A dll circuit is designed to adjust the delay time and the duty applied to an input clock signal, thus producing a dll clock signal. In a non-clocking state of the dll clock signal in which pulses disappear temporarily, the dll circuit stops updating the delay time and the duty of the dll clock signal. That is, the dll circuit is capable of preventing a phase difference between the input clock signal and the dll clock signal from being erroneously detected in the non-clocking state of the dll clock signal, thus preventing the delay time and the duty from being updated based on the erroneously detected phase difference. Thus, it is possible to reduce the number of cycles adapted to the delay-locked control and to thereby stabilize the operation of the dll circuit.
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8. A semiconductor device comprising:
a control circuit that responds to first and second feedback signals to produce a control signal; and
a dll clock signal generation circuit that receives an input clock signal and the control signal and generates a dll clock signal that is related to the input clock signal and controlled in at least one of a phase and a duty in response to the control signal,
wherein the first feedback signal is produced in response to at least the dll clock signal and the second feedback signal that is produced in response to the dll clock signal unchanged in a logic level during at least one cycle of the input clock signal.
0. 14. A delay locked loop (dll) circuit comprising:
a delay control circuit that produces a delay signal to control a delay time applied to an input clock signal;
a delay circuit that applies the delay time to the input clock signal based on the delay signal, thus producing a dll clock signal; and
a clock detection circuit that detects either a clocking state or a non-clocking state with respect to a clock signal based on the input clock signal,
wherein the clock detection circuit controls the delay control circuit to prevent updates to the delay signal when the non-clocking state is detected and to allow updates to the delay signal when the clocking state is detected.
1. A dll circuit adjusting a duty of an input clock signal, comprising:
a duty control circuit that produces a duty signal to control the duty of the input clock signal;
a duty adjustment circuit that adjusts the duty of the input clock signal based on the duty signal, thus producing a dll clock signal; and
a dll clock detection circuit that detects either a clocking state or a non-clocking state with respect to the dll clock signal,
wherein the dll clock detection circuit controls the duty control circuit to produce the duty signal to change the dll clock signal from the non-clocking state to the clocking state when the dll clock detection circuit detects the non-clocking state with respect to the dll clock signal.
2. A dll circuit comprising:
a duty control circuit that produces a duty signal to control a duty of a first clock signal input thereto;
a duty adjustment circuit that adjusts the duty of the first clock signal based on the duty signal, thus producing a second clock signal;
a delay control circuit that produces a delay signal to control a delay time applied to the second clock signal;
a delay circuit that applies the delay time to the second clock signal based on the delay signal, thus producing a dll clock signal; and
a dll clock detection circuit that detects either a clocking state or a non-clocking state with respect to the dll clock signal,
wherein the dll clock detection circuit controls at least one of the duty control circuit and the delay control to produce corresponding one or ones of the duty signal and the delay signal to change the dll clock signal from the non-clocking state to the clocking state when the dll clock detection circuit detects the non-clocking state of the dll clock signal.
3. A dll circuit adjusting a phase of an input clock signal, comprising:
a delay control circuit that produces a delay signal to control a delay time applied to the input clock signal;
a delay circuit that applies the delay time to the input clock signal based on the delay signal, thus producing a dll clock signal; and
a dll clock detection circuit that detects either a clocking state or a non-clocking state with respect to the dll clock signal,
wherein the dll clock detection circuit controls the delay control circuit to produce the delay signal to change the dll clock signal from the non-clocking state to the clocking state when the dll clock detection circuit detects the non-clocking state with respect to the dll clock signal, and
wherein the dll clock signal and a dll clock detection enable signal for periodically activating the dll clock detection circuit are supplied to the dll clock detection circuit, which includes a counter for counting a number of pulses included in the dll clock signal during activation of the dll clock detection enable signal, and a latch circuit for declaring the clocking state of the dll clock signal when the counted number is greater than a prescribed number and for declaring the non-clocking state of the dll clock signal when the counted number is less than the prescribed number.
