High speed DLL offset cancellation

Abstract

In an embodiment, a primary charge pump and replica charge pump may be coupled to matching control mechanisms and loads. In an embodiment, the replica charge pump may produce an error current originating from charge pump timing mismatches in a steady locked loop state. The error current produced by the replica charge pump may be measured by a difference amplifier to adjust at least one current source to compensate for the error current originating from the timing mismatches. To adjust the current sources, the amplifier may cause the current source to produce an equal but opposite current to cancel the effects of the error current, resulting in a constant output voltage.

Description

BACKGROUND

A charge pump in a phase compare application is used to output a current in response to a difference between two signals applied to the input of a phase or frequency comparator. A positive or negative phase difference at the input of the comparator is converted to a positive or negative current out of the charge pump. An ideal charge pump used with an ideal phase comparator should produce zero average current if no phase difference exists between the two signals being compared. However a charge pump is never ideal due to DC and transient mismatches inherent to any charge pump topology. Even if positive and negative pump current sources are perfectly matched, the time delay to enable or disable the positive and negative output currents may not be equal. The result of this timing mismatch is that even when signals with no phase difference are applied to an ideal phase comparator driving a non-ideal charge pump, the charge pump output average current will be non zero. The severity of this error worsens as the frequency of the phase comparison increases.

While others have focused on eliminating other sources of charge pump error, such as correcting static current mismatches, there is a need to eliminate these transient residual phase errors to reduce noise and offset control loop errors. The invention described is a general method for reducing the transient mismatches observed in commonly used charge pump architectures. The simple circuit techniques allow for reduced design time by boosting the performance of common architectures so that they may be used in applications demanding higher performance and accuracy.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 a is shows an exemplary delay lock loop embodiment of the invention.

FIG. 1 b shows an exemplary configuration of a coupled primary and replica charge pump in an embodiment shown in FIG. 1a.

FIG. 2 shows changes to an initial reference clock signal after processing through different stages in an embodiment.

FIG. 3 a shows an exemplary phase lock loop application of an embodiment of the invention.

FIG. 3 b shows an exemplary configuration of a coupled primary and replica charge pump in an embodiment shown in FIG. 3a.

FIG. 3 c shows a second exemplary configuration of a coupled primary and replica charge pump in an embodiment.

FIG. 4 shows an exemplary method in an embodiment of the invention.

FIG. 5 shows an second exemplary method in an embodiment of the invention.

DETAILED DESCRIPTION

In an embodiment, a primary charge pump and replica charge pump may be coupled to matching control mechanisms and loads. In an embodiment, the replica charge pump may produce an error current originating from charge pump timing mismatches in a steady locked loop state. The error current produced by the replica charge pump may be measured by a difference amplifier to adjust at least one current source to compensate for the error current originating from the timing mismatches. To adjust the current sources, the amplifier may cause the current source to produce an equal but opposite current to cancel the effects of the error current, resulting in a constant output voltage.

The amplifier may control a positive or negative current source to a charge pump to ensure the output voltage remains constant. In an embodiment, the amplifier output may also be coupled to the primary charge pump current source in a feed forward fashion so the primary charge pump transient output current matches that of the replica charge pump in a locked steady state. In an embodiment, feedback in the replica charge pump may cause transient mismatches to be cancelled and in a further embodiment, the steady state voltage at the primary charge pump load may be coupled to the replica charge pump to be used as a reference voltage.

FIG. 1 a is illustrates a delay lock loop (DLL) 100 according to an embodiment of the present invention. The DLL 100 may include a pair of flip flops 101, 102 and inverter 103 connected in a loop and driven by a an input clock (4×). The DLL 100 further may include a delay element 104, a pair of XOR gates 105, 106 and a charge pump system 110. The charge pump system 110 may include a pair of charge pumps 107, 108, respective capacitors VC and VC2 and a driving amplifier 109. In other embodiments phase frequency detectors may be used instead of xor gates for phase differencing.

In the embodiment illustrated in FIG. 1a, the flip flops 101, 102 and inverter 103 generate a variety of oscillating clock signals, shown as 1×a, 1×b and 1×. In this example, the clock inputs of the flip flops 101 and 102 may both be coupled to the 4× reference clock signal. An input of the first flip flop may be coupled to the output of an inverting amplifier 103, an input of a XOR circuit 106 and an input of a delay element 104. The output of the first flip flop 101 may be coupled to the input of the second flip flop 102, and the input of a XOR circuit 105. The output of the second flip flop 102 may be coupled to the input of XOR circuit 105 and the input of inverting amplifier 103.

