DE102006051284B4 - Duty cycle correction circuit, integrated circuit, phase locked loop circuit, delay locked loop circuit, memory device and method for generating a clock signal - Google Patents

Abstract

A duty cycle correction circuit (620) configurable for use in a clock generation circuit (610), comprising:
A first amplifier circuit (625a) adapted to receive a first pair of differential intermediate clock signals (CLK1, CLKB1) and to output a first pair of internal clock signals (CCLK1, CCLKB1),
A second amplifier circuit (625b) adapted to receive a second pair of differential intermediate clock signals (CLK2, CLKB2) and to output a second pair of internal clock signals (CCLK2, CCLKB2), and
A charge pump (630) for receiving the first and second pairs of internal clock signals (CCLK1, CCLKB1, CCLK2, CCLKB2) and outputting a control signal (VC, VCB) based on the first and second pairs of internal clock signals (FIG. CCLK1, CCLKB1, CCLK2, CCLKB2), wherein
The first amplifier circuit (625a) sets a duty cycle of the first pair of differential intermediate clock signals (CLK1, CLKB1) in response to the control signal (VC, VCB) and the second amplifier circuit (625b) sets a duty cycle of ...

Description

The present invention relates to a duty cycle correction circuit, an integrated circuit, a phase locked loop circuit, a delay lock loop circuit, a memory device, and a method of generating a clock signal.

Semiconductor devices having clock generating circuits often include phase locked loop (PLL) circuits or delay locked loop (DLL) circuits. A conventional PLL includes a voltage controlled oscillator (VCO) that generates internal clock signals at relatively high frequencies, and a duty cycle correction circuit (DCC) that includes at least a pair of amplifier means and a corresponding charge pump. On the other hand, a conventional DLL comprises a voltage-controlled delay line (VCDL) and a DCC, which analogously has at least one pair of amplifier means and a corresponding charge pump.

With reference to 1 includes a conventional PLL circuit 100 a phase detector (PD) 110 , a charge pump (CP) 120 , a loop filter (LP) 130 , a voltage controlled oscillator (VCO) 140 , a divider (DIV) 160 and a duty cycle correction circuit (DCC) 150 ,

During operation, the PD generates 110 In response to a phase difference between an external clock signal (INS) and a feedback clock signal (FEEDS), a control signal and the control signal, the CP 120 to disposal. The control signal comprises a signal UP and a signal DN (not shown). When the phase of the signal INS precedes the phase of the feedback clock signal, the PD is 110 activates and generates an activated signal UP. Otherwise, the PD generates 110 an activated signal DN when the phase of the signal INS lags the phase of the signal FEEDS. The CP 120 and the LP 130 increase the level of the control voltage (VC) in response to the activated signal UP, and reduce the level of the control voltage VC in response to the activated signal DN. The control voltage is in the VCO 140 entered.

The VCO 140 generates two intermediate clock signals CLK and CLKB which are from the DCC 150 be received. The phase difference between CLK and CLKB is approximately 180 degrees. The DCC removes a duty cycle error that may exist in each of the intermediate clock signals CLK and CLKB, and generates first internal clock signals CCLKB and CCLK that maintain a normal duty cycle of 50%: 50%. The phase difference between CCLKB and CCLK is also about 180 degrees.

The DIV 160 receives one of the first internal clock signals, which in the example according to 1 the signal CCLK, and then outputs the divided clock signal FEEDS whose frequency corresponds to the frequency of the signal INS. That is, for detecting the first internal clock signals CCLKB and CCLK having a higher frequency than the external clock signal INS, the DIV 160 is provided in the PLL. On the other hand, if a PLL does not have a divisor like the DIV 160 , the frequency of the first internal clock signals CCLKB, CCLK the frequency of the external clock signal INS.

With reference to 2 includes a conventional DLL circuit 200 a VCDL 240 instead of a VCO 140 of the PLL 100 as well as a phase detector (PD) 210 , a charge pump (CP) 220 , a loop filter (LP) 230 and a duty cycle correction (DCC) circuit 250 ,

During operation, the VCDL generates 240 Intermediate clock signals CLKB and CLK which are delayed by a predetermined time from an external clock signal INS in response to an output signal of the charge pump CP 220 and the LP 230 , which is generally implemented as a low-pass filter. Then the DCC generates 250 first internal clock signals CCLKB, CCLK capable of holding normal duty cycles after the removal of duty cycle errors that may be included in each of the intermediate clock signals CLKB, CLK.

With reference to 3 is below a conventional DCC circuit 150 . 250 described in more detail. The DCC 150 . 250 can, as in 3 shown receiving differential clock signals CLK and CLKB having a phase difference of approximately 180 degrees, which will be described below with reference to FIGS 4 and may also receive a single-ended clock signal, which will be described below with reference to FIG 5 is described. In the case of differential clock signals, the duty cycle errors of the intermediate clock signals CLK, CLKB are corrected in response to control signals VC and VCB received from a charge pump CP 320 of the DCC circuit can be generated. The CP 320 adjusts the voltage values of the control signals VC, VCB in response to the signals CCLK, CCLKB such that an amplifier part or amplifier means (AP) 310 Adjust the duty ratios of the signals CLK, CLKB according to the voltage values of the signals VC, VCB to output the first internal clock signals CCLK, CCLKB holding normal duty ratios of 50%: 50%.