5. A dll circuit adjusting a phase of an input clock signal, comprising:
a delay control circuit that produces a delay signal to control a delay time applied to the input clock signal;
a delay circuit that applies the delay time to the input clock signal based on the delay signal, thus producing a dll clock signal;
a dll clock detection circuit that detects either a clocking state or a non-clocking state with respect to the dll clock signal;
a dq buffer for buffering the dll clock signal;
a dq replica circuit for receiving the dll clock signal so as to output a dq replica output signal; and
a phase detection circuit for detecting a phase difference between the input clock signal and the dq replica output signal, thus producing a phase detection result,
wherein the dll clock detection circuit controls the delay control circuit to produce the delay signal to change the dll clock signal from the non-clocking state to the clocking state when the dll clock detection circuit detects the non-clocking state with respect to the dll clock signal,
wherein the delay control circuit includes a latch circuit for latching the delay time presently applied to the dll clock signal, and an adder for adding the phase difference to the delay time based on the phase detection result so as to produce an addition result, and
wherein the addition result of the adder is latched by the latch circuit as a new delay time when the dll clock detection circuit declares the clocking state of the dll clock signal.
4. The dll circuit according to
6. The dll circuit according to
9. The semiconductor device according to
10. The semiconductor device according to
11. The semiconductor device according to
12. the semiconductor device according to
13. The semiconductor device according to
0. 15. The dll circuit of claim 14, wherein the clock signal based on the input clock signal is the dll clock signal.
0. 16. The dll circuit of claim 14, wherein the clock detection circuit comprises a plurality of D-type latches, a first latch among the plurality of D-type latches having an output terminal connected to an input terminal of a second latch among the plurality of D-type latches.
0. 17. The dll circuit of claim 16, wherein the clock detection circuit allows updates to the delay signal when the plurality of D-type latches each have the same logic level on respective output terminals.
0. 18. The dll circuit of claim 14, further comprising a duty control circuit and a duty adjustment circuit to adjust the duty of the dll clock signal.
0. 19. The dll circuit of claim 18, wherein the duty control circuit controls the duty adjustment circuit to adjust the duty of the dll clock signal to approximately 50%.
0. 20. The dll circuit of claim 18, wherein the clock detection circuit controls the duty control circuit to prevent adjustment of the duty of the dll clock signal when the non-clocking state is detected and to allow adjustment of the duty of the dll clock signal when the clocking state is detected.
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1. Field of the Invention
The present invention relates to delay-locked loop (DLL) circuits adapted to semiconductor devices.
The present application claims priority on Japanese Patent Application No. 2008-129638, the content of which is incorporated herein by reference.
2. Description of the Related Art
Due to increasing high-speed processing of electronic systems recently developed, it is necessary to perform high-speed data transfer between semiconductor devices installed in electronic systems, wherein semiconductor devices employ clock synchronization methods. As semiconductor memory devices, synchronous dynamic random-access memories (SDRAM) have been conventionally used and further developed into double-data-rate (DDR) SDRAM, DDR2 SDRAM, and DDR3 SDRAM which operate in synchronization with leading/trailing edges of clock pulses.
In order to establish synchronization with clock pulses, delay-locked loop (DLL) circuits have been used for synchronous dynamic random-access memories (SDRAM) so as to establish synchronization of timing between internal clock pulses and external clock pulses.
Along a path A shown by dotted lines, the DLL clock signal is supplied to a DQ replica circuit 15, from which a DQ replica output signal is supplied to a phase detection circuit 16 and subjected to phase comparison with the clock signal CK and the inverse clock signal /CK. The phase comparison result is fed back to a delay control circuit 13. Based on the phase comparison result output from the phase detection circuit 16, the delay control circuit 13 outputs a delay signal to a delay circuit 12 so as to adjust a delay element of the delay circuit 12.
Along a path B shown by dotted lines, the DLL clock signal is supplied to a duty detection circuit 21 and subjected to detection as to whether a duty thereof is above or below 50%. The duty detection result is fed back to a duty control circuit 22. Based on the duty detection result output from the duty detection circuit 21, the duty control circuit 22 outputs a control signal (i.e. a duty signal) to a duty adjustment circuit 23. The duty adjustment circuit 23 adjusts the duty of a clock signal output from the initial circuit 11 based on the clock signal CK and the inverse clock signal /CK in accordance with the duty signal output from the duty control circuit 22.
