KR20230008487A - phase calibration circuit for charge pump - Google Patents

Abstract

The present invention relates to a phase calibration circuit for a charge pump, which comprises: a phase detector which receives a pull-up signal (UP) and a pull-down signal (DN), which are output signals of a phase frequency detector, detects a phase difference, and outputs a phase difference detection signal (PD_OUT); and a counter which receives the phase difference detection signal (PD_OUT) and outputs a charge control signal (S_charge) or a discharge control signal (S_discharge). The output characteristics of the phase locked loop can be improved by minimizing, through calibration, current mismatch generated from the charge pump within the phase locked loop.

Description

Phase calibration circuit for charge pump {phase calibration circuit for charge pump}

The present invention relates to a phase-correction circuit of a charge pump, and more particularly, to a charge pump implemented to improve output characteristics of a phase-locked loop by minimizing a mismatch of current generated by a charge pump in a phase-locked loop through correction. It is for the phase correction circuit of the pump.

In general, a phase locked loop (PLL) is a frequency feedback type circuit that generates a signal having an arbitrary frequency in response to the frequency of a signal input from the outside. The phase-locked loop is a circuit that detects a frequency and phase difference between a reference signal and an oscillation signal, and synchronizes the phase of the oscillation signal to a desired frequency by means of a pull-up or pull-down signal according to the detected frequency and phase difference. Such a phase-locked loop circuit is widely used in interfaces for high-speed data communication, frequency synthesis circuits, or clock recovery circuits in data processing circuits.

1 is a block diagram showing a general phase locked loop.

Referring to FIG. 1, the phase-locked loop 100 includes a phase frequency detector (PFD) 110, a charge pump circuit (CP) 120, and a loop filter (LPF) 130. ), a voltage controlled oscillator (VCO) 140 and a divider (DIVIDER) 150.

The phase frequency detector 110 receives a reference signal (Fref) and a feedback signal (F _div ), compares the phase and frequency of the two signals, and generates a pull-up signal (UP) or a pull-down (UP) corresponding to the comparison result. pull-down) signal (DN) is output. Here, the phase frequency detector 110 generates the pull-up signal UP when the phase of the reference signal (F _ref ) is ahead of the phase of the feedback signal (F _div ), and the phase of the reference signal (F _ref ) is the feedback signal The pull-down signal DN may be generated when it lags behind the phase of (F _div ).

The charge pump circuit 120 receives the pull-up signal (UP) or pull-down signal (DN) of the phase frequency detector 110 and charges the loop filter 130 in response to the pull-up signal (UP) or pull-down signal (DN). is charged, or the charge charged in the loop filter 130 is discharged.

The loop filter 130 is implemented in a low pass filter structure, filters high-frequency components generated during loop operation, and applies a voltage to the voltage controlled oscillator 140 through a change in the amount of charge accumulated using a capacitor. do.

The voltage controlled oscillator 140 generates an oscillation signal F _out synchronized with the reference signal F _ref in response to the voltage output from the loop filter 130 and provides it to the outside. The divider 150 divides the oscillation signal F _out at a constant division ratio to generate a feedback signal F _div , and provides the feedback signal F div to the phase frequency detector 110 .

FIG. 2 is a circuit diagram illustrating the charge pump circuit shown in FIG. 1 .

Referring to FIG. 2 , the charge pump circuit 120 includes a bias current generator 210, a pull-up current source 220, a first driving switch 230, a pull-down current source 240, and a second driving switch 250. do. The bias current generator 210 generates a bias current Ibias. The bias current generator 210 includes a bias current source 212 that generates the bias current Ibias and an NMOS transistor M1 that grounds the bias current source 212 .

The pull-up current source 220 generates a reference current (I _ref ) based on the bias current (I _bias ), and sources the charging current (I _charge ) to the output node (N1) according to the reference current (I _ref ). do. The pull-up current source 220 includes PMOS transistors M2 and M3 constituting current mirrors.

The first driving switch 230 is connected between the power supply voltage VDD node and the output node N1 and performs a switching operation in response to the pull-up signal UP. The first driving switch 230 may include a PMOS transistor M4.