With reference to 12a If the intermediate clock signals CLK / CLKB have no duty cycle errors, first internal clock signals CCLK / CCLKB have no duty cycle errors. Therefore, the average voltage of the control signal VC remains constant for one clock period every interval for all clock periods.

With reference to 13a If the intermediate clock signals CLK / CLKB have a duty cycle error, first internal clock signals CCLK / CCLKB also have a duty cycle error. The CP works accordingly 320 of the DCC circuit 150 . 250 to adjust the voltage level of the control signal VC to the amplifier means AP 310 to control the duty cycle error correction of the clock signals. As shown, the average voltage value of the control signal VC differs per clock period between each interval until the signals CCLK / CCLKB are restored to a normal duty ratio by the operation of the DCC circuit.

With reference to 4 gives the VCO 410 two pairs of differential clock signals CLK1 / CLKB1 and CLK2 / CLKB2 off. In this case, the DCC 400 two charge pumps (CP) 430a . 430b in a one-to-one relationship with repeater (AP) 425a . 425b are arranged, as from the blocks 420a and 420b to correct the duty cycle errors of the two pairs of differential clock signals. While 4 a connection between the VCO 410 and the DCC 400 in a PLL circuit, it will be understood that a similar arrangement between a VCDL and a DCC may exist in a DLL circuit, with a VCDL in place of the VCO 410 is used.

With reference to 5 gives the VCO 510 four single ended clock signals CLK1, CLK2, CLK3, CLK4 off. In this case, the DCC 500 four charge pumps (CP) 530a . 530b . 530c . 530d in a one-to-one relationship with repeater (AP) 425a . 425b . 425c . 425d are arranged, as from the blocks 520a . 520b . 520c and 520d can be seen to correct the duty cycles of the four unbalanced clock signals. The duty cycle errors of the intermediate clock signals CLK1, CLK2, CLK3, CLK4 are corrected in response to the control signals VC1, VC2, VC3, VC4, each from CPs 530a . 530b . 530c . 530d which adjust the voltage values of the control signals VC1, VC2, VC3, VC4 in response to the signals CCLK1, CCLK2, CCLK3, CCLK4, so that the amplifier means AP 425a . 425b . 425c . 425d respectively set the duty ratios of the signals CLK1, CLK2, CLK3, CLK4 according to the voltage values of the voltages VC1, VC2, VC3, VC4 to output the first internal clock signals CCLK1, CCLK2, CCLK3, CCLK4 with corrected duty ratios.

As in the case according to 4 It will be understood that a corresponding arrangement between a VCDL and a DCC may exist in a DLL circuit, with a VCDL instead of the VCO 510 is used while 5 a connection between the VCO 510 and the DCC 500 in a PLL circuit shows.

As is apparent from the foregoing description, in conventional clock generating circuits, a duty cycle correction charge pump is disposed in association with each amplifier means which receives the intermediate clock signals and generates first internal clock signals. The number of charge pumps required in the duty cycle correction circuits of conventional semiconductor devices results in high power consumption and requires a large chip area.

The WO 01/01266 A1 shows a digital delay locked loop in which a duty cycle of an output signal to a duty cycle of an input signal is adjusted.

The US 5,572,158 shows a circuit that actively corrects a duty cycle of a periodic signal, such as a clock signal.

The US 2004/0189364 A1 shows an IC with a duty cycle correction circuit.

The US 2003/0111705 A1 shows a phase splitter with duty cycle correction function.

The US 6,833,743 B2 shows circuits for adjusting the duty cycle of a clock signal.

The invention has for its object to provide a duty cycle correction circuit, an integrated circuit, a phase locked loop circuit, a delay locked loop circuit, a memory device and a method for generating a clock signal, resulting in a reduced chip area and reduced power consumption.

The invention solves this problem by providing a duty cycle correction circuit having the features of claim 1 or 21, an integrated circuit having the features of claim 14, a phase-locked loop circuit having the features of claim 15, a delay locked loop circuit having the features of claim 17, a memory device with the Features of claim 19 and a method of generating a clock signal having the features of claim 28.

Advantageous developments of the invention are specified in the subclaims, the wording of which is hereby incorporated by reference into the description in order to avoid unnecessary test repetitions.

One aspect of the present invention is directed at least to the above-mentioned problems and / or disadvantages and at least to the provision of the advantages described below. Accordingly, one aspect of the present invention is to implement at least lower power consumption and chip size reduction in a semiconductor device, such as a memory device, using clock generation circuitry.

Certain embodiments of the present invention provide a clock generating circuit and method for generating a clock signal, wherein a DCC comprises a plurality of amplifier means generating first internal clock signals and at least one divided charge pump which determines the voltage level of a control signal VC in response to the first set internal clock signals and provides the control signal VC the amplifier means available.

In accordance with another embodiment of the present invention, a duty cycle correction circuit is configurable for use in a clock generation circuit and includes a first amplifier circuit configured to receive a first single ended intermediate clock signal and output a first internal clock signal, a second amplifier circuit to receive a second single ended intermediate clock signal and configured to output a second internal clock signal, and a second charge pump configured to receive the first and second internal clock signals and to output a second control signal based on the first and second internal clock signals. The first and second amplifier circuits set duty ratios of the first and second single ended intermediate clock signals, respectively.