The output of XOR circuit 105 may be coupled to a control block of charge pump 107. an output of charge pump 107 may be coupled to a capacitor and an input of an amplifier 109. An input of amplifier 109 may also be coupled to the output of a multiplexer, mux 110. A first input of mux 110 may be coupled to a fixed reference voltage source. The fixed reference voltage source may be set to be similar to the mid point of the control voltage range of the VCO 309 or delay element 104. In an embodiment, the fixed reference voltage source may be set around the middle of the charge pump operating range. A second input of mux 110 may be coupled to the output of charge pump 108 in an embodiment. The output of charge pump 108 may also be coupled to a filter or load, which may include the capacitor coupled to the output of charge pump 107. The output of charge pump 108 may also be coupled to a control of delay element 104 to vary the amount of delay from the output of inverting amplifier 103 to an input of XOR circuit 106.

The output of the delay element 104 may be coupled to an input of XOR circuit 106. An output of XOR circuit 106 may be coupled to a control block of charge pump 108. An output from amplifier 109 may be coupled to an input of charge pumps 107 and 108.

FIG. 1 b shows an exemplary configuration of a coupled primary and replica charge pump in an embodiment shown in FIG. 1a. Two current paths are illustrated extending between a first voltage supply VCC and a second voltage supply VEE (say, ground). A first current path may be formed of transistors 135, 158 and a switch 160 (which itself may be a transistor). The first path may be considered to be a first charge pump. A second current path may be formed of transistors 154, 159 and switch 161 (which, again, may be a transistor). The second current path may be considered to be the replica charge pump.

Sources of transistors 153 and 154 may be coupled to a supply line VCC and the gates of the transistors 153 and 154 may be coupled to the output of amplifier 157. A drain of transistor 154 may be coupled to a filter 156, an input of an operational amplifier 157, and a third transistor 159. A reference voltage Vref may be coupled to a second input of amplifier 157. A drain of transistor 153 may be coupled to filter 155 and a fourth transistor 158. The gates of transistors 158 and 159 may be coupled to a supply line voltage Vb. In other embodiments, current sources other than transistors may be used instead.

A drain of transistor 158 may be coupled to a switch 160, which in turn may be coupled to a supply line VEE. A drain of transistor 159 may be coupled to a switch 161, which in turn may also be coupled to supply line VEE. Transistors 154 and 159 may be configured so that twice the current I flows through transistor 159 as transistor 154 when the transistors are active. Similarly, transistors 153 and 158 may be configured so twice the current flow through transistor 158 as 153. In other embodiments, the transistors may have different configurations and/or current ratios. Filters 155 and 156 may be provided as or include capacitors, for example, capacitors VC and VC2 as illustrated in FIG. 1a.

In the embodiment, the switch 160 may be configured to interact with XOR circuit 106, so that the switch 160 closes when XOR circuit 106 output is a first state (say “1”) and the switch opens when XOR circuit 106 output is a second state (“0”). Similarly, switch 161 may be configured to interact with XOR circuit 105 so that when XOR circuit 105 outputs a “1”, the switch is closed and when XOR circuit 105 outputs a “0”, the switch is open.

The coupling shown in FIG. 1b of the primary and replica charge pumps may result in the cancellation of transient voltage mismatches at the two filters. In an embodiment, the voltage at filter 156 may be pegged to the input voltage to amplifier 157. As voltage fluctuation occur at filter 156, these fluctuations may be propagated through the amplifier 157 to the other charge pump resulting in a voltage change at filter 155 mirroring the fluctuation at filter 156. Voltage fluctuations at filter 155, however, may not be propagated to filter 156, as there is no reverse propagation path from filter 155 to 156 during stable operation. At steady state, the amplifier may force the voltages at filters 155 and 156 to match thereby cancelling any transient voltage mismatches between the filters. When the switch 161 is coupled to a reference clock signal, as shown, for example, in FIG. 1a, a replica clock signal may be generated matching the clock signal at switch 161 without dynamic mismatching errors at higher frequencies.