The pull-down current source 240 generates a reference current I _ref based on the bias current I _bias , and sinks the discharge current I _discharge from the output node N1 according to the reference current Iref. . The pull-down current source 240 includes NMOS transistors M5 and M6 constituting a current mirror.

The second driving switch 250 is connected between the output node N1 and the ground voltage (GND) node, and performs a switching operation in response to the pull-down signal (DN). The second driving switch 250 may include an NMOS transistor M7.

The above-described charge pump circuit 120 controls the relationship between the charging current (I _charge ) and the discharging current (I _discharge ) by the channel length modulation phenomenon of the PMOS transistor (M3) and NMOS transistor (M7) operating as current sources. Mismatches can occur.

When a mismatch between the charging current (I _charge ) and the discharging current (I _discharge ) occurs in the charge pump circuit 120 , characteristics of an output signal of the phase locked loop 100 may deteriorate. Accordingly, there has been a need for a phase correction circuit capable of improving a mismatch between a charge current (I _charge ) and a discharge current (I _discharge ) in the charge pump circuit 120 .

A technical problem to be achieved by the present invention is to provide a phase correction circuit of a charge pump implemented to improve output characteristics of a phase-locked loop by minimizing a mismatch of a current generated by a charge pump in a phase-locked loop. there is.

In order to achieve the above object, a phase correction circuit of a charge pump according to an embodiment of the present invention is a phase correction circuit of a charge pump in a phase-locked loop, and a pull-up signal (UP) and a pull-down signal ( a phase detector that receives DN), detects a phase difference, and outputs a phase difference detection signal (PD_OUT); and a counter receiving the phase difference detection signal PD_OUT and outputting a charge control signal S _charge or a discharge control signal S _discharge .

In order to achieve the above object, a phase correction circuit of a charge pump according to another embodiment of the present invention includes a pull-up signal (UP) and a pull-down signal that are output signals of a phase frequency detector in a phase correction circuit of a charge pump in a phase-locked loop. a time amplifier that receives (DN) and amplifies it to output an amplified pull-up signal (TA_UP) and an amplified pull-down signal (TA_DN); a phase detector detecting a phase difference between the amplified pull-up signal TA_UP and the amplified pull-down signal TA_DN and outputting a phase difference detection signal PD_OUT; and a counter receiving the phase difference detection signal PD_OUT and outputting a charge control signal S _charge or a discharge control signal S _discharge .

According to the phase-correction circuit of the charge pump according to the present invention, there is an advantage in that output characteristics of the phase-locked loop can be improved by minimizing the mismatch of the current generated by the charge pump in the phase-locked loop through correction.

1 is a block diagram showing a general phase locked loop.
2 is a circuit diagram showing a charge pump circuit in the phase locked loop shown in FIG. 1;
3 is a block diagram showing a phase locked loop including a phase correction circuit of a charge pump according to the present invention.
4 is a block diagram illustrating a phase correction circuit of a charge pump according to an embodiment of the present invention.
5 is a block diagram illustrating a phase correction circuit of a charge pump according to another embodiment of the present invention.
FIG. 6 is a circuit diagram of a time amplifier of the phase correction circuit of the charge pump according to FIG. 5 .
FIG. 7 is a diagram for explaining the operation of the time amplifier of the phase correction circuit shown in FIG. 6;
FIG. 8 is a circuit diagram of a phase detector of the phase correction circuit of the charge pump according to FIG. 5 .
9 is a circuit diagram of a charge pump for phase correction according to the present invention.
FIG. 10 is a timing diagram illustrating an embodiment of a correction operation of the phase correction circuit of the charge pump according to FIG. 5 .

Since the present invention may have various changes and various forms, specific embodiments are illustrated in the drawings and described in detail in the text. However, it should be understood that this is not intended to limit the present invention to the specific disclosed form, and includes all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Unless otherwise defined, all terms used in the text, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in this application, it should not be interpreted in an ideal or excessively formal meaning. don't

Hereinafter, specific contents of the present invention will be described in detail with reference to the drawings.