According to another embodiment of the present invention, a method of generating a clock signal includes generating first and second pairs of differential intermediate clock signals, inputting the first pair of differential intermediate clock signals into a first amplifier circuit to generate a first pair of internal clock signals, inputting of the second pair of differential intermediate clock signals into a second amplifier circuit to produce a second pair of internal clock signals, inputting the first and second pairs of internal clock signals into a second charge pump to generate a second control signal based on the first and second pairs of generating internal clock signals, and inputting the second control signal to at least one of the first and second amplifier circuits to adjust duty cycles of the first and second pairs of differential intermediate clock signals, respectively.

According to another embodiment of the present invention, a method of generating a clock signal comprises generating first and second single ended intermediate clock signals, inputting the first single ended intermediate clock signal to a first amplifier circuit to generate a first internal clock signal, inputting the second single ended intermediate clock signal a second amplifier circuit for generating a second internal clock signal, inputting the first and second internal clock signals into a second charge pump to generate a second control signal based on the first and second internal clock signals, and inputting the second control signal in at least one of the second control signals one of the first and second amplifier circuits to adjust duty cycles of the first and second single-ended intermediate clock signals, respectively.

In accordance with another embodiment of the present invention, a charge pump includes a first input configured to receive a first internal clock signal from a first amplifier circuit, a second input configured to receive a second internal clock signal from a second amplifier circuit, and an output. which is adapted to transmit a control signal to at least one of the first and second amplifier circuits. The control signal is based on the first and second internal clock signals.

According to another embodiment of the present invention, a method for correcting a duty cycle error in a clock generating circuit comprises outputting a first internal clock signal from a first amplifier circuit to a charge pump, outputting a second internal clock signal from a second amplifier circuit to the charge pump, generating a control signal on the first and second internal clock signals, and transmitting the control signal from the charge pump to at least one of the first and second amplifier circuits.

Advantageous, described below embodiments of the invention and the above for their better understanding, forth Conventional embodiments are shown in the drawings.

Show it:

1 FIG. 4 is a block diagram showing a configuration of a conventional phase locked loop (PLL) circuit. FIG.

2 10 is a block diagram showing a configuration of a conventional delay locked loop (DLL) circuit;

3 a block diagram showing a configuration of a conventional duty cycle correction (DCC) circuit, the PLL in accordance with 1 or in the DLL according to 2 can be arranged

4 a block diagram showing the interconnection of a conventional DCC circuit processing differential clock signals,

5 a block diagram showing the interconnection of a conventional DCC circuit that processes unbalanced clock signals,

6 FIG. 3 is a block diagram illustrating an exemplary embodiment of a clock generation circuit according to the present invention. FIG.

7 1 is a circuit diagram illustrating an exemplary embodiment of a charge pump according to the invention;

8th 5 is a circuit diagram illustrating an exemplary embodiment of an amplifier device according to the invention;

9 1 is a circuit diagram to illustrate another exemplary embodiment of a charge pump according to the invention,

10 FIG. 4 is a block diagram showing another exemplary embodiment of a clock generating circuit according to the present invention. FIG.

11A FIG. 3 is a circuit diagram illustrating another exemplary embodiment of an amplifier device according to the invention, FIG.

11B 1 is a circuit diagram to illustrate another exemplary embodiment of a charge pump according to the invention,

12A FIG. 4 is a timing chart showing a normal duty ratio of a first internal clock signal in a conventional clock generating circuit. FIG.

12B FIG. 4 is a timing chart illustrating a normal duty ratio of a first internal clock signal in a clock generating circuit according to an exemplary embodiment of the present invention. FIG.

13A FIG. 3 is a timing chart showing an abnormal duty ratio of a first internal clock signal in a conventional clock generating circuit. FIG.

13B FIG. 4 is a timing chart showing an abnormal duty ratio of a first internal clock signal in a clock generating circuit according to an exemplary embodiment of the present invention. FIG.

14 FIG. 2 is a block diagram illustrating another exemplary embodiment of a PLL circuit according to the invention. FIG.

15 a block diagram illustrating another exemplary embodiment of a DLL circuit according to the invention and

16 a block diagram illustrating another exemplary embodiment of a memory device according to the invention.

With reference to 6 includes a semiconductor device 600 according to an embodiment of the present invention, a clock generating circuit 610 and a duty cycle correction circuit DCC 620 , In an exemplary embodiment, a PLL may be present, in which case the clock generation circuit 610 as a VCO can be implemented. In another exemplary embodiment, a DLL may be present, in which case the clock generation circuit 610 as VCDL can be implemented.

How out 6 is apparent, is the DCC circuit 620 according to an embodiment of the present invention by means of a shared charge pump CP 630 implemented, rather than independent charge pumps as in the example in 4 to compensate for duty cycles to the differential intermediate clock signals CLK1 / CLKB1, CLK2 / CLKB2. Accordingly, the chip area and the power consumption caused by the charge pump in the DCC can be reduced as compared with the conventional arrangement. The divided charge pump CP of the DCC circuit controls the voltage values VC / VCB in response to the duty cycle average value of the signals CCLK1 / CCLKB1 and CCLK2 / CCLKB2. The of the shared CP to the amplifier means AP 625a output signals VC / VCBs can connect to the amplifier means AP 625b output signals VC / VCB or different.