The delay circuit 12 performs delay adjustment so as to cancel out timing skew between the DQ replica output signal and the clock signal CK (or the inverse clock signal /CK). In addition, the duty adjustment circuit 23 performs duty adjustment such that the duty of the DLL clock signal becomes equal to or close to 50%.
The clock signal output from the initial circuit 11 is subjected to a frequency dividing process by a counter clock generation circuit 17, which thus outputs a counter clock signal to a DLL cycle counter 18. Based on the counter clock signal, the DLL cycle counter 18 generates an update clock signal for a prescribed duration, thus outputting it to the delay control circuit 13 and the duty control circuit 22. The delay control circuit 13 and the duty control circuit 22 update their operations in response to the update clock signal.
It is necessary for the DLL circuit of
Since the phase detection circuit 16 and the duty detection circuit 21 trigger their operations in response to the DLL clock signal, it is very difficult to precisely detect the phase in the period in which the DLL clock signal disappears.
Repeating the phase detection and the duty detection in erroneous manners increases the number of cycles adapted to the delay-locked control and disables the delay-clocked control pursuant to prescribed technical specifications which are determined in advance. This requires manufacturers to solve the above problem due to the temporary disappearance of the DLL clock signal.
Various technologies for canceling out deviations of duties of clock signals have been developed and disclosed in various documents such as Patent Document 1.
Patent Document 1 teaches a clock generation circuit which cancels out deviations of the duty of an output clock signal (causing some problems in phase control) by additionally using a simple circuit, thus achieving high-precision phase control. Specifically, a variable delay circuit is followed by a clock duty adjustment circuit and is controlled in the delay time thereof at the leading edge of a clock pulse, wherein the clock duty adjustment circuit performs adjustment at the trailing edge when the phase of the output clock signal at its leading edge matches the phase of a reference clock signal, thus identifying the duty of the output clock signal with the duty of the reference clock signal.
The present inventors have recognized that the clock generation circuit of Patent Document 1 is not designed to solve the above problem regarding the delay-locked control in which the DLL circuit fails to precisely perform phase adjustment due to erroneous detection during the disappearance period of the DLL clock signal, thus increasing the number of cycles adapted to the delay-locked control.
Due to the execution of the delay-locked control with a small number of cycles during the DLL reset period, it is necessary for the DLL circuit to simultaneously perform the delay adjustment and the duty adjustment. At a high input clock frequency, each pulse width of the input clock signal varies greatly due to delay adjustment during the delay-locked control so as to cause the disappearance period of the DLL clock signal, which makes it very difficult to precisely perform the phase detection and the duty detection.
In addition, repeating the phase detection and the duty detection in erroneous manners increases the number of cycles adapted to the delay-locked control and disables the delay-locked control pursuant to prescribed technical specifications.
The invention seeks to solve the above problem, or to improve upon the problem at least in part.
The present invention is directed to a DLL circuit which generates and monitors a DLL clock signal based on an input clock signal and which prevents a delay time and a duty from being updated based on the phase detection result and the duty detection result erroneously produced due to disappearance of the DLL clock signal, thus executing the delay-locked control with a small number of cycles in a stable manner.
In one embodiment, a DLL circuit for adjusting the phase of an input clock signal is constituted of delay control circuit for producing a delay signal so as to control a delay time applied to the input clock signal, a delay circuit for applying the delay time to the input clock signal based on the delay signal, thus producing a DLL clock signal, and a DLL clock detection circuit for detecting either a clocking state or a non-clocking state with respect to the DLL clock signal, wherein the DLL clock detection circuit controls the delay control circuit to stop updating the delay time in the delay circuit in the non-clocking state of the DLL clock signal.
In another embodiment, a DLL circuit for adjusting the duty of an input clock signal is constituted of a duty control circuit for producing a duty signal so as to control the duty of the input clock signal, a duty adjustment circuit for adjusting the duty of the input clock signal based on the duty signal, thus producing a DLL clock signal, and a DLL clock detection circuit for detecting either a clocking state or a non-clocking state with respect to the DLL clock signal, wherein the DLL clock detection circuit controls the duty control circuit to stop updating the duty in the duty adjustment circuit in the non-clocking state of the DLL clock signal.
