA structure is shown in
For the purposes of testing, the OTA was connected in a unity-gain configuration and its unit step response was simulated using SPICE and compared to the expected modified-Gaussian behavior. The results are collected for OTA orders from 2 to 5 and displayed in
OTAs often operate over many different bandwidths and impedance levels. By designing with a frequency and impedance normalized prototype, such as those described in Table I, other OTAs can be derived from it by applying a scaling factor to the components of the prototype. In general, there are two independent scale factors that are commonly used. One involves scaling the bandwidth of the OTA and the other involves scaling the impedance level (or in other words, finding more practical component values).
In general, the bandwidth of the OTA can be increased from 1 rad/s to ωO rad/s by dividing all integrator capacitors by this same factor given in Equation (18). It should be noted that if the OTA frequency response were to scale to very high frequencies, its behavior would experience changes on account of the influence of various transistor parasitics not considered in our analysis here.
Conversely, the impedance level of any components associated with a single integrator can be scaled without changing its transfer function as long as the same factor, say γ, is used on all the transconductances and the integration capacitor associated with that cell. For instance, the two-input Miller-C integrator shown in
gm,1→γ·gm,1 (19A)
gm,2→γ·gm,2 (19B)
gm,3→γ·gm,3 (19C)
C1→γ·C1 (19D)
rO,1→rO,1/γ (20A)
rO,2→rO,2/γ (20B)
rO,3→rO,3/γ (20C)
Another form of scaling can be used to equalize the peak or RMS values associated with each integrator output during closed-loop operation. This maximizes the signal handling capability of the overall closed-loop configuration, i.e., maximizes the input linear range before the onset of slew-rate limiting. Moreover, scaling for maximum dynamic range reduces the spread in the various components used to realize the OTA, a benefit that can be exploited with every design.
Through a transient or frequency-domain analysis of the OTA in closed-loop operation, a metric of interest is collected for each integrator output, such as the peak value corresponding to a step input, and assigned to the corresponding element of a diagonal matrix, normalized by the desired peak value Vmax. For instance, if the peak value of the output of the ith integrator is denoted as αi. and then one can write the diagonal matrix as given by Equation (21).
Dynamic range scaling would then be performed on the state-space parameters according to the similarity transformation described by Equation (22). For the specific set of OTA state-space parameters seen listed in Equation (7), one would arrive at the scaled state-space parameters as given by Equations (21A) to (21C) respectively.
While the only nonzero element in the C vector appears as though it is no longer unity, in practice, Vmax and α1 would actually be the same value on account of the goals of the closed-loop system. Table III presents the state-space coefficients corresponding to the modified Gaussian transfer function presented earlier in Table I when scaled for equal integrator transient peak outputs.
A canonical state-space realization is very sensitive to its coefficients. This has to date limited their use as precision filter circuits. However, for OTA applications, this sensitivity is less critical unless the order of the realization is very high, and as such, some form of post-manufacturing calibration can be introduced.
To better understand the performance robustness of the proposed OTA structure, consider the analysis of an OTA design in a unity gain configuration for orders ranging from 2 to 5. As before, a closed-loop modified Gaussian response will be used. Two metrics will be considered. The first is the normalized sensitivity of the peak value of the step response to the individual filter coefficients, di. Mathematically, it is defined as Equation (24).
Through a numerical analysis, the results of which are displayed in
Another sensitivity metric that is quite revealing is the normalized sensitivity to settling time, TS. Mathematically, it is defined by Equation (25) and the results are displayed in
A means to quantify the stability robustness of a closed-loop system was defined using a four polynomial method involving its characteristic function. Consider that the input-output transfer function T(s) of the OTA of
Here, the poles of this system are simply the roots of the denominator polynomial. The system will be stable if the poles of this feedback system remain in the left-half plane (LHP) under all possible variations in the OTA parameters. Assuming each coefficient can undergo a worst-case error offset due to manufacturing, the system will be stable if the roots of the four polynomials given by Equations (27A) to (27D), respectively, remain in the LHP.