FIG. 2 shows changes to an initial reference clock signal after processing through different stages in an embodiment. In an embodiment, a initial reference clock signal, in this case a 4× clock signal, is coupled to the control lines of both flip flops 101 and 102, which may be initially cleared to output a zero bit signal. At time 21, a rising edge of the reference 4× clock occurs corresponding to a bit representing a ‘1.’ The ‘1’ sent to flip flops 101 and 102 may activate the registers, causing them each to output a ‘0.’ The 1×a and 1×b signals may therefore also both be ‘0’ and the XOR 105 output to the 2×R signal may also be ‘0.’ The ‘0’ output from flip flop 102 may be inverter at inverting amplifier 103, which may result in a ‘1’ being sent to the input of flip flop 101. The 1× signal inputted to XOR circuit 106 and delay element 104 may also be ‘1.’

At time 22, a second rising edge of the reference clock signal 4× may occur corresponding to a ‘1’ bit. The ‘1’ bit in the 4× clock signal may trigger the flip flops 101 and 102, and the ‘1’ previously queued in the input of flip flop 101 may be outputted from flip flop 101. Similarly, the ‘0’ previously outputted from flip flop 101 at time 21 may be queued in the input of flip flop 102 and outputted by flip flop 102 at time 22. Thus, the 1×a signal from the output of flip flop 101 may be a ‘1’ and the 1×b signal from the output of flip flop 102 may be a ‘0.’ Since the 1×a signal is different from the 1×b signal, the 2×R signal at the output of XOR circuit 105 may be a ‘1.’ The 1×b signal may be inverted to a ‘1’ at inverting amplifier 103, result in the 1× signal at the input of XOR circuit 106 being a ‘1.’ The inverted 1×b signal outputted from inverting amplifier 103 may then be sent to the input of flip flop 101.

At time 23, a third rising edge of the reference clock signal 4× may again trigger flip flops 101 and 102. The ‘1’ previously queued in the input of flip flop 101 from the output of inverting amplifier 103 may be outputted from flip flop 101, and the ‘1’ previously queued at the input of flip flop 102 from the prior output of flip flop 101 may be outputted from flip flop 102. Thus, the 1×a and 1×b signal may both be ‘1.’ Since the 1×a and 1b× signals are both the same, the 2×R signal output of XOR circuit 105 may be ‘0.’ The 1× signal from inverting amplifier 103 may also be ‘0,’ and the ‘0’ signal may be sent to the input of flip flop 101.

At time 24, a fourth rising edge of the reference clock signal 4× may trigger flip flops 101 and 102. The ‘0’ previously queued in the input of flip flop 101 from the output of inverting amplifier 103 may be outputted from flip flop 101, and the ‘1’ previously queued at the input of flip flop 102 from the prior output of flip flop 101 may be outputted from flip flop 102. Thus, the 1×a signal may be ‘0’ and the 1×b signal may be ‘1.’ Since the 1×a and 1b× signals are different, the 2×R signal output of XOR circuit 105 may be ‘1.’ The 1× signal from inverting amplifier 103 may also be ‘0’ after inverting the ‘1’ in the 1×b signal and the ‘0’ signal may be sent to the input of flip flop 101.

The delay element 104 may be initially set to a default value and may be adjusted over time so the 2×R signal matches the 2× signal at steady state. In an embodiment, the output of the charge pump 108 is used to adjust the amount of delay in the delay element 104. Mux 110 may also be used to have Vc2 track Vc and a reference voltage, such as the middle of the charge pump operating range, by switching the input to amplifier 109 between the reference voltage and the output of charge pump 108 to further tweak the voltage outputs of charge pumps 107 and 108.

FIG. 3 a shows an exemplary phase lock loop application of an embodiment of the invention. In an embodiment, a reference signal 301 may be coupled to an input of a first phase frequency detector (PFD) 302, and to two inputs of a second PFD 303. In an embodiment, a PFD may detect the phase difference between two input signals and generate an up or down control signal when a reference signal is leading or lagging a feedback signal.

The outputs of the first PFD 301 may be coupled to a control block of a first charge pump 304 and the outputs of the second PFD 302 may be coupled to a control block of a second charge pump 305 in an embodiment. In an embodiment, the charge pump may drive current into or draw current from filter or load, which may include a capacitor, depending on whether the charge pump receives an up or down control signal from the PFD. In an embodiment, the output of the first charge pump 304 may be coupled to a filter 306 and to an input of a voltage controlled oscillator (VCO) 309.

