There are multiple architectures or topologies for Delta-Sigma Analog-to-Digital Converters (ADCs). One such architecture uses an input feed-forward path to minimize swings on integrator outputs. In such topologies a feed-forward path feeds ADC input to the quantizer, which is typically a so-called “sub-ADC.” This sub-ADC is typically a comparator in a single bit ADC and in a multi-bit ADC it is a flash ADC, or the like, having a number of comparators, by way of example sixteen comparators for a four bit quantizer.
Advantageously, in such an input feed-forward topology for delta-sigma ADC, the integrators in the discrete-time loop filter 116, exhibit low voltage swings at their outputs. However, because sub-ADC 108 is directly sampling the input there is kickback (118) from the quantizer to the input U(s). Since the driving circuit generating signal U(s) has finite bandwidth and nonzero output impedance the disturbance caused by this kickback may not settle in one clock cycle. This leads to distortion of the signal being sampled by the input sampling circuit 110. Therefore, in such a delta-sigma ADC architecture with input feed-forward path, this kickback from quantizer 108 limits the distortion performance of ADC 100.
Embodiments of the present disclosure for improving distortion performance in a delta-sigma Analog-to-Digital Converter (ADC), which may be at least a part of an Integrated Circuit (IC), may include filtering input to a feed-forward path, such as may extend from an input to the delta-sigma ADC to a feed-forward summing circuit disposed between the loop filter and quantizer of a delta-sigma ADC.
Hence, an apparatus for improving distortion performance in a delta-sigma ADC (device) might comprise a filter disposed in an input feed-forward path of the delta-sigma ADC. The filter may be a low pass filter, for example, a Resistor-Capacitor (RC) circuit. Regardless, the filter has a cut-off frequency outside the passband of the ADC. The filtering provided may be continuous-time filtering, even if the delta-sigma ADC is a discrete-time delta-sigma ADC.
Having thus described the present systems and methods in general terms, reference will now be made to the accompanying drawings, wherein:
The techniques of this disclosure now will be described more fully hereinafter with reference to the accompanying drawings. These techniques may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of this disclosure to those skilled in the art. One skilled in the art may be able to use the various embodiments described herein.
For example, while this disclosure may describe the present systems and methods referring to one specific type of delta-sigma Analog-to-Digital Converters (ADCs) (i.e. discrete-time ADCs) the present systems and methods are not limited to this type of ADC or ADC modulators. For example, embodiments of the present systems and methods may also be implemented in continuous-time feed-forward delta-sigma ADCs or ADC modulators. Further, while the present systems and methods are described herein with reference to ADCs, it should be appreciated that as discussed herein such discussed ADCs and ADC modulators may be considered one and the same.
While input feed-forward delta-sigma ADCs have the advantage of there being no signal content at any of the ADC integrator outputs, leading to smaller voltage swings, which may then allow linearity requirements for the the integrators to be relaxed, the kickback from the input feed-forward branch can limit distortion performance in such ADCs.
The present systems and methods isolate the delta-sigma ADC input from the quantizer. One proposed means to do so may involve inserting a buffer in the input branch.
However, in accordance with the present systems and methods the feed-forward delta-sigma ADC quantizer may be isolated from ADC input, and hence the ADC input sampling circuitry or ADC driver circuitry, using a filter. Thus, an implementation for improving distortion performance in a delta-sigma ADC with input feed-forward topology includes filtering input to (e.g. in) a feed-forward path (e.g. in the feed-forward path).
A resulting delta-sigma ADC (IC) may have a hybrid topology with an input feed-forward filter which is continuous-time and all other circuits operating in discrete-time. This leads to the ADC transfer function, which is no longer independent of ADC clock frequency.
Thus, in input feed-forward delta-sigma ADC 300 analog voltage U(s), an un-sampled analog signal, is fed forward to feed-forward summing circuit 306, via feed-forward path 304. Analog voltage U(s) is filtered at continuous-time filter 302 to provide filtered signal U′(s), which may be consider equal to U(s)G(s), which in turn, is sampled at feed-forward sampling network 308 to provide filtered and sampled signal U′(z), a sampled analog input, and hence a discrete-time signal, which is delivered to quantizer 310, via summing circuit 306.
Analog input voltage U(s) is separately sampled by ADC sampling network 312 to provide sampled voltage U(z), a sampled analog input, and hence a discrete-time signal. U(z) and output of sub-Digital-to-Analog Converter (sub-DAC) 314 are differentiated in ADC delta circuit 316, providing an analog voltage at the input of discrete-time loop filter H(z) 318. Discrete-time loop filter 318 may include one or more integrators, in accordance with various discrete-time delta-sigma ADC architectures.