In the above, it is possible to prevent a phase difference between the input clock signal and the DLL clock signal from being erroneously detected in the non-clocking state of the DLL clock signal in which pulses disappear temporarily, thus preventing the delay time and the duty from being updated based on the erroneously detected phase difference. Thus, it is possible to reduce the number of cycles adapted to the delay-locked control and to thereby stabilize the operation of the DLL circuit.
The above features and advantages of the present invention will be more apparent from the following description of certain preferred embodiments taken in conjunction with the accompanying drawings, in which:
The present invention will be now described herein with reference to illustrative embodiments. Those skilled in the art will recognize that many alternative embodiments can be accomplished using the teachings of the present invention and that the invention is not limited to the embodiments illustrated for explanatory purposes.
In
The counter clock generation circuit 17 divides the frequency of the clock signal so as to generate and output a counter clock signal (see
The delay circuit 12 includes a plurality of delay elements, one of which is selected to impart a prescribed delay time to the clock signal in response to a delay signal output from the delay control circuit 13.
The delay control circuit 13 determines the delay time based on the phase detection result output from the phase detection circuit 16, thus outputting the delay signal to the delay circuit 12. The DQ buffer 14 buffers a DLL clock signal output from the delay circuit 12, thus outputting a DQ signal. The DQ replica circuit 15 is a replica (or a replication) of the DQ buffer 14; that is, it is a buffer circuit having the same PVT dependency (i.e. dependency of process, voltage, and temperature) as the DQ buffer 14.
The phase detection circuit 16 performs phase comparison between the DQ replica output signal (output from the DQ replica circuit 15) and the clock signals CK and /CK, thus outputting a phase detection result representing a phase difference between them to the delay control circuit 13. The DLL cycle counter 18 counts the number of pulses included in the counter clock signal so as to generate an update clock signal (see
The DLL circuit of
In the DLL circuit of
The DLL clock signal output from the delay circuit 12 is also supplied to the DQ replica circuit 15 which has the same PVT dependency as the DQ buffer 14. Since the DQ replica circuit 15 serves as a buffer circuit having the same PVT dependency as the DQ buffer 14, the DQ replica output signal is output at the same timing as the DQ buffer 14 outputting the DQ output signal. The DQ replica output signal is supplied to the phase detection circuit 16 and subjected to phase comparison with the clock signals CK and /CK. The phase detection result output from the phase detection circuit 16 is supplied to the delay control circuit 13, so that the delay circuit 12 adjusts the delay time based on the delay signal output from the delay control circuit 13.
The DLL clock detection circuit 31 receives the DLL clock detection enable signal (output from the DLL cycle counter 18) and the DLL clock signal (output from the delay circuit 12), wherein the DLL clock detection circuit 31 is periodically activated by the DLL clock detection enable signal. The period of the DLL clock detection enable signal is identical to the update period for updating the delay time.
The DLL clock detection circuit 31 makes determination as to whether or not the DLL clock signal is placed in a clocking state, thus producing and outputting a DLL clock detection result (or update enable/disable signals) to the DLL cycle counter 18 and the delay control circuit 13. The DLL clock detection circuit 31 controls the DLL cycle counter 18 to output or stop the update clock signal, thus executing or stopping updating the delay time by way of the delay circuit 12 and the delay control circuit 13.
The first embodiment is characterized by using the DLL clock detection circuit 31 for determining whether or not the DLL clock signal is placed in a clocking state, wherein the DLL clock determination result is supplied to the DLL cycle counter 18 and the delay control circuit 13 so as to stops updating the delay time in a non-clocking state of the DLL clock signal. In the delay-locked control of the DLL circuit of the first embodiment, it is possible to prevent the delay time from being updated based on the phase detection result which is erroneously produced in the disappearance period of the DLL clock signal. Thus, it is possible to reduce the number of clock pulses adapted to the delay-locked control and to thereby improve the stability of the DLL circuit performing the delay-locked control.