In an embodiment, the filter 306 may convert signals from the charge pump to a control voltage used to adjust the VCO 309. The VCO 309 may output a variable oscillation frequency that varies depending on the applied voltage at the input of the VCO 309. In an embodiment, the VCO 309 may include a module reducing the output frequency by a predetermined factor of “N.” In an embodiment, the output of the VCO 309 may be coupled to a second input of the first PFD 302.

In an embodiment, the outputs of the second PFD 303 may be coupled to an input of a charge pump 305. The output of charge pump 305 may be coupled to a load or filter 308, which may include a capacitor, and an input of an amplifier 307. A second input of amplifier 307 may be connected to a reference voltage Vref, such as the middle of the charge pump operating range. The output of the amplifier 307 may be coupled to an input of both charge pumps 304 and 305.

When the reference signal 301 is coupled to both inputs of PFD 303, the signals may be in phase, and PFD 303 may output both an up and down control signal to charge pump 305 in an embodiment. In an embodiment, the combined up and down control signals may result in matching currents at charge pump 305, so the resulting output at charge pump 305 may proportional to the input from the output of amplifier 307. The output at charge pump 305 may then be sent to filter 308 to generate a voltage input to amplifier 307, which may in turn output an amplified output that is inputted to charge pumps 304 and 305.

In an embodiment, charge pump 304 may receive an up or down control signal from PFD 302. In an embodiment, charge pump 304 may drive current into or draw current from filter 306 depending on whether the control signal is up or down. In an embodiment, the amount of current that is driven or drawn from the filter 306 may depend on the control signal from PFD 302. In an embodiment, the filter 306 may convert the current from charge pump 304 to a voltage for adjusting VCO 309. Over time, the control voltage to the VCO 309 may be adjusted so the VCO 309 outputs an oscillating frequency and phase matching the reference signal 301.

FIG. 3 b shows an exemplary configuration of a coupled primary and replica charge pump in an embodiment shown in FIG. 3a. In an embodiment, transistors 353 and 354 may be coupled to switches 351 and 352 respectively, which may in turn be coupled to a supply line VCC. In an embodiment, the gates of the transistors 353 and 354 may be coupled to the output of amplifier 357. In an embodiment, the remaining end of transistor 354 may be coupled to a filter 356, an input of amplifier 357, and a third transistor 359. In an embodiment, a reference voltage Vref may be coupled to a second input of amplifier 357. In an embodiment, the remaining end of transistor 353 may be coupled to filter 355 and a fourth transistor 358. The gates of transistors 358 and 359 may be coupled to a supply line voltage Vb. In other embodiments, other current sources may be used instead of or in addition to transistors.

In an embodiment, the remaining end of transistor 358 may be coupled to a switch 360, which in turn may be coupled to a supply line VEE. In an embodiment, the remaining end of transistor 359 may be coupled to a switch 361, which in turn may also be coupled to supply line VEE. In an embodiment, each of the transistors 354 and 359 may be configured to enable currents of the same magnitude to flow through when active. In other embodiments, the transistors may have different configurations and/or current ratios. In an embodiment, filters 355 and 356 may include one or more capacitors.

In this embodiment, switch 351 may be configured to interact with the UP output of PFD 302, so that when the UP output is active, the switch 351 is closed and when the UP output is inactive, the switch 351 is open, or vise versa. In an embodiment, switch 352 may be similarly configured to interact with the UP output of PFD 303, switch 360 may be similarly configured to interact with the DOWN output of PFD 302, and switch 361 may be similarly configured to interact with the DOWN output of PFD 303. In other embodiments, the switches may have the reverse configurations, opposite configurations, or different configurations altogether.

FIG. 3 c shows a second exemplary configuration of a coupled primary and replica charge pump in an embodiment to correct both AC and DC error. In an embodiment, transistors 373 and 374 may be coupled to switches 371 and 372 respectively, which may in turn be coupled to a supply line VCC. Transistor 382 may bypass the switches and be connect to the supply line VCC. In an embodiment, the gates of the transistors 373, 374, and 382 may be coupled to the output of amplifier 377. In an embodiment, the remaining ends of transistors 374 and 382 may be coupled to a filter 376, an input of amplifier 377, and a third and fourth transistors 379 and 383. In an embodiment, the remaining end of transistor 373 may be coupled to filter 375, a second input of amplifier 377, and a fourth transistor 378. The gates of transistors 378, 379, and 383 may be coupled to a supply line voltage Vb. In other embodiments, other current sources may be used instead of or in addition to transistors.

