The technology described in this disclosure relates generally to digitally controlled oscillators (DCOs) and more particularly to the use of DCOs in phase locked loops (PLLs).
All-digital PLLs (ADPLLs) are widely used in advanced complementary metal-oxide-semiconductor (CMOS) based semiconductor devices. There they exploit the naturally fine resolution of voltage-controlled oscillators (VCOs), e.g., digitally-controlled oscillators (DCOs), thus reducing area and power dissipation versus analog PLLs.
Aspects of the present disclosure are best understood from the following detailed description when read with the accompanying figures. It is noted that, in accordance with the standard practice of the industry, various features are not drawn to scale. In fact, the dimensions of the various features may be arbitrarily increased or reduced for clarity of discussion.
The following disclosure provides many different embodiments, or examples, for implementing different features of the provided subject matter. Specific examples of components and arrangements are described below to simplify the present disclosure. These are, of course, merely examples and are not intended to be limiting. In addition, the present disclosure may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed.
Further, spatially relative terms, such as “beneath,” “below,” “lower,” “above,” “upper” and the like, may be used herein for ease of description to describe one element or feature's relationship to another element(s) or feature(s) as illustrated in the figures. The spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. The apparatus may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein may likewise be interpreted accordingly.
DCOs can be implemented in a variety of forms. For example, an inductor-capacitor (LC) based DCO, which also can be referred to as an LC-tank, can achieve improved phase noise (PN) at lower power consumption, with low frequency pushing, and immunity from process and temperature variations. However, there is a strong non-linear behavior of the LC-based DCO across the overall tuning band. Such non-linearity can result in a potential stability issue and can increase uncertainty in the loop's behavior. In some embodiments, systems and methods described herein relate to techniques for compensating for the nonlinear behavior of digitally-controlled oscillator (DCO) gain and related systems and devices. Further embodiments describe interpolation based compensation techniques for the cubic behavior of DCO gain, and related systems and devices, such as center linear interpolation based compensation techniques, systems, and devices. For example, certain embodiments describe clock generation techniques, LC-tank oscillators (VCOs/DCOs), nonlinear oscillator gain, linear interpolation techniques, frequency hopping, and/or fast locking, and suitable combinations thereof.
Certain embodiments herein describe generating stable and finely tuned frequencies with a DCO, such as for use in generating clock signals in digital circuitry (e.g., in computer processors), generating frequency hopped signals such as for use in cellular communications, and the like. Certain embodiments describe a method for locking a phase locked loop (PLL), such as an all-digital PLL (ADPLL), to a frequency generated by a DCO that exhibits nonlinear gain as a function of frequency and thus otherwise may be difficult to lock to stably with a PLL. Certain embodiments provide one or more of the following advantages: the nonlinear behavior of DCO gain can be predicted and thus used to lock to the frequency of the DCO with a PLL without the need for measuring the frequency of the DCO at runtime, and hence provides one or more of (1) reduction of phase error when locking to the frequency of the DCO, (2) more rapid locking to the frequency of the DCO, (3) finer tuning to the frequency of the DCO, and (4) more stable generation of clock signals or communication frequencies.
The details of the example methods, systems, and devices of the present disclosure are described in the attached disclosure and drawings. It should be noted that the present technology is not limited to silicon based DCOs, nor to DCOs with cubic gain behavior, but also is applicable to DCOs based on other materials and/or with other nonlinear behavior.
In some embodiments, a relationship that ties the frequency step ΔfT of a DCO, such as DCO 120 illustrated in
ΔfT(f)=−2π2(L·ΔCT)f3 (1)
in which L is the LC-tank inductance. Both L and ΔCT are constants for a stable process, voltage, and temperature (PVT). In some embodiments, L and ΔCT are the only unknowns and subject to the PVT variations on the right-hand side of the equation, so it can make sense to group them together as a product. The resonating frequency f is controlled by the total capacitance C of the LC-tank. f is known precisely (within a frequency control word (FCW) resolution—1.5 Hz/LSB) by virtue of the ADPLL loop operation.