With reference to 7 includes an exemplary embodiment of the shared CP according to the invention 630 output means 710 and an input driver 720 , The output means 710 comprise a first current source IS1, a second current source IS2 and a capacitive element C, which, as in 7 shown connected to the nodes NO and NOB. In this case, the capacitive element C operates as a low-pass filter. The input driver 720 comprises a drive current source ISD which is connected at a node NC to transistors ITR1 and ITR2 and transistors ITRB1 and ITRB2, wherein a respective transistor ITR1 and ITR2 receives one of the input signals CCLK1 and CCLK2 and a respective transistor ITRB1 and ITRB2 receives one of the input signals CCLKB1 and respectively CCLKB2 receives.

With reference to 9 includes another exemplary embodiment of the shared CP according to the invention 630 output means 910 and an input driver 920 , In contrast to the arrangement according to 7 here is the input driver 920 two drive power sources on. A first drive current source ISD1 is connected at a node NC1 to transistors ITR1 and ITRB1, while a second drive current source ISD2 is connected at a node NC2 to transistors ITR2 and ITRB2.

With reference to 8th In one exemplary embodiment of the present invention, AP 625a and or 625b load means 810 and control means 820 that are configured as shown. That is, intermediate clock signals CLK1 / CLKB1 are received at the transistor ATR2 / ATR1, which are connected at a node NCA1 to a first drive current source ISD1. On the other hand, signals VC / VCB output from the split CP are received at transistors ATR4 / ATR3 which are connected at a node NCA2 to a second drive current source ISD2. The signals CCLK1 / CCLKB1 are output to node NAOB / NOA.

With reference to 12B and 13B A method of generating a control signal according to an embodiment of the invention will now be described.

How out 12B As can be seen, first internal clock signals CCLK1 / CCLKB1 and CCLK2 / CCLKB2 have no duty cycle errors when intermediate clock signals CLK1 / CLKB1 and CLK2 / CLKB2 have no duty cycle errors.

In an interval A off 12B Both a clock signal CCLK1, which refers to the node NO, and a clock signal CCLKB2, which refers to the node NOB, are at a high level. Therefore, the voltage drop at the node NO is the same as at the node NOB. Accordingly, the voltage level VC remains constant.

In an interval B off 12B For example, only the two clock signals CCLK1 and CCLK2 relating to the node NO are at a high level, so that an additional voltage drop occurs at the node NO due to an additionally activated transistor ITR2, while the voltage at the node NOB rises, since all at the node NOB arranged transistors are turned off. Therefore, the voltage level VC decreases as shown.

In an interval C off 12B For example, both the clock signal CCLK2 related to the node NO and the clock signal CCLKB1 relating to the node NOB are at a high level. Therefore, the voltage drop at the node NO is the same as at the node NOB. Accordingly, the voltage level VC remains constant.

In an interval D off 12B For example, only the two clock signals CCLKB1 and CCLKB2 related to the node NOB are at a high level, so that an additional voltage drop occurs at the node NOB due to an additionally activated transistor ITRB2 while the voltage at the node NO increases, since all the transistors are off are switched. Therefore, the voltage level VC increases as shown.

As in 12B is shown, the average voltage level VC is the same from one interval to the next, since no duty cycle error is present in the intermediate clock signals. As a result, the DCC does not need to match the duty cycle error. How out 12B 4, a ripple of the control voltage signal VC according to an exemplary embodiment of the invention decreases as compared with the control voltage signal VC of the conventional DCC 12A also off.

How out 13B As can be seen, the first internal clock signals CCLK1 / CCLKB1 and CCLK2 / CCLKB2 also have a duty cycle error when the intermediate clock signals CLK1 / CLKB1 and CLK2 / CLKB2 have a duty cycle error.

In an interval A off 13B For example, both the clock signal CCLK1 related to the node NO and the clock signal CCLKB2 related to the node NOB are at a high level. Therefore, the voltage drop at node NO the same as at node NOB. Accordingly, the voltage level VC remains constant.

In an interval B off 13B For example, only the two clock signals CCLK1 and CCLK2 relating to the node NO are at a high level, so that an additional voltage drop occurs at the node NO due to an additionally activated transistor ITR2, while the voltage at the node NOB rises, since all at the node NOB arranged transistors are turned off. Therefore, the voltage level VC decreases as shown.

In an interval C off 13B For example, both the clock signal CCLK2 related to the node NO and the clock signal CCLKB1 relating to the node NOB are at a high level. Therefore, the voltage drop at the node NO is the same as at the node NOB. Accordingly, the voltage level VC remains constant.

In an interval D off 13B For example, only the two clock signals CCLKB1 and CCLKB2 related to the node NOB are at a high level, so that an additional voltage drop occurs at the node NOB due to an additionally activated transistor ITRB2 while the voltage at the node NO increases, since all the transistors are off are switched. Therefore, the voltage level VC increases as shown. In an exemplary embodiment, the voltage VC increases over a long period of time in the interval D, while decreasing in the interval B over a short period of time.