In an embodiment, the remaining end of transistor 378 may be coupled to a switch 380, which in turn may be coupled to a supply line VEE. In an embodiment, the remaining end of transistor 379 may be coupled to a switch 381, which in turn may also be coupled to supply line VEE. In an embodiment, each of the transistors may be configured to enable currents of the same magnitude to flow through when active. In other embodiments, the transistors may have different configurations and/or current ratios. In an embodiment, filters 375 and 376 may include one or more capacitors.

In this embodiment, switch 371 may be configured to interact with the UP output of PFD 302, so that when the UP output is active, switch 371 is closed and when the UP output is inactive, the switch 371 is open, or vise versa. In an embodiment, switch 372 may be similarly configured to interact with the UP output of PFD 303, switch 380 may be similarly configured to interact with the DOWN output of PFD 302, and switch 381 may be similarly configured to interact with the DOWN output of PFD 303. In other embodiments, the switches may have the reverse configurations, opposite configurations, or different configurations altogether.

FIG. 4 shows an exemplary method in an embodiment of the invention. In box 401, a reference clock signal may be scaled to achieve a desired cycle length. In some embodiments, it may desirable to have a matched path scaled clock cycle that is double the length of the original cycle time, though in other embodiments other scaled clock cycles may be more desirable.

In box 402, the clock signal may be split into a fixed clock signal component and a variable clock signal component. The fixed clock signal component may be obtained directly from the scaled reference clock signal component without any further adjustments. The variable clock signal component may include an additional variable delay element that may adjust the phase and/or clock cycle length of the clock signal.

In box 403, an initial amplified input signal may be separately adjusted based on split clock signals. In an embodiment, an initial charge pump configuration may adjust input signal according to the fixed clock signal while the replicated charge pump configuration may adjust the input signal variable clock signal.

In box 404, the results of the adjustments may result in different voltages at the output of each respective charge pump configuration. In an embodiment, the output of each charge pump may be adjusted according to the respective fixed and variable clock signals controlling each charge pump configuration, and the adjusted charge pump output may result in different voltages at the input of an amplifier, such as amplifier 109.

In box 405, the delay of the variable scaled clock signal may be adjusted based on the output of the charge pump connected to the variable clock signal. In an embodiment, the delay of the variable scaled clock signal may be adjusted to more closely match the fixed scaled clock signal, since the output of the variable scaled clock signal charge pump may be dependent in part on the output of the fixed scaled clock signal charge pump.

FIG. 5 shows an second exemplary method in an embodiment of the invention. In box 501, a reference clock signal may be split between different phase frequency detectors (PFD). In an embodiment, each of the different PFDs may be used to detect phase differences between the reference clock signal and a different second signal.

In box 502, a phase difference may be detected between the reference clock signal and each of the different second signals. In an embodiment, the second signal may also include the reference clock signal, which may trigger dead band operation as there may be no phase difference between the reference clock signal and itself. In an embodiment, the second signal may also include a signal from a voltage controlled oscillator.

In box 503, the detected phase difference may be used to select a current direction to either cause current to flow into or be drawn from a filter. In an embodiment, a filter may include a capacitor. In an embodiment, when the phase detector indicates that the second signal lags the reference clock signal, a current direction causing current to flow into a filter may be selected. In an embodiment, when the phase detector indicates that the second signal leads the reference clock signal, a current direction causing current to be drawn from a filter may be selected. In an embodiment, when the phase detector indicates that the second signal is in phase with the reference clock signal, a current direction causing current to both flow into and be drawn from the filter may be selected, resulting in no net current.

In an embodiment, a phase difference and current direction may be separately calculated for both the reference clock signal compared to a voltage controlled oscillator output signal and the reference clock signal compared to itself. In box 504, the selected current direction may be applied to an input signal to further amplify the current, either positively or negatively, in the input signal. In an embodiment, the same input signal may be amplified separately for both the reference clock signal compared to itself and the reference clock signal compared to the voltage controlled oscillator signal.

In box 505, a voltage controlled oscillator signal may be generated that is proportional to the adjusted input signal after the amplified current in the selected direction is applied. In an embodiment, the direction of the amplified current, i.e. whether current flows into or out of the filter, may depend on the detected phase difference between the reference clock signal and the prior voltage controlled oscillator output signal.