Because KDCO=|ΔfT|, equation (1) can be rewritten as equation (2):
KDCO(f)=2π2(L·ΔCT)f3 (2)
Taking the derivative of KDCO with respect to frequency f results in equation (3):
In some embodiments, the KDCO estimate, {circumflex over (K)}DCO, is generated by gain estimation module 112 in a manner such as described elsewhere herein, and used in the ADPLL frequency synthesizer in the denominator of the DCO normalizing gain multiplier of value x, e.g., provided to MUX 114 for use in generating x based on {circumflex over (K)}DCO and the external reference frequency fR (which reference frequency can be generated by ADPLL 110) such as illustrated in
In some embodiments, an exemplary purpose of this is to conveniently decouple the phase and frequency information throughout the system from the PVT variations that normally affect the gain KDCO of the DCO 120. For example, the frequency information can be normalized to the value of external reference frequency fR using {circumflex over (K)}DCO. Such normalization alternatively can be performed within the DCO, e.g., within a normalized DCO (nDCO) 130 such as illustrated in
The normalizing gain multiplier x based on the estimated gain {circumflex over (K)}DCO can be expressed as x=fR/{circumflex over (K)}DCO, or alternatively a normalizing gain multiplier x based on the actual KDCO can be expressed as x=fR/KDCO. In either embodiment, the generation of x can be performed on a per-packet basis with a just-in-time method using dedicated hardware or software modules, e.g., gain estimation module 112 and MUX 114 such as illustrated in
To further reduce the design complexity of digital coding, the nonlinear (e.g., cubic) behavior of the DCO gain can be estimated using one or more linear functions, e.g., using linear interpolation. For example, in some embodiments taking the derivative of x=fR/KDCO (e.g., based on the actual DCO gain KDCO rather than the estimated DCO gain {circumflex over (K)}DCO) as a function of frequency results in equation (5):
which could be conveniently written as equation (6):
Equation (6) reveals that, in some embodiments, the DCO gain variation ΔKDCO is roughly 3 times that of the frequency variation.
The term y0[k] is denormalized for the particular packet frequency f, such that y[k] could be used as the DCO gain multiplier. In this method the just-in-time calculated sample, as considered too noisy, is not immediately substituted for the normalizing gain multiplier, but rather it is input to the filtering algorithm. Then, the filtering is performed at 240 according to the equation of a “leaky integrator” in equation (8):
0[k]=(1−α)·0[k−1]+α·x0[k] (8)
where α is a coefficient of a first-order infinite impulse response (IIR) filter and y0[k] is the filtered normalized value. For practical implementation reasons, α=2−λ where λ is an integer. This way, the multiplication by can be realized as a right bit shift operation.
At 250, the new packet frequency f is determined. The denormalization equation for the filtered multiplier y, calculated at 260, is shown in equation (9):
In equation (9), y corresponds to ΔKDCO, f0 corresponds to the frequency at which the gain variation is 100%, and y0 corresponds to the value of ΔKDCO at which the gain variation is 100%. At 270, the calculated value of y is written and/or output as the DCO gain multiplier.
The reduced digital design can benefit from the reduction from a cubic polynomial to a linear equation. For example,
After deriving non-linear gain of the DCO (operation 530), a linear interpolation could be used to reduce the frequency error (operation 540), e.g., a center linear interpolation such as described herein with reference to equation (7) and
Because the gain of the DCO varies nonlinearly as a function of frequency, the value of {circumflex over (K)}DCO used to compensate for such nonlinearity similarly can change as a function of frequency. Accordingly, in each different channel (frequency band) to be generated by the DCO, there may be a difference in the DCO gain for use in generating the linear formulas (F1,F2). In some embodiments, {circumflex over (K)}DCO could be calculated by adopting the Δf into the equation. Alternatively, the different values of DCO gain, KDCO1 . . . KDCON could be stored in a lookup table and selected based on the channel (frequency band) selection (operation 550). For example, when the system receives a channel hopping (frequency changing/frequency locking) request, the DCO OTW calculator may use the lookup table to obtain the corresponding DCO gain to achieve the accurate output frequency and to generate an OTW based thereon (operation 560) which is provided to the DCO (operation 570) for use in generating a frequency by the DCO, for example, twice the desired frequency used by the application fckv as shown in
In certain embodiments herein, the predicted DCO gain can be close to the actual silicon behavior, which can significantly reduce the phase error in the ADPLL at the beginning of the phase locking process. So this technique could also help to improve the locking time and settling time.