The DLL circuit of
In
The counter clock generation circuit 17 divides the frequency of the clock signal so as to generate and output the counter clock signal (see
The duty detection circuit 21 performs detection as to whether the duty of the DLL clock signal is above or below 50%. Based on the duty detection result output from the duty detection circuit 21, the duty control circuit 22 performs the duty control on the update clock signal from the DLL cycle counter 18. Based on the duty signal output from the duty control circuit 22, the duty adjustment circuit 23 adjusts the duty of the clock signal output from the initial circuit 11, thus outputting the DLL clock signal.
The DLL cycle counter 18 counts the number of pulses included in the counter clock signal so as to generate the update clock signal for updating the duty control. The DLL clock detection circuit 31 detects whether or not the DLL clock signal disappears (or whether or not the DLL clock signal is placed in a clocking state), thus generating the DLL clock detection result (or the update enable/disable signals) for executing or stopping updating the duty control. The details of the DLL clock detection circuit 31 will be described later.
In
The DLL clock signal output from the duty adjustment circuit 23 is supplied to the duty detection circuit 21 and subjected to duty detection. The duty detection result output from the duty detection circuit 21 is supplied to the duty control circuit 22. Based on the duty detection result, the duty control circuit 22 generates the duty signal for controlling the duty adjustment performed by the duty adjustment circuit 23. Based on the duty signal, the duty adjustment circuit 23 adjusts the duty of the clock signal output from the initial circuit 11. The details of the duty detection circuit 21 will be described later.
The DLL clock detection circuit 31 receives the DLL clock detection enable signal (from the DLL cycle counter 18) and the DLL clock signal (from the duty adjustment circuit 23), wherein the DLL clock detection circuit 31 is periodically activated by the DLL clock detection enable signal. The period of the DLL clock detection enable signal is identical to the update period for updating the duty.
The DLL clock detection circuit 31 detects either a clocking state or a non-clocking state with respect to the DLL clock signal, thus outputting the DLL clock detection result (or the update enable/disable signals) to the DLL cycle counter 18 and the duty detection circuit 21. Thus, the DLL clock detection circuit 31 controls the DLL cycle counter 18 to output or stop the update clock signal while also controlling the duty adjustment circuit 23 to execute or stop the duty control.
The second embodiment is designed such that the DLL clock detection result, which is produced by the DLL clock detection circuit 31 detecting either the clocking state or the non-clocking state with respect to the DLL clock signal, is fed back to the duty detection circuit 21 for producing the duty detection result, wherein the DLL clock signal is restored by means of the duty detection circuit 21 and the duty control circuit 22. The constitution and operation of the duty detection circuit 21 will be described later in detail.
In the delay-locked control of the DLL circuit of the second embodiment, it is possible to prevent the duty from being updated based on the duty detection result which is erroneously produced in the disappearance period of the DLL clock signal. Thus, it is possible to reduce the number of clock pulses adapted to the delay-locked control and to thereby improve the stability of the DLL circuit performing the delay-locked control. In addition, it is possible to restore the DLL clock signal by means of the duty detection circuit 21 and the duty control circuit 22.
The DLL circuit of
The duty adjustment circuit 23 adjusts the duty of the clock signal of the initial circuit 11 such that the duty of an internal clock signal used in the DQ buffer 14 becomes equal to or close to 50%. The delay circuit 12 corrects the delay time imparted to the duty-adjusted clock signal output from the duty adjustment circuit 23 such that the DQ output signal of the DQ buffer 14 is synchronized with the clock signals CK and /CK, thus outputting the DLL clock signal to the DQ buffer 14.
The DLL clock signal is supplied to the DQ replica circuit 15 having the same PVT dependency as the DQ buffer 14. Since the DQ replica circuit 15 serves as a buffer circuit having the same dependency of process, voltage, and temperature as the DQ buffer 14, the DQ replica output signal is output at the same timing as the DQ output signal. The DQ replica output signal of the DQ replica circuit 15 is supplied to the phase detection circuit 16 and subjected to phase comparison with the clock signals CK and /CK. The phase detection result output from the phase detection circuit 16 is supplied to the delay control circuit 13, thus adjusting the delay time by way of the delay circuit 12.