As in 13B is shown, the average voltage level VC is not the same from one interval to the next since a duty cycle error is present in the intermediate clock signal. This means in the example according to 13B in that the average value of the voltage VC increases slightly from one clock period to the next until substantially eliminating the duty cycle error existing in the intermediate clock signal.

During the duty cycle error correction according to an embodiment of the present invention, the average voltage VC increases stepwise to extend the high interval of the signal CCLK until the high interval of the signal CCLK finally becomes identical with the low interval and the low respectively Duration of the signal is CCLK.

With reference to 10 includes a semiconductor device 1000 According to another embodiment of the present invention, a clock generating circuit 1010 , In an exemplary embodiment, a PLL may be present, in which case the clock generation circuit 1010 as a VCO can be implemented. In another exemplary embodiment, a DLL may be present, in which case the clock generation circuit 1010 can be implemented as VCDL.

How out 10 is apparent, is a DCC circuit 1020 according to another embodiment of the present invention by means of a shared charge pump CP 1030 realized, for example, as in the in 5 to use conventional charge pump to compensate for duty cycles in the unbalanced intermediate clock signals CLK1, CLK2, CLK3, CLK4. Accordingly, the chip area and the power consumption caused by the charge pump in the DCC can be reduced as compared with the conventional arrangement. The divided CP of the DCC circuit controls the voltage values of the signal VC in response to the duty cycle average value of the signals CCLK1, CCLK2, CCLK3 and CCLK4. The signal VC is sent from the shared CP to the AP 1025a . 1025b . 1025C and 1025d output.

With reference to 11A In an exemplary embodiment of the present invention, the amplifier means AP 1025a , or one or all of the other amplifying means AP 1025b . 1025C and or 1025d , Transistors SATR2 / SATR3, which receive the unbalanced intermediate clock signal CLK1 and output the first internal clock signal CCLK1. The transistors SATR2 / SATR3 are driven by transistors SATR1 / SATR4, which receive the control signal VC output from the shared CP.

With reference to 11B includes the shared CP 1030 in an exemplary embodiment of the present invention, output means 110 and an input driver having four pairs of transistors PTR1 / NTR1, PTR2 / NTR2, PTR3 / NTR3 and PTR4 / NTR4 connected at a common node N1 to a first current source IS1 and at a common node N2 to a second current source IS2 , The transistor pairs PTR1 / NTR1, PTR2 / NTR2, PTR3 / NTR3 and PTR4 / NTR4 are configured to receive the signals CCLK1, CCLK2, CCLK3, CCLK4 and generate a common output signal at a node NOS. The output means 110 include an amplifier 1115 , The amplifier 1115 is configured to receive a reference voltage VREF and the output signal at the node NOS at its inputs and to output the control voltage signal VC.

During operation, a duty cycle error of the signal CLK1 may be adjusted in response to the voltage value of the control voltage signal VC to output the first internal clock signal CCLK1 maintaining a normal duty cycle of 50%: 50%. For example, when the high interval of the signal CLK1 is longer than the low interval of the signal CLK1, the voltage value of the signal VC is relatively high, as in the circuit diagram of the exemplary pump circuit 1030 according to 11B can be seen, whereby the driving capabilities of the transistor SATR4 are much larger than that of the transistor SATR1. Therefore, the high interval of the signal CCLK1 is shorter than in a previous step, while the low interval of the signal CCLK1 is longer than in a previous step.

With reference to 14 Another exemplary embodiment of the present invention provides a PLL circuit 1400 available in which a duty cycle correction circuit (DCC circuit) 1450 is provided, the AP 1455a . 1455b and a shared second CP 1460 includes, as in 6 to 9 can be shown represented. In the in 14 illustrated embodiment includes the PLL circuit 1400 a phase detector (PD) 1410 , a first charge pump (CP) 1420 , a loop filter (LP) 1430 , a voltage controlled oscillator (VCO) 1440 , a divider (DIV) 1470 and the DCC circuit 1450 , The VCO 1440 outputs two pairs of differential intermediate clock signals CLK1 / CLKB1 and CLK2 / CLKB2 to the DCC circuit 1450 out.

In another exemplary embodiment, the VCO 1450 be designed to output a plurality of unbalanced clock signals, in which case the DCC circuit 1450 is designed accordingly, see for example 10 . 11A and 11B , In another exemplary embodiment of the PLL 1400 For example, an external clock signal INS may be latched to one of the first internal clock signals, such as signal CCLK2.

With reference to 15 Another exemplary embodiment of the present invention provides a DLL circuit 1500 available in which a duty cycle correction circuit (DCC circuit) 1550 is provided, the AP 1555a . 1555b and a shared second CP 1560 includes, as in 6 to 9 can be shown represented. In the in 15 illustrated embodiment includes the DLL circuit 1500 a phase detector (PD) 1510 , a first charge pump (CP) 1520 , a loop filter (LP) 1530 , a voltage-controlled delay line (VCDL) 1540 and the DCC circuit 1550 , The VCDL 1540 Gives two pairs of differential clock signals CLK1 / CLKB1 and CLK2 / CLKB2 to the DCC circuit 1550 out. The DLL 1500 includes a VCDL 1540 instead of the VCO 1440 of in 14 represented PLL 1400 which delays an external clock signal by a predetermined period of time and a plurality of intermediate clock signals having a constant phase difference, e.g. B. 90 degrees phase difference, outputs between the adjacent clock signals.