The output voltage of discrete-time loop filter 318 is combined with the filtered sampled input signal U′(z) by summing circuit 306. Depending on the resulting voltage, the output of quantizer 310 is changed. Sub-DAC 314 responds on the next clock phase by changing its analog output voltage, causing discrete-time loop filter 316 to progress in the opposite direction and forcing the value of ADC digital output Y(z), to track the average value of the input U(s).
Because (continuous-time) filter 302 G(s) is inserted in input feed-forward path 304 kickback from quantizer 310 is reduced, particularly kickback created by input feed-forward path sampling network 308 is minimized, minimizing impact on ADC input sampling circuit 312 and/or driver, or the like, providing analog input U(s).
The feed-forward path filter 404 disposed in input feed-forward path 406 may be a passive filter, such as the illustrated first order passive low pass RC circuit. In discrete-time input feed-forward delta-sigma ADC 402 analog voltage U(s), an un-sampled analog signal is fed forward to feed-forward summing circuit 408, via feed-forward path 406. Analog voltage U(s) is filtered at continuous-time passive filter 404 to provide filtered signal U′(s), which may be considered equal to U(s)G(s), which is, in turn, sampled at feed-forward (switched-capacitor) sampling network 410 to provide filtered and sampled signal U′(z), a sampled analog input, and hence a discrete-time signal, which is delivered to sub-ADC quantizer 412, via summing circuit 408.
Analog input voltage U(s) is separately sampled by ADC (switched-capacitor) sampling network 414 to provide sampled voltage U(z), a sampled analog input, and hence a discrete-time signal. U(z) and output of sub-DAC 416 are differentiated in ADC delta circuit 418, providing an analog voltage at the input of discrete-time loop filter 420. The number of integrators making up discrete-time loop filter 420, or the like may define the “order” of the ADC. For example, a second order ADC may have two integrators, third order ADC may have three integrators etc.
The output voltage of discrete-time loop filter 420 is combined with the filtered sampled input signal U′(z) by summing circuit 408. Again, the output of sub-ADC quantizer 412 may be changed, dependent on the resulting voltage. Sub-DAC 416 responds on the next clock phase by changing its analog output voltage, causing discrete-time loop filter 418 to progress in the opposite direction and forcing the value of the ADC digital output Y(z) (such as to an ADC decimation filter), to track the average value of the input U(s).
Again, because of passive continuous-time RC filter 404 in input feed-forward path 406, kickback from quantizer 412 is reduced, particularly kickback created by (switched-capacitor) feed-forward path sampling network 410, minimizing impact on ADC (switched-capacitor) input sampling circuit 414 and/or a driver circuitry, or the like, providing analog input U(s).
As noted, filter 302 or 404 may be a continuous-time filter, in that it operates at all times, regardless of the sampling state of the analog signal. That is, although ADC 300 or 402 may be discrete-time (switched-capacitor), wherein all transfer functions are in the “z” (discrete-time or sampled) domain, the filter may be implemented in the “s” (continuous-time) domain. Thus, in such examples, only the filter transfer function is in the s-domain, the rest of the ADC operates in the z-domain. However, embodiments of the present systems and methods may be implemented in continuous-time feed-forward delta-sigma ADCs, wherein both the feed-forward filter and the ADC operating the s-domain.
As noted, continuous-time filter 302 G(s) or 404 may take the form of a low-pass RC filter circuit. Such a low pass filter passes signals with a frequency lower than a certain cutoff frequency and attenuates signals with frequencies higher than the cutoff frequency. The amount of attenuation for each frequency depends on the filter design. High frequency input signals, such as may be handled by the ADC devices described herein, an input feed-forward path employing a filter, particularly a passive filter, in accordance the present systems and methods, may be attenuated. Thus, a cut-off frequency of filter 302 or 404 is outside a passband selected to pass input signals U(s). For higher frequency inputs embodiments, antialiasing filter may be disposed in front of ADC 402 to attenuate those high frequency inputs.
Hence, as evidenced in
Many modifications and other embodiments will come to mind to one skilled in the art to which this disclosure pertains having the benefit of the teachings presented in the foregoing descriptions, and the associated drawings. Therefore, it is to be understood that the techniques of this disclosure are not to be limited to the specific embodiments disclosed. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
This application is a continuation of U.S. Nonprovisional application Ser. No. 15/153,384, filed May 12, 2016, which claims the benefit of U.S. Provisional Application No. 62/273,755, filed Dec. 31, 2015, and of U.S. Provisional Application No. 62/160,450, filed May 12, 2015, the disclosures of which are incorporated herein by reference in their entirety.
Number | Date | Country | |
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62273755 | Dec 2015 | US | |
62160450 | May 2015 | US |
Number | Date | Country | |
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Parent | 15153384 | May 2016 | US |
Child | 15651077 | US |