3 is a block diagram showing a phase-locked loop including a phase correction circuit of a charge pump according to the present invention, and FIG. 4 is a block diagram showing a phase correction circuit of a charge pump according to an embodiment of the present invention.

Referring to FIG. 3, the phase locked loop 300 including the phase correction circuit of the charge pump according to the present invention includes a phase frequency detector (PFD, 310), a charge pump circuit (CP, 320), and a loop filter (LPF, 330). , a voltage controlled oscillator (VCO, 340), a divider (DIVIDER, 350) and a phase correction circuit (CAL, 360).

The phase-locked loop 300 shown in FIG. 3 is the same as the phase-locked loop 100 shown in FIG. 1 except for the configuration of correcting the phase of the charge pump circuit 320 by the phase correction circuit 360. A detailed description of other configurations will be omitted.

Referring to FIG. 4 , the charge pump phase correction circuit 360 according to an embodiment of the present invention includes a phase detector (PD) 361 and a counter 362.

The phase detector 361 receives the pull-up signal UP and the pull-down signal DN, detects a difference therebetween, and outputs a phase difference detection signal PD_OUT.

The phase difference detection signal PD_OUT outputs '1' when the phase of the pull-up signal UP leads the pull-down signal DN, and outputs '0' when the phase of the pull-up signal UP lags behind the pull-down signal DN. '.

When the output of the phase difference detection signal PD_OUT is '1', it means that the charge current of the charge pump 320 is less than the discharge current. Therefore, when the output of the phase difference detection signal PD_OUT is '1', the charging current control signal S _charge is output using the counter 362 so that more charging current I _charge flows.

Conversely, when the output of the phase difference detection signal PD_OUT is '0', it means that the charging current of the charge pump 320 is flowing more than the discharging current. Therefore, when the output of the phase difference detection signal PD_OUT is '0', the discharge current control signal S _discharge is output using the counter 362 so that more discharge current I _discharge flows.

5 is a block diagram illustrating a phase correction circuit of a charge pump according to another embodiment of the present invention.

Referring to FIG. 5 , the charge pump phase correction circuit 360 according to another embodiment of the present invention includes a Time Amplifier (TA) 363, a Phase Detector (PD) 364, and a Counter , 365).

The time amplifier 363 detects the difference between the pull-up signal (UP) and the pull-down signal (DN), which are the output signals of the phase frequency detector 310, amplifies the difference, and then generates the amplified pull-up signal (TA_UP) and the amplified pull-down signal (TA_DN). ) is output.

The phase detector 364 receives the amplified pull-up signal TA_UP and the amplified pull-down signal TA_DN output from the time amplifier 363, detects a difference therebetween, and outputs a phase difference detection signal PD_OUT.

The phase difference detection signal PD_OUT outputs '1' when the phase of the amplified pull-up signal TA_UP is ahead of the amplified pull-down signal TA_DN, and the amplified pull-up signal TA_UP corresponds to the amplified pull-down signal TA_DN. If the phase lags behind, '0' is output.

When the output of the phase difference detection signal PD_OUT is '1', it means that the charge current of the charge pump 320 is less than the discharge current. Therefore, when the output of the phase difference detection signal PD_OUT is '1', the charging current control signal S _charge is output using the counter 365 so that more charging current I _charge flows.

Conversely, when the output of the phase difference detection signal PD_OUT is '0', it means that the charging current of the charge pump 320 is flowing more than the discharging current. Therefore, when the output of the phase difference detection signal PD_OUT is '0', the discharge current control signal S _discharge is output using the counter 365 so that more discharge current I _discharge flows.

In the present invention, the charge current control signal (S _charge ) is a 5-bit charge control signal (Charge[4:0]), and the discharge current control signal (S _discharge ) is a 5-bit discharge control signal (Discharge[4:0]). 0]) will be described as an example. However, the charging current control signal S _charge and the discharge current control signal S _discharge are not limited thereto.

FIG. 6 is a circuit diagram of a time amplifier of the phase correction circuit of the charge pump according to FIG. 5 .