The DDL clock signal is supplied to the duty detection circuit 21 and subjected to duty detection, so that the duty detection result is supplied to the duty control circuit 22, thus adjusting the duty by way of the duty adjustment circuit 23.
The DLL clock detection circuit 31 is periodically activated by the DLL clock detection enable signal, wherein the period of the DLL clock detection enable signal is identical to the period for updating the delay time and duty.
The DLL clock detection circuit 31 detects either the clocking state or the non-clocking state with respect to the DLL clock signal, thus generating the DLL clock detection result (or the update enable/disable signals). The DLL clock detection result is supplied to the delay control circuit 13, the DLL cycle counter 18, and the duty detection circuit 21.
In accordance with the DLL clock detection result, the DLL cycle counter 18 outputs or stops the update clock signal while the delay control circuit 13 executes or stops updating the delay time. In addition, the duty detection circuit 21, the duty control circuit 22, and the duty adjustment circuit 23 collaborate to execute or stop updating the duty in accordance with the DLL clock detection result.
The third embodiment is designed such that the DLL clock detection circuit 31 detects either the clocking state or the non-clocking state with respect to the DLL clock signal, and then the DLL clock detection result is supplied to the delay control circuit 13, the DLL cycle counter 18, and the duty control circuit 22, thus inhibiting the delay control and the duty control in the non-clocking state of the DLL clock signal.
In addition, the third embodiment is designed such that the DLL clock detection result, which is produced by the DLL clock detection circuit 31 detecting either the clocking state or the non-clocking state with respect to the DLL clock signal, is fed back to the duty detection circuit 21 producing the duty detection result, wherein the DLL clock signal is restored by way of the duty detection circuit 21 and the duty control circuit 22. The constitution and operation of the duty detection circuit 21 will be described later in detail.
In the delay-locked control of the DLL circuit of the third embodiment, it is possible to prevent the delay time and the duty from being updated based on the phase detection result and the duty detection result which are erroneously produced in the disappearance period of the DLL clock signal. Thus, it is possible to reduce the number of clock pulses adapted to the delay-locked control and to thereby improve the stability of the DLL circuit performing the delay-locked control. In addition, it is possible to restore the DLL clock signal by means of the duty detection circuit 21 and the duty control circuit 22.
The DLL circuit of
The output signal of the inverter 101 is supplied to reset terminals R of D-type latch circuits 105 and 106 (having data terminals D, output terminals Q, and clock terminals C) as well as a first input terminal “a” of an RS-type latch circuit 104 including NAND circuits 102 and 103. In the RS-type latch circuit 104, the first input terminal “a” corresponds to one input terminal of the NAND circuit 102, and a second input terminal “b” corresponds to one input terminal of the NAND circuit 103, wherein the NAND circuits 102 and 103 are coupled together such that an output terminal “c” of the NAND circuit 102 is connected to another input terminal of the NAND circuit 103 whose output terminal is connected to another input terminal of the NAND circuit 102.
The DLL clock detection circuit 31 includes a plurality of D-type latch circuits wherein the D-type latch circuit 105 is an uppermost one and is followed by the D-type latch circuit 106. The date terminal D of the first D-type latch circuit 105 is connected to a power-supply voltage Vcc (at a high level) while an output terminal Q thereof is connected to the data terminal D of the second D-type latch circuit 106.
The D-type latch circuits 105 and 106 are followed by a NAND circuit 107 having three input terminals a1, a2, and a3 such that the output terminal Q of the first D-type latch circuit 105 is connected to the first input terminal a1 while the output terminal Q of the second D-type latch circuit 106 is connected to the second input terminal a2. Both the clock terminals C of the D-type latch circuits 105 and 106 receive the DLL clock signal subjected to detection.
The output signal of the NAND circuit 107 is supplied to the second input terminal b of the RS-type latch circuit 104, so that the RS-type latch circuit 104 outputs an output signal OUT as the DLL clock detection result (or the update enable/disable signals) toward the delay control circuit 13 and the duty detection circuit 21. The DLL clock detection result becomes a high-level update enable signal in the clocking state of the DLL clock signal, while it becomes a low-level update disable signal in the non-clocking state of the DLL clock signal.