In another exemplary embodiment, the VCDL 1550 be designed to output a plurality of unbalanced clock signals, in which case the DCC circuit 1550 is designed accordingly, see for example 10 . 11A and 11B , In another exemplary embodiment of the DLL 1500 For example, an external clock signal INS may be latched to one of the first internal clock signals, such as signal CCLK2.

With reference to 16 Another exemplary embodiment of the present invention provides a memory device 1600 available, the input / output means 1610 , a memory cell array 1620 , an address decoder 1630 , a command decoder 1640 and a clock generating circuit 1650 includes. The clock generating circuit may be a PLL circuit such as in 14 shown, or have a DLL circuit, such as in 15 which implement a split CP DCC circuit as in the corresponding ones 1 to 11 shown.

Claims (29)

Duty cycle correction circuit ( 620 ) for use in a clock generation circuit ( 610 ) is configurable, comprising: - a first amplifier circuit ( 625a ) adapted to receive a first pair of differential intermediate clock signals (CLK1, CLKB1) and to output a first pair of internal clock signals (CCLK1, CCLKB1), - a second amplifier circuit ( 625b ) adapted to receive a second pair of differential intermediate clock signals (CLK2, CLKB2) and to output a second pair of internal clock signals (CCLK2, CCLKB2), and - a charge pump ( 630 ) for receiving the first and second pairs of internal clock signals (CCLK1, CCLKB1, CCLK2, CCLKB2) and outputting a control signal (VC, VCB) based on the first and second pairs of internal clock signals (CCLK1, CCLKB1, CCLK2 , CCLKB2), wherein - the first amplifier circuit ( 625a ) sets a duty cycle of the first pair of differential intermediate clock signals (CLK1, CLKB1) in response to the control signal (VC, VCB) and the second amplifier circuit (FIG. 625b ) a duty cycle of the second pair of differential Intermediate clock signals (CLK2, CLKB2) in response to the control signal (VC, VCB). Duty cycle correction circuit according to claim 1, characterized in that a correction of the duty cycles of the first and the second pair of internal clock signals (CCLK1, CCLKB1, CCLK2, CCLKB2) based on the control signal (VC, VCB). Duty cycle correction circuit according to claim 1 or 2, characterized in that the control signal comprises a first and a second control voltage signal (VC, VCB) and the charge pump ( 630 ) comprises: - output means ( 710 ) having a first node (NO), which outputs the first control voltage signal (VC), and a second node (NOB), which outputs the second control voltage signal (VCB), - an input driver ( 720 ) for receiving the first and second pairs of internal clock signals (CCLK1, CCLKB1, CCLK2, CCLKB2) and outputting the first and second control voltage signals (VC, VCB) at the first and second nodes (NO, NOB), respectively is formed on the internal clock signals (CCLK1, CCLKB1, CCLK2, CCLKB2), and - a capacitive element (C) formed in response to the first and second nodes (NO, NOB). Duty cycle correction circuit according to claim 3, characterized in that the capacitive element (C) is adapted to maintain a substantially constant voltage difference between the first control voltage signal (VC) and the second control voltage signal (VCB). Duty cycle correction circuit according to claim 3 or 4, characterized in that the capacitive element comprises a capacitor (C) inserted between the first and the second node (NO, NOB). Duty cycle correction circuit according to one of claims 3 to 5, characterized in that the input driver ( 720 ) comprises: a first pair of transistor elements (ITR1, ITR2) adapted to receive a first internal clock signal (CCLK1) of the first pair of internal clock signals and a third internal clock signal (CCLK2) of the second pair of internal clock signals, respectively; a second pair of transistor elements (ITRB1, ITRB2) adapted to receive a second internal clock signal (CCLKB1) of the first pair of internal clock signals and a fourth internal clock signal, respectively (FIG. CCLKB2) of the second pair of internal clock signals and for outputting the second control voltage signal (VCB) at the second node (NOB). Duty cycle correction circuit according to one of claims 3 to 6, characterized in that the charge pump ( 630 ) comprises: - a first current source (IS1) connected to the first node (NO), and - a second current source (IS2) connected to the second node (NOB). Duty cycle correction circuit according to one of claims 3 to 7, characterized in that the charge pump ( 630 ) a first with the input driver ( 920 ) driver power source (ISD). Duty cycle correction circuit according to claim 8, characterized in that the input driver ( 920 ) comprises: a first pair of transistor elements (ITR1, ITR2) adapted to receive a first internal clock signal (CCLK1) of the first pair of internal clock signals and a third internal clock signal (CCLK2) of the second pair of internal clock signals, respectively; a second pair of transistor elements (ITRB1, ITRB2) adapted to receive a second internal clock signal (CCLKB1) of the first pair of internal clock signals and a fourth internal clock signal (CCLKB2 ) of the second pair of internal clock signals and for outputting the second control voltage signal (VCB) at the second node (NOB), the first drive current source (ISD) being connected to the first and the second pair of transistor elements (ISD) at a third node (NC) ITR1, ITR2, ITRB1, ITRB2) and the first and second pairs of transistor elements (ITR1, ITR2, ITRB1, ITRB2) from the first drive Power source (ISD) are driven. Duty cycle correction circuit according to claim 8 or 9, characterized in that the charge pump ( 630 ) a second, with the input driver ( 920 ) driver power source (ISD2). Duty cycle correction circuit according