As shown in FIG. 6, the time amplifier 363 of the phase correction circuit of the charge pump according to the present invention receives a first input signal, a pull-up signal (UP) and a second input signal, a pull-down signal (DN), and generates a first An amplified pull-up signal TA_UP as an output signal and an amplified pull-down signal TA_DN as a second output signal are output.

At this time, the time amplifier 363 receives the pull-up signal (UP) and the pull-down signal (DN) and uses a normal discharging path and a dependent discharging path to generate the pull-up signal (UP) and the pull-down signal (DN). The difference of the pull-down signal (DN) is amplified and output.

The main discharge path includes a first main discharge path 363a that turns on when '1' is input to the pull-up signal UP to discharge the first intermediate node (node A) to ground voltage and the pull-down signal DN. ) includes a second main discharge path 363d that turns on when '1' is input and discharges the second intermediate node (node B) to ground voltage.

The auxiliary discharge path is turned on when '1' is input to the pull-up signal (UP) and '0' is input to the pull-down signal (DN) to discharge the first intermediate node (node A) to ground voltage. When '0' is input to the first auxiliary discharge path 363b and the pull-up signal UP, and '1' is input to the pull-down signal DN, the second intermediate node (node B) is turned on and the ground voltage is applied. and a second auxiliary discharge path 363c for discharging to .

That is, the time amplifier 363 amplifies the difference between the two input signals using the first and second auxiliary discharge paths 363b and 363c.

Meanwhile, the time amplifier 363 may further include a first inverter 363e and a second inverter 363f.

The first inverter 363e inverts and outputs the signal of the first intermediate node (node A), and the second inverter 363f inverts and outputs the signal of the second intermediate node (node B).

FIG. 7 is a diagram for explaining the operation of the time amplifier shown in FIG. 6;

7(a) is a diagram showing a path when both the pull-up signal UP as the first input signal and the pull-down signal DN as the second input signal are '0'. As shown in (a) of FIG. 7 , when '0' is input to both the first input signal UP and the second input signal DN, the first PMOS transistor MP1 and the second PMOS transistor The first intermediate node (node A) and the second intermediate node (node B) are charged with the supply voltage VDD through MP2, and the amplified pull-up signal TA_UP as the first output signal and the amplified second output signal are All of the pull-down signals TA_DN output '0'.

7(b) is a diagram illustrating a path when the first input signal UP changes to '1' and the second input signal DN maintains '0'. In this case, the first intermediate node (node A) is rapidly discharged to the ground voltage (VSS) by the first main discharge path 361a and the first auxiliary discharge path 361b, and the second intermediate node (node B) supplies Since the voltage VDD is maintained, the first output signal TA_UP outputs '1' and the second output signal TA_DN outputs '0'.

7(c) is a diagram illustrating a path when the first input signal UP maintains '0' and the second input signal DN changes to '1'. In this case, the first intermediate node (node A) maintains the supply voltage (VDD), and the second intermediate node (node B) is grounded by the second main discharge path 363d and the second auxiliary discharge path 363c. Since it is quickly discharged to (VSS), the first output signal TA_UP outputs '0' and the second output signal TA_DN outputs '1'.

7(d) is a diagram illustrating a path when both the first input signal UP and the second input signal DN are '1'. Unlike FIGS. 6(b) and 6(c), in (d) of FIG. 6, the first auxiliary discharge path 363b and the second auxiliary discharge path 363c are blocked and do not operate, and the first main discharge path Discharge proceeds only through 363a and the second main discharge path 363d. As a result, both the first output signal TA_UP and the second output signal TA_DN output '1'.

For example, when the W/L ratio of the main discharge paths 363a and 363d and the auxiliary discharge paths 363b and 363c are the same, if it takes a first time T to discharge in the first transition process In the second transition process, a second time period (2T) is taken, so that the phase difference between the two inputs is doubled.

FIG. 8 is a circuit diagram of a phase detector of the phase correction circuit of the charge pump according to FIG. 5 .