Using the state-space parameters for the OTA from Table III for orders of 2 to 5, the worst-case manufacturing error can be found by solving for the value of 2 that leads to the critically damped situation. These results are summarized in Table IV. The higher the OTA order, the lower the tolerance to manufacturing errors. As a first-order approximation, one can state that the maximum error tolerance decreases by a factor of two with increasing order beyond second-order. The careful placement of poles and zeros in the synthesized transfer function results in a more robust closed loop stability than its pole-zero cancellation counterpart, whose closed-loop performance is largely dependent on the magnitude of the process variations.
In order to demonstrate the principles described herein, a fully programmable state-space OTA was designed for fabrication using the IBM 130 nm CMOS process. The design occupies a total active area of 1 mm2, which includes the 23 bond pads with electro-static discharge (ESD) protection. The circuit can be programmed for OTA orders ranging from 2 to 5, and can be used to realize a wide range of transfer functions. A system-level architectural view of the proposed amplifier is depicted in
The unit-sized Gm cell shown in
The unit-sized Vctrl cell was designed for a nominal transconductance of 50 pA/V at a control voltage of 300 mV using the transistor aspect ratios listed in Table V. The input and output CM levels are set at one-half the VON level at 600 mV. At Vctrl=0V, the transconductance is observed to vary from 40 μA/V to as high as 66 μA/V for control voltage settings 280 mV≤Vctrl≤320 mV as determined by SPICE modelling. Note that the cell can be completely turned off by setting the control voltage to zero. This provides a simple on-off control mechanism that is used to set a desired transconductance level in a programmable Gm cell.
The programmable Gm stage consists of 20 unit-sized Gm cells all connected in parallel in the manner described earlier and illustrated in
Fully differential inputs and outputs are used as the target application for this prototype is to realize minimum-sized integrators with a unity-gain bandwidth of approximately 10 MHz. A 2 pF capacitor was used with each integrator realization. Using two feed-in branches to the integrator, one was realized with a unit-sized Gm stage and the other set at 20 times the unit-size. The stage supporting the integrator capacitor was set at 100 unit-sizes. The bias voltage Vctrl for each Gm cell was set at 300 mV.
With one input grounded and other excited by a 1V AC voltage source, the frequency response behavior of a fully extracted circuit including layout parasitics was simulated using SPICE. The magnitude and phase results are shown in
The a single input integrator described above did not contain this additional parasitic pole. While an expression for this pole in terms of the parasitic elements is rather cumbersome, the general form of the Miller-C integrator transfer function would appear as Equation (28) where AO, z1, and p1 are the same as before as shown in Equation (13) and p2 represents the additional parasitic pole. This parasitic pole-zero pair does degrade the phase behavior of the integrator around its unity gain frequency. For the minimum Gm case, the phase error is about 0° whereas for the maximum Gm case, the phase error is as large as 30°. For the specific transistor sizing used in this Miller-C integrator, each additional unit-sized Gm cell will contribute a 1.5° phase error at their respective unity-gain frequencies.
For large capacitive loads, an output buffer can be included in the circuit of
It Note that the phase error contributed by the large Gm cell is not as bad as it appears. As the OTA transfer function is modified by the remainder function R(s), the parasitic pole of each integrator has only a marginal effect on the open-loop response of OTA. To see this, the magnitude and phase response of the OTA with layout parasitics included for orders 2 to 5 is plotted in
In order to measure the impact of the layout parasitics on the OTA as described herein, as well as any coefficient quantization effect, a fully extracted SPICE simulation was performed of a fully differential version of the OTA in a unity-gain configuration. These simulations include all the parasitics in the design, including those that arise from the digital scan chain control lines, pads and ESD structures. Owing to the fully differential nature of the OTA, the OTA will be embedded into the unity-gain resistive feedback circuit shown in
Note that the feedback factor β is no longer equal to one, as was assumed before, and is now equal to 0.5. This, in turn, requires the OTA to have twice the gain it had before. This is accommodated by doubling all the b coefficients in the state-space formulation shown listed in Table III. Moreover, to implement any one of the state-space realizations described in Table III, one considers that the OTA is programmable in terms of unit-sized Gm cells. Hence, the coefficients in Table III are mapped and quantized in terms of integer values. Table VI lists the values of all integrator capacitors.