to claim 10, characterized in that the input driver ( 920 ) comprises: - a first transistor element (ITR1) configured to receive a first internal clock signal (CCLK1) of the first pair of internal clock signals, - a second transistor element (ITR2) adapted to receive a third internal clock signal (CCLK2) of the second pair of internal clock signals, wherein the first and second transistor elements (ITR1, ITR2) for outputting the first control voltage signal (VC) are formed at the first node (NO), - a third transistor element (ITRB1) for receiving a second internal clock signal (CCLKB1) of the first pair of internal clock signals, and a fourth transistor element (ITRB2) configured to receive a fourth internal clock signal (CCLKB2) of the second pair of internal clock signals, the third and third clock signals the fourth transistor element (ITRB1, ITRB2) is designed for outputting the second control voltage signal (VCB) at the second node (NOB), the first drive current source (ISD1) being connected to the first and the third transistor element (ITR1, ITRB1) and the first and third transistor elements (ITR1, ITRB1) are driven by the first drive current source (ISD1), and - where wherein the second drive current source (ISD2) at a fourth node (NC2) is connected to the second and fourth transistor elements (ITR2, ITRB2), and the second and fourth transistor elements (ITR2, ITRB2) are driven by the second drive current source (ISD2). Duty cycle correction circuit according to one of claims 1 to 11, characterized in that the control signal has a first and a second control voltage signal (VC, VCB) and the first and / or the second amplifier circuit ( 625a . 625b ) comprises: a first transistor element (ATR2) adapted to receive a first differential intermediate clock signal (CLK1) of a pair of differential intermediate clock signals, a second transistor element (ATR1) adapted to receive a second differential intermediate clock signal (CLKB1) of the pair of a third transistor element (ATR4) configured to receive the first control voltage signal (VC), and a fourth transistor element (ATR3) configured to receive the second control voltage signal (VCB), the first one and the third transistor element (ATR2, ATR4) for outputting a second internal clock signal (CCLKB1) of a pair of the internal clock signals at a first node (NOAB), and - the second and fourth transistor elements (ATR1, ATR3) for outputting a first one internal clock signal (CCLK1) of the pair of internal clock signals at a second Node (NOA) are formed. Duty cycle correction circuit according to claim 12, characterized in that the first and / or the second amplifier circuit ( 625a . 625b ) comprises: - a first drive current source (ISD1) connected to the first and second transistor elements (ATR2, ATR1) at a third node (NCA1), the first and second transistor elements (ATR2, ATR1) being from the first drive current source (ISD1), and - a second drive current source (ISD2) connected to the third and fourth transistor elements (ATR4, ATR3) at a fourth node (NCA2), the third and fourth transistor elements (ATR4, ATR3) driven by the second drive current source (ISD2). Integrated circuit with a duty cycle correction circuit ( 620 ) according to one of claims 1 to 13, characterized by a clock generation circuit ( 610 ) outputting the first and second pairs of differential intermediate clock signals (CLK1, CLKB1, CLK2, CLKB2). Phase locked loop circuit ( 1400 ) with a duty cycle correction circuit according to one of claims 1 to 13, characterized by: - a phase detector ( 1410 ) configured to receive an external clock signal and one of the internal clock signals and to output a second control signal, - a second charge pump ( 1420 ) and a loop filter ( 1430 ) configured to receive the second control signal and to output a control voltage based on the second control signal, and a voltage controlled oscillator ( 1440 ) configured to receive the control voltage and to output the first and second pairs of differential intermediate clock signals. Phase locked loop circuit ( 1400 ) according to claim 15, characterized in that the external clock signal is locked to one of the internal clock signals. Delay locked loop circuit ( 1500 ) with a duty cycle correction circuit according to one of claims 1 to 13, characterized by: - a phase detector ( 1510 ) configured to receive an external clock signal and one of the internal clock signals and to output a second control signal, - a second charge pump ( 1520 ) and a loop filter ( 1530 ) configured to receive the second control signal and to output a control voltage based on the second control signal, - a voltage-controlled delay line ( 1540 ), which are used to receive the control voltage and for outputting the first and the second pair of differential intermediate clock signals. Delay locked loop circuit according to claim 17, characterized in that the external clock signal is locked to one of the internal clock signals. Memory device ( 1600 ) with a duty cycle correction circuit according to one of claims 1 to 13, characterized by: - a memory cell array ( 1620 ), - an input / output circuit ( 1610 ) configured to receive data signals from the memory cell array and to output data signals to the memory cell array, and a clock generating circuit ( 1650 ) comprising the duty cycle correction circuit, - wherein the clock generation circuit ( 1650 ) is adapted to receive an external clock signal and to output the first and second pairs of internal clock signals to the input / output circuit. Memory device according to claim 19, characterized by: - an address decoder ( 1630 ) operatively connected to the memory cell array ( 1620 ) and is adapted to receive an address signal, and - a command decoder ( 1640 ) operatively connected to the input / output circuit and adapted to receive a command signal. Duty cycle correction circuit configurable for use in a clock generation circuit, comprising: - a first amplifier circuit (10); 1025a ), which is designed to receive a first unbalanced intermediate clock signal (CLK1) and to output a first internal clock signal (CCLK1), - a second amplifier circuit ( 1025b ) configured to receive a second unbalanced intermediate clock signal (CLK2) and to output a second internal clock signal (CCLK2), and - a charge pump ( 1030 ) configured to receive the first and second internal clock signals (CCLK1, CCLK2) and to output a first control voltage signal (VC) based on the first and second internal clock signals (CCLK1, CCLK2), the first and second internal clock signals Amplifier circuit ( 1025a . 