Arithmetic module 620 of PLL 600 illustrated in
and the normalizing gain multiplier x(CH) for that channel can be expressed as:
Arithmetic module 620 (e.g., multiplier module) can be configured to multiply OTWPRE by x(CH) so as to generate output OTWHOP for the particular hopped frequency at channel CH. As shown in
Arithmetic module 630 of PLL 600 illustrated in
In one exemplary implementation, the channels CH and CH20 are at double the Bluetooth band, and the output of DCO 640 is input to an arithmetic module 650 (e.g., a module configured to divide the DCO output by 2), so that PLL 600 and DCO can have relatively small modules as compared to the size of modules that may be needed to directly generate a DCO output within the Bluetooth band. The desired Bluetooth frequency is represented by fckv.
An OTW, e.g., the OTW in the DCO circuit 120 or the DCO circuit 640, may comprise the inputs to the exemplary DCO circuit 1200 listed in the above table, including FM, Fine, COAR, PVT, HOP1, HOP2.
Flow chart 1300 also includes an operation of generating a normalizing gain multiplier based on the reference frequency and an interpolation of the nonlinear function of frequency of the DCO gain (operation 1320). For example, ADPLL 110 illustrated in
Flow chart 1300 also includes an operation of multiplying a normalized tuning word (NTW) by the normalizing gain multiplier x to obtain an oscillator tuning word (operation 1330). For example, ADPLL 110 illustrated in
Flow chart 1300 also includes an operation of inputting the OTW to the DCO to cause the DCO to hop to a channel (operation 1340). For example, ADPLL 110 illustrated in
Note that any suitable combination of modules provided herein suitably can be integrated with or coupled to the PLL or the DCO as appropriate. For example, any suitable combination of some or all of the gain estimation module, multiplexer, and arithmetic module mentioned with reference to
Under one exemplary aspect provided herein is derived a nonlinear DCO gain behavior as a cubic function of oscillation frequency. For example, in some embodiments the DCO gain will increase cubically as the oscillation frequency increases. The present disclosure, among other things, shows that this nonlinear behavior is predictable and independent of the process, voltage and temperature (PVT) variation. Based on derivation of this nonlinear (e.g., cubic) gain, for example based on a center linear interpolation, the free run DCO frequency could be substantially or exactly achieved without the need for measurement of the gain. Under another exemplary aspect provided herein, a linear approach to mimic the silicon behavior is not enough for the finest resolution application. For example, a interpolation from center of the curve could greatly improve the predicted error between silicon and simulation behavior. Under another exemplary aspect provided herein, the present approach could be implemented for any type of DCO in the fast locking applications. For example, it could help to minimize the phase error in the beginning of locking progress.
Accordingly, a derived cubic rule of the nonlinear behavior of DCO gain is provided. A linear interpolation could help to get an accurate DCO gain with less complexity of design. A center linear interpolation technique further can improve the DCO gain. A “just in time” DCO gain calibration flow can include use of a calculator output a final normalized DCO gain, a multiplexer (mux) configured to select the right normalized DCO gain, and a multiplier configured to change the NTW to OTW when the calculation is completed. Typically, “calibration” implies that a series of steps that have been performed prior to the operation of hardware. However, the term “just in time calibration” is used here to describe a calibration-type process that can be performed during the operation of the hardware and “just in time” for the outputs to be generated. A completed DCO gain calibration flow for channel hopping (frequency band selection) can include use of a derived cubic formula, a inductance effect to the frequency, a non-linear DCO gain curve, a center linear interpolation equation, a lookup table, an OTW calculator, and a DCO. It could be adopted in any frequency hopping, fast locking and frequency prediction application. The calibration could be combined with any other type of DCO gain/frequency calibration, for example linear calibration (binary errors). The DCO design could be any type of LC-tank oscillator, for example inductors and/or transformers. The capacitor bank is not limited to the example and the combination is not limited to binary controlled or unit-weighted. The DCO gain after compensation can in be the same overall frequency range. The DCO frequency curve can be linear to the oscillation frequency after compensation.