The DLL clock detection enable signal becomes high so as to activate the DLL clock detection circuit 31, wherein a low-level output signal of the inverter 101 is supplied to the reset terminals R of the D-type latch circuits 105 and 106 so as to release the reset states of the D-type latch circuits 105 and 106, so that the output terminals Q of the D-type latch circuits 105 and 106 are each turned to a low level.
Just after the reset states of the D-type latch circuits 105 and 106 are released, the input terminals a1 and a2 of the NAND circuit 107 are each set at a low level, so that the output signal of the NAND circuit 107 is at a high level which is applied to the second input terminal b of the RS-type latch circuit 104. Since the low-level output signal of the inverter 101 is supplied to the first input terminal a1 (corresponding to one input terminal of the NAND circuit 102), the output terminal c of the NAND circuit 102 becomes high, so that the output signal OUT (corresponding to the output terminal of the NAND circuit 103) becomes low. That is, just after the DLL clock detection circuit 31 is activated, the RS-type latch circuit 104 outputs the low-level output signal OUT serving as the update disable signal declaring the non-clocking state of the DLL clock signal.
At the leading edge of a first pulse of the DLL clock signal supplied to the clock terminals C of the D-type latch circuits 105 and 106, the output terminal Q of the D-type latch circuit 105 becomes high while the output terminal Q of the D-type latch circuit 106 remains low.
When a second pulse of the DLL clock signal is subsequently supplied to the clock terminals C of the D-type latch circuits 105 and 106, the output terminal Q of the D-type latch circuit 106 becomes high while the output terminal Q of the D-type latch circuit 105 remains high. That is, every time the D-type latch circuits receive a pulse of the DLL clock signal, the output terminals Q thereof are sequentially turned to a high level in an order from the uppermost one.
When all the output terminals Q of the D-type latch circuits (including the D-type latch circuits 105 and 106) become high, all the input terminals of the NAND circuit 107 become high so that the NAND circuit 107 outputs a low-level signal to the second input terminal b of the RS-type latch circuit 104 (corresponding to one input terminal of the NAND circuit 103). Thus, the output terminal of the NAND circuit 103 becomes high so that the output signal OUT of the RS-type latch circuit 104 correspondingly becomes high, whereby the DLL clock detection circuit 31 outputs the update enable signal declaring the clocking state of the DLL clock signal.
When the DLL clock signal disappears, at least one of the input terminals a1 to a3 of the NAND circuit 107 remains at a low level so that the output terminal of the NAND circuit 107 still remains at a high level, wherein the output signal OUT of the RS-type latch circuit 104 is not turned to a high level and still remains at a low level, so that the DLL clock detection circuit 31 outputs the update disable signal declaring the non-clocking state of the DLL clock signal.
Thereafter, the DLL clock detection enable signal becomes low, so that the RS-type latch circuit 104 retains the previous DLL clock detection result (representing either the clocking state or the non-clocking state) until DLL clock detection enable signal turns to a high level.
The activation period (or high-level period) of the DLL clock detection enable signal is set to “2×(clock period tCK [ns])” or more when the DLL clock detection circuit 31 uses the two D-type latch circuits 105 and 106. In response to the number “n” of D-type latch circuits included in the DLL clock detection circuit 31 (where n≧3), the activation period of the DLL clock detection enable signal is set to “n×(clock period tCK [ns])” or more.
Next, the operation of the DLL clock detection circuit 31 of
Next, the operation of the DLL clock detection circuit 31 for detecting either the clocking state or the non-clocking state and the operation of the DLL cycle counter 18 for generating the update clock signal will be described with reference to
Upon reception of the counter clock signal of
The DLL clock detection circuit 31 starts detecting either the clocking state or the non-clocking state with respect to the DLL clock signal of
Due to the non-clocking state of the DLL clock signal occurring at the timing when the DLL clock detection circuit 31 starts detecting either the clocking state or the non-clocking state of the DLL clock signal in response to the pulse C2 of the DLL clock detection enable signal of
The waveforms of signals shown in
First, the operation of the DLL circuit in the clocking state of the DLL clock signal will be described with reference to
The DLL clock detection result of
Thus, the update clock signal of
In response to the high-level update clock signal from the DLL cycle counter 18 and the high-level update enable/disable signal from the DLL clock detection circuit 31, the delay control circuit 13 controls the delay circuit 12 to adjust the delay time applied to the DLL clock signal.