As shown in FIG. 8, the phase detector 364 of the phase correction circuit of the charge pump according to the present invention detects the amplified pull-up signal TA_UP as the first input signal and the amplified pull-down signal TA_DN as the second input signal. It receives the two input signals and outputs a first output signal Q, which is a phase difference detection signal PD_OUT, and a second output signal QB having a phase opposite to the first output signal Q.

When the phase of the amplified pull-up signal TA_UP, which is the first input signal, is ahead of the amplified pull-down signal TA_DN, which is the second input signal, the S node becomes '1' and the R node becomes '0' to detect the phase difference. The first output signal Q, which is the signal PD_OUT, outputs '1' and the second output signal QB outputs '0'.

Conversely, when the phase of the amplified pull-up signal TA_UP, which is the first input signal, lags behind the phase of the amplified pull-down signal TA_DN, which is the second input signal, the S node becomes '0' and the R node becomes '1'. Thus, the first output signal Q, which is the phase difference detection signal PD_OUT, outputs '0' and the second output signal QB outputs '1'.

As such, the phase detector 364 compares the amplified pull-up signal TA_UP and the amplified pull-down signal TA_DN by using a function of detecting a phase difference between the two inputs to determine the charge current I _charge of the charge pump 320. It determines whether to increase or increase the discharge current (I _discharge ).

When '1' is output as the phase difference detection signal PD_OUT, the counter 365 outputs the charge control signal S _charge to increase the charging current of the charge pump, and outputs '1' as the phase difference detection signal PD_OUT. When 0' is output, the discharge control signal S _discharge is output to increase the discharge current of the charge pump.

9 is a circuit diagram of a charge pump for phase correction according to the present invention.

As shown in (a) of FIG. 9, the charge pump circuit for phase correction according to the present invention is designed to adjust the current of the charge pump with a 5-bit control signal, and the charge current (I _charge ) through the correction operation and discharge current (I _discharge ) can be independently controlled.

9(b) shows a charging current source. The charging current source was able to control the charging current (I _charge ) from 1% to a maximum of 15% with a charge[4:0] signal, which is a 5-bit charging control signal.

9(c) shows a discharge current source. As with the charging current source, the discharge current source can control the discharge current (I _discharge ) from 1% to a maximum of 15% with a discharge[4:0] signal, which is a 5-bit discharge control signal.

10 is a timing diagram illustrating an embodiment of a correction operation of a phase correction circuit of a charge pump according to an embodiment of the present invention. FIG. 10 shows a timing diagram for a correction operation when the charge current (I _charge ) of the charge pump is smaller than the discharge current (I _discharge ).

The time amplifier amplifies the pull-up signal (UP) and the pull-down signal (DN) and outputs the amplified pull-up signal (TA_UP) and the amplified pull-down signal (TA_DN). The phase detector receives the amplified pull-up signal TA_UP and the amplified pull-down signal TA_DN, detects a difference therebetween, and outputs a phase difference detection signal PD_OUT. At this time, when the phase of the amplified pull-up signal TA_UP is ahead of the amplified pull-down signal TA_DN, the phase difference detection signal PD_OUT outputs '1', and outputs '0' in the opposite case. After starting the correction, when '1' is stored in the first phase difference detection signal (PD_OUT) value, the charging current (I _charge ) is increased, and when '0' is stored, the discharge current (I _discharge ) is increased.

Referring to FIG. 10, since '1' is stored as the first phase difference detection signal (PD_OUT) value, the charging current control signal (S _charge ), which is a signal for controlling the charging current (I _charge ) by the counter, is output so that the charging current (I charge ) is output. _charge ) increases.

As the charge current (I _charge ) continues to increase, the charge current (I _charge ) becomes greater than the discharge current (I _discharge ) at some point, and accordingly, if the phase difference detection signal (PD_OUT) value is output in reverse, the counter subtracts from the addition operation By switching the mode to operation, the charging current (I _charge ) is reduced.

Thereafter, the charge current (I _charge ) is repeatedly increased and decreased than the discharge current (I _discharge ), and the correction operation is forcibly terminated by the correction end signal (CAL_END) after 32 cycles.