The foregoing description has been presented for purposes of illustration and description. It is not exhaustive and does not limit embodiments of the invention to the precise forms disclosed. Modifications and variations are possible in light of the above teachings or may be acquired from the practicing embodiments consistent with the invention.

Claims

1. A device comprising: a first current source coupled to a second current source, a single first switch, a first filter, and an input of an amplifier, the single first switch is a sole switch controlling a current flow path between the first current source, the second current source, the first filter, and the input of the amplifier; anda third current source coupled to a fourth current source, a second filter, and a single second switch, the single second switch is a sole switch controlling a current flow path between the third current source, the fourth current source, and the second filter;wherein an output of the amplifier controls current in the first and third current sources.

2. The device of claim 1, wherein a second input of the amplifier is coupled to a reference voltage.

3. The device of claim 1, wherein the first and second filters include a capacitor.

4. The device of claim 1, wherein each current source includes a transistor.

5. The device of claim 4, wherein the second and fourth transistors are configured to provide a gain twice that of the first and third transistors.

6. The device of claim 1, further comprising a fixed reference clock scaling circuit coupled to the first switch and a variable reference clock scaling circuit coupled to the second switch, the variable reference clock scaling circuit also coupled to the third and fourth current sources, wherein a current flowing between the third and fourth current sources adjusts a delay in the variable reference clock scaling circuit.

7. The device of claim 6, wherein the delay is adjusted by adding or subtracting delay to a delay element in the variable reference clock scaling circuit.

8. The device of claim 6, further comprising a first and a second phase differencing XOR circuit coupled to the respective first and second switches, the XOR circuit controlling a switching state of each of the respective switches based on a phase difference.

9. A method comprising: inputting an output of a first and second current source to an amplifier, the second current source activated by a single first switch that is a sole switch controlling a current flow path between the first current source, the second current source, a first filter, and an input of the amplifier;varying a current in the first current source and a third current source based on an output of the amplifier, the third current source coupled to a fourth current source activated by a single second switch that is a sole switch controlling a current flow path between the third current source, the fourth current source, and a second filter; andactivating the single first and second switches to equalize a first voltage at the first filter between the first and second current sources and a second voltage at the second filter between the third and fourth current sources.

10. The method of claim 9, wherein the switches are activated by a reference clock signal.

11. The method claim 10, wherein the reference clock signal is split, scaled, and adjusted for each switch.

12. A device comprising: a first current source coupled to a second current source, a first switch, a first filter, and an input of an amplifier, the first switch is a sole switch controlling a current flow path between the first current source, the second current source, the first filter, and the input of the amplifier;a third current source coupled to a fourth current source, a second filter, and a second switch, the second switch is a sole switch controlling a current flow path between the third current source, the fourth current source, and the second filter;wherein an output of the amplifier controls current in the second and fourth current sources.

13. The device of claim 12, further comprising a first and second phase frequency detector, a first and second output of the first phase frequency detector coupled to the first and second switches respectively, and a first and second output of the second phase frequency detector coupled to the third and fourth switches respectively.

14. The device of claim 13, further comprising a voltage controlled oscillator coupled to the second filter and a first input of the second phase frequency detector.

15. The device of claim 14, further comprising a reference clock signal coupled to a second input of the second phase frequency detector and a first and a second input of the first phase frequency detector.

16. A method comprising: inputting an output of a first and second current source to an amplifier, the second current source activated by a first switch that is a sole switch controlling a current flow path between the first current source, the second current source, a first filter, and an input of the amplifier;varying a current in the first current source and a third current source based on an output of the amplifier, the third current source coupled to a fourth current source, the fourth current source activated by a second switch that is a sole switch controlling a current flow path between the third current source, the fourth current source, and a second filter; andactivating the first and the second switches to equalize a first voltage at the first filter between the first and second current sources and a second voltage at the second filter between the third and fourth current sources.

17. The method of claim 16, wherein the first and second switches are activated by respective outputs of a first phase frequency detector and the third and fourth switches are activated by respective outputs of a second phase frequency detector.

18. The method of claim 17, wherein the first phase frequency detector detects a phase difference between a reference clock signal and itself.

19. The method of claim 17, wherein the second phase frequency detector detects a phase difference between a reference clock signal and an output from a voltage controlled oscillator.

20. The method of claim 19, wherein the output of the voltage controlled oscillator is determined by a voltage at the second filter.