On the other hand, in response to the high-level update clock signal from the DLL cycle counter 18 and the duty detection result from the duty detection circuit 21, the duty control circuit 22 controls the duty adjustment circuit 23 to adjust the duty of the DLL clock signal, which is thus set to 50%.
Next, the operation of the DLL circuit coping with the disappearance of pulses of the DLL clock signal will be described with reference to
At time t1 when the DLL clock detection enable signal of
At time t1, pulses disappear in the DLL clock signal of
Thus, the DLL clock detection result of
Thus, the DLL cycle counter 18 does not generate a pulse of the update clock signal shown in
As shown in
A first input terminal of the AND circuit 205 receives the update clock signal from the DLL cycle counter 18, while a second input terminal thereof receives the DLL clock detection result (i.e. the update enable/disable signals) from the DLL clock detection circuit 31. The output terminal of the AND circuit 205 is connected to the clock terminals C of the D-type latch circuits 202, 203, and 204 respectively.
In the delay control circuit 13 of
When the DLL clock detection result becomes high (denoting the update enable signal) during the high-level period of the update clock signal, the output signal of the adder 201 (representing the updated delay time) is latched by the D-type latch circuits 202 to 204, from which it is supplied to the delay circuit 12.
When the DLL clock detection result becomes low (denoting the update disable signal) during the high-level period of the update clock signal, the output signal of the AND circuit 205 becomes low so that the updated delay time of the adder 201 is not latched by the D-type latch circuits 202 to 204. At this time, the D-type latch circuits 202 to 204 are not updated so as to still retain the previous delay time.
Next, the detailed constitution and operation of the duty detection circuit 21 will be described with reference to
In the duty detection circuit 21 of
Meanwhile, the DLL clock signal is supplied to a duty detector 303 and a data terminal D of a D-type latch circuit 304. The output signal of the duty detector 303 is supplied to a first input terminal “a” of the selector 306. The output signal of the D-type latch circuit 304 at its output terminal Q is inverted in logic level by an inverter 305 and is then supplied to a second input terminal “b” of the selector 306.
The duty detector 303 detects whether the duty (i.e. the high-level period of a pulse of the DLL clock signal) is greater or less than 50%, thus producing the duty detection result. In the case of
In response to the high-level DLL clock detection result (declaring the clocking state of the DLL clock signal), the selector 306 switches over to the first input terminal “a” so as to select the duty detection result of the duty detector 303, which is then output to the duty control circuit 22.
In response to the low-level DLL clock detection result (declaring the non-clocking state of the DLL clock signal), the selector 306 switches over to the second input terminal “b” so as to select the output signal of the inverter 305, which is then output to the duty control circuit 22.
In the transition of the DLL clock detection result to the low level, the D-type latch circuit 304 latches the stack level of the DLL clock signal, which is inverted by the inverter 305 (whose input terminal is connected to the output terminal Q of the D-type latch circuit 304) and is then supplied to the second input terminal b of the selector 306.
When the DLL clock detection result declares the non-clocking state of the DLL clock signal, the duty detection result turns to a low level (representing the duty decrease signal) in response to the “high” level stacked in the DLL clock signal, while the duty detection result turns to a high level (representing the duty increase signal) in response to the “low” level stacked in the DLL clock signal. Responding to the high level or the low level of the duty detection result, the duty of the DLL clock signal is restored by increasing or decreasing. This makes it possible to control the duty of the DLL clock signal, thus restoring the clocking state of the DLL clock signal.
Lastly, it is apparent that the present invention is not limited to the above embodiments, but may be modified and changed without departing from the scope and spirit of the invention.
Kuroki, Koji, Takishita, Ryuuji
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