As described above, according to the phase-correction circuit of the charge pump according to the present invention, the output characteristic of the phase-locked loop can be improved by minimizing the mismatch of the current generated by the charge pump in the phase-locked loop.

Claims (12)

In the phase correction circuit of the charge pump in the phase locked loop,
a phase detector receiving the pull-up signal (UP) and the pull-down signal (DN), which are output signals of the phase frequency detector, detecting a phase difference, and outputting a phase difference detection signal (PD_OUT); and
and a counter that receives the phase difference detection signal (PD_OUT) and outputs a charge control signal (S _charge ) or a discharge control signal (S _discharge ). In the phase correction circuit of the charge pump in the phase locked loop,
a time amplifier that receives the pull-up signal (UP) and the pull-down signal (DN), which are output signals of the phase frequency detector, and amplifies them to output an amplified pull-up signal (TA_UP) and an amplified pull-down signal (TA_DN);
a phase detector detecting a phase difference between the amplified pull-up signal TA_UP and the amplified pull-down signal TA_DN and outputting a phase difference detection signal PD_OUT; and
and a counter that receives the phase difference detection signal (PD_OUT) and outputs a charge control signal (S _charge ) or a discharge control signal (S _discharge ). The method of claim 2, wherein the time amplifier
By receiving the pull-up signal (UP) and the pull-down signal (DN), the difference between the pull-up signal (UP) and the pull-down signal (DN) is amplified by using the main discharge path and the auxiliary discharge path, thereby generating the amplified pull-up signal (TA_UP). and outputting the amplified pull-down signal TA_DN. 4. The method of claim 3, wherein the main discharge path is
a first main discharge path that is turned on when '1' is input to the pull-up signal (UP) and discharges the first intermediate node (A) to a ground voltage; and
and a second main discharge path that turns on when '1' is input to the pull-down signal (DN) and discharges the second intermediate node (B) to ground voltage. 4. The method of claim 3, wherein the auxiliary discharge path
a first auxiliary discharge path that is turned on when '1' is input to the pull-up signal (UP) and '0' is input to the pull-down signal (DN) to discharge the first intermediate node (A) to ground voltage; and
A second auxiliary discharge path that is turned on when '0' is input to the pull-up signal (UP) and '1' is input to the pull-down signal (DN) to discharge the second intermediate node (B) to ground voltage. A phase correction circuit of a charge pump comprising: The method of claim 4 or 5, wherein the time amplifier
a first inverter inverting and outputting a signal of the first intermediate node (node A); and
and a second inverter for inverting and outputting a signal of the second intermediate node (node B). The method of claim 1, wherein the phase detector
When the phase of the pull-up signal UP is ahead of the phase of the pull-down signal DN, '1' is output as the phase difference detection signal PD_OUT, and the phase of the pull-down signal DN corresponds to that of the pull-up signal UP. The phase correction circuit of the charge pump, characterized in that for outputting '0' as the phase difference detection signal (PD_OUT) when it is ahead of the phase of . The method of claim 2, wherein the phase detector
When the phase of the amplified pull-down signal TA_UP is ahead of the phase of the amplified pull-down signal TA_DN, '1' is output as the phase difference detection signal PD_OUT, and the phase of the amplified pull-down signal TA_DN is and outputting '0' to the phase difference detection signal PD_OUT when the phase of the amplified pull-up signal TA_UP is ahead of the phase correction circuit of the charge pump. The method of claim 7 or 8, wherein the counter
and when '1' is output as the phase difference detection signal, the charge control signal (S _charge ) is output to increase the charging current of the charge pump. The method of claim 7 or 8, wherein the counter
and increasing the discharge current of the charge pump by outputting the discharge control signal (S _discharge ) when '0' is output as the phase difference detection signal. According to claim 7 or 8,
The charge pump phase correction circuit, characterized in that each of the charge control signal (S _charge ) and the discharge control signal (S _discharge ) are 5-bit control signals. According to claim 11,
phase correction of the charge pump, characterized in that the charging current and the discharging current can be controlled within a range of 1% to 15%, respectively, using the charge control signal (S _charge ) and the discharge control signal (S _discharge ). Circuit.

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