In one embodiment, a method is provided for controlling a digitally controlled oscillator (DCO). A first normalized tuning word (NTW) corresponding to a first channel of the plurality of channels is generated. A first normalizing gain multiplier X is generated based on the nonlinear function of frequency, on an estimate of the nonlinear function of frequency, at a first frequency corresponding to the first channel. The first NTW is multiplied by the first X to obtain a first oscillator tuning word (OTW). The first OTW is input to the DCO to cause the DCO to hop to the first channel.
In another embodiment, a system is provided for controlling a digitally controlled oscillator (DCO). The system comprises: a phase-locked loop (PLL) is configured to generate a plurality of normalized tuning words, each NTW corresponding to a respective channel of the plurality of channels; a DCO having a gain that is a nonlinear function of frequency; a multiplexer configured to generate a plurality of normalizing gain multipliers X, each X being based on a reference frequency fR and the nonlinear function of frequency, or an estimate of the nonlinear function of frequency, at a respective frequency of a channel of the plurality of channels; and an arithmetic module configured to generate a plurality of oscillator tuning words (OTWs) based on a respective NTW and a respective X, wherein the DCO hops among the channels based on respective OTWs of the plurality of OTWS.
In yet another embodiment, a normalized digitally controlled oscillator (nDCO) comprises: a digitally controlled oscillator (DCO) having a gain that is a nonlinear function of frequency; a multiplexer configured to generate a plurality of normalizing gain multipliers X, each X based on a reference frequency fR and the nonlinear function of frequency, or an estimate of the nonlinear function of frequency, at a respective frequency of a plurality of frequencies; and an arithmetic module configured to generate a respective oscillator tuning word (OTW) based on each X, the DCO generating a respective frequency based on each OTW.
The foregoing outlines features of several embodiments so that those skilled in the art may better understand the aspects of the present disclosure. Those skilled in the art should appreciate that they may readily use the present disclosure as a basis for designing or modifying other processes and structures for carrying out the same purposes and/or achieving the same advantages of the embodiments introduced herein. Those skilled in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the present disclosure, and that they may make various changes, substitutions, and alterations herein without departing from the spirit and scope of the present disclosure.
This written description and the following claims may include terms, such as “on,” that are used for descriptive purposes only and are not to be construed as limiting. The embodiments of a system, PLL, and/or DCO described herein can be manufactured, used, or shipped in a number of configurations.
This application is a continuation application of U.S. patent application Ser. No. 16/106,163, filed Aug. 21, 2018, entitled “Compensation Technique for the Nonlinear Behavior of Digitally,” which claims priority to U.S. Provisional Patent Application No. 62/549,004, filed Aug. 23, 2017 and entitled “Compensation Technique for the Nonlinear Behavior of Digitally-Controlled Oscillator (DCO) Gain,” which are incorporated herein by reference in their entireties.
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Staszewski, Robert, Leipold, Dirk, Muhammad, Khurram, Balsara, Poras; Digitally Controlled Oscillator (DCO)-Based Architecture for RF Frequency Synthesis in a Deep-Submicrometer CMOS Process; IEEE Transactions on Circuits and Systems—II: Analog and Digital Signal Processing, 50(11); pp. 815-828; Nov. 2003. |
Staszewski, Robert, Leipold, Dirk, Balsara, Poras; Just-In-Time Gain Estimation of an RF Digitally-Controlled Oscillator for Digital Direct Frequency Modulation; IEEE Transactions on Circuits and Systems—II: Analog and Digital Signal Processing, 50(11); pp. 887-892; Nov. 2003. |
Number | Date | Country | |
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20200244271 A1 | Jul 2020 | US |
Number | Date | Country | |
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62549004 | Aug 2017 | US |
Number | Date | Country | |
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Parent | 16106163 | Aug 2018 | US |
Child | 16851452 | US |