The OTA amplifier layout was implemented using IBM 130 nm CMOS technology. The design occupies a total active area of 1 mm2 including the 23 bond pads with ESD protection. The active area occupied by the programmable OTA is approximately 0.6 mm2. A schematic layout view of the OTA IC is shown in
A set of five CMOS chips containing the programmable OTA were manufactured and one of these configured on a PCB for unity-gain operation as depicted in
The first test was to verify the operation of the amplifier in a unity-gain configuration in response to a small input step of 20 mV for OTA orders 2 through 5. The measured results in normalized format are plotted in
The second test performed involved increasing the magnitude of the step input from 20 mV to a higher level until the amplifier output showed signs of excessive ringing or slew-rate limiting. The results captured from the benches are shown in
A summary of the measured performance of the OTA (without buffer) is listed in Table VII. Various performance metrics like gain, bandwidth, slew-rate, phase margin, power and active area are listed as a function of the OTA order. Only the slew rate of the 2nd order OTA was observed before the OTA operation exhibits excessive ringing. In addition, these results are compared to five separate prior art OTA realizations.
To further demonstrate the features of OTAs according to some embodiments, two small-signal figure of merits (FOMs) were defined as given by Equations (29A) and (29B) respectively and are used to compare the results of OTAs according to embodiments described herein with prior art results. For OTA orders larger than 3, the OTAs according to embodiments described herein have comparable or better figures of merit. This stems from the very high DC gain that gives the OTAs according to embodiments described herein very high gain bandwidth products (GBPs).
All four orders of the OTA proposed here have high 3-dB bandwidth with a minimum of 10 kHz. While this suggests the proposed designs would have very high gain-bandwidth products, the unity gain frequencies are only moderate between 5 MHz and 20 MHz. This is the result of the multi-pole behavior introduced by the proposed topology in contrast to the single-pole behavior found with all other OTA topologies. The proposed OTA consumes a large active area and static power as the 100 Gm cell assigned in the Miller-C integrator has to account for the effect of various programming numbers as the order of OTA increases. In comparison to other designs, this is a result of its fully programmable nature, an aspect that the prior art designs do not have.
To reduce the overshoot and undershoot associated with high-order OTA designs, a search for a new pole-zero canonical transfer function was undertaken. Through computer optimization methods, a new pole-zero canonical transfer function with reduced over/undershoot was obtained for the 4th order realization as shown in
Implementation of the techniques, blocks, steps and means described above may be done in various ways. For example, these techniques, blocks, steps and means may be implemented in hardware, software, or a combination thereof. For a hardware implementation, the processing units may be implemented within one or more application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs), processors, controllers, micro-controllers, microprocessors, other electronic units designed to perform the functions described above and/or a combination thereof.
The foregoing disclosure of the exemplary embodiments has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Many variations and modifications of the embodiments described herein will be apparent to one of ordinary skill in the art in light of the above disclosure. The scope of the invention is to be defined only by the claims appended hereto, and by their equivalents.
This application claims the benefit of U.S. Provisional Patent Application No. 62/354,178 filed on Jun. 24, 2016, the contents of which are hereby incorporated by reference.
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7075364 | Gudem | Jul 2006 | B2 |
7636003 | Liu | Dec 2009 | B2 |
9319003 | Chen | Apr 2016 | B2 |
20130194040 | Lin | Aug 2013 | A1 |
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20170373650 A1 | Dec 2017 | US |
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62354178 | Jun 2016 | US |