1025b ) in response to the first control voltage signal (VC) each set a duty cycle of the first and the second single-ended intermediate clock signal (CLK1, CLK2), characterized in that the charge pump ( 1030 ) comprises: - a first current source (IS1) connected to a second node (N1), and - a second current source (IS2) connected to a third node (N2), - a first transistor element (PTR1) a first pair of transistor elements and a third transistor element (PTR2) of a second pair of transistor elements are connected to the second node (N1); and a second transistor element (NTR1) of the first pair of transistor elements and a fourth transistor element (NTR2) of the second pair of Transistor elements are connected to the third node (N2). Duty cycle correction circuit according to claim 21, characterized in that the charge pump comprises: - an input driver for receiving the first and the second internal clock signal (CCLK1, CCLK2) and outputting a voltage value at a first node (NOS) based on the first and the second internal clock signal (CCLK1, CCLK2) is formed, and - output means ( 110 ) configured to receive the voltage value at the first node (NOS) and receive a reference voltage value (VREF), and configured to output the first control voltage signal (VC). Duty cycle correction circuit according to claim 22, characterized in that the input driver comprises: The first pair of transistor elements (PTR1, NTR1) configured to receive the first internal clock signal (CCLK1) and to output a first voltage value at the first node (NOS), and - The second pair of transistor elements (PTR2, NTR2), which is adapted to receive the second internal clock signal (CCLK2) and to output a second voltage value at the first node (NOS). Duty cycle correction circuit according to one of claims 21 to 23, characterized in that the first and / or the second amplifier circuit ( 1025a . 1025b ) comprises: a first and a fourth transistor element (SATR1, SATR4) configured to receive the first control voltage signal (VC), and a second and a third transistor element (SATR2, SATR3) adapted to receive an unbalanced intermediate clock signal (CLK1 ) and for outputting an internal clock signal (CCLK1). Duty cycle correction circuit according to claim 24, characterized in that a Duty ratio error of the unbalanced intermediate clock signal (CLK1) is set in response to a voltage value of the first control voltage signal (VC1), wherein the duty cycle of the internal clock signal (CCLK1) is normalized. Duty cycle correction circuit according to one of Claims 21 to 25, characterized by: - a third amplifier circuit ( 1025C ) configured to receive a third unbalanced intermediate clock signal (CLK3) and to output a third internal clock signal (CCLK3), and - a fourth amplifier circuit ( 1025d ), which is designed to receive a fourth unbalanced intermediate clock signal (CLK4) and to output a fourth internal clock signal (CCLK4), - the charge pump ( 1030 ) for receiving the first, the second, the third and the fourth internal clock signal (CCLK1 ~ CCLK4), - the first control voltage signal (VC) on the first, the second, the third and the fourth internal clock signal (CCLK1 ~ CCLK4) and the first, second, third and fourth amplifier circuits (1025a ~ 1025d), in response to the first control voltage signal (VC), have a duty ratio of the first, second, third and fourth single ended intermediate clock signals (CLK1~CLK4 ) to adjust. Duty cycle correction circuit according to claim 26, characterized in that a correction of the duty cycles of the first, the second, the third and the fourth internal clock signal (CCLK1 to CCLK4) based on the first control voltage signal (VC). A method of generating a clock signal comprising the steps of: generating first and second pairs of differential intermediate clock signals (CLK1, CLKB1, CLK2, CLKB2), inputting the first pair of differential intermediate clock signals (CLK1, CLKB1) into a first amplifier circuit ( 625a ) to generate a first pair of internal clock signals (CCLK1, CCLKB1), inputting the second pair of differential intermediate clock signals (CLK2, CLKB2) into a second amplifier circuit (FIG. 625b ) to generate a second pair of internal clock signals (CCLK2, CCLKB2), inputting the first and second pairs of internal clock signals (CCLK1, CCLKB1, CCLK2, CCLKB2) into a charge pump ( 630 ) to generate a control voltage signal (VC, VCB) based on the first and second pairs of internal clock signals (CCLK1, CCLKB1, CCLK2, CCLKB2), and inputting the control voltage signal (VC, VCB) into the first and / or the second second amplifier circuit ( 625a . 625b ) to set a duty ratio of the first and second pairs of differential intermediate clock signals (CLK1, CLKB1, CLK2, CLKB2). The method of claim 28, characterized by correcting the duty cycles of the first and second pairs of internal clock signals (CCLK1, CCLKB1, CCLK2, CCLKB2) based on the control voltage signal (VC, VCB).

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