KR100399947B1 - clock signal generator - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a clock signal generator, and more particularly to a 512/1025 clock divider used in a code division multiple access phone (CDMA phone). SUMMARY OF THE INVENTION An object of the present invention is to provide a clock generation circuit which is simple in circuit construction and can be used not only for non-integer division but also for even division or odd division. According to an aspect of the present invention, two or three divisions for receiving an input clock signal having a predetermined frequency and dividing two or three at the first edge of the input clock signal according to a first control signal to generate as an output clock signal. Way; Control signal generating means for generating a second control signal by counting an output clock signal of said two or three division means; And synchronizing means for synchronizing the second control signal output from the control signal generating means to the second or third division means as the first control signal in synchronization with the second edge of the input clock signal. Or the third dividing means comprises: an AND gate for making the control signal provided from the synchronizing means a first input; A first D flip-flop for outputting the AND gate as an input signal, inputting the input clock signal as a clock signal, and providing an inverted output thereof to a second input of the AND gate; A noah gate having the output of the first D flip-flop as one input; And an output signal of the NOR gate as an input signal, the clock input signal as a clock signal, and an output signal of the NOR gate as a clock signal divided by two or three, and at the same time, the third input and the noah of the AND gate. A clock signal generation circuit is provided, comprising a 2D flip-flop for providing with a gate type force.

Description

Clock signal generator circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a clock signal generator, and more particularly to a 512/1025 clock divider used in a code division multiple access phone (CDMA phone).

CDMA phones use the 9.8304Mhz clock signal, which is eight times the clock of 1.2288Mhz, as the master clock. The clock signal generated from the commonly used clock oscillator has a frequency of 19.68Mhz. In order to make a clock signal of 9.8304Mhz using the clock signal of 19.68Mhz, 512/1025 division should be performed instead of integer division.

A technique for producing a clock signal of 9.8304Mhz by dividing a clock signal of 19.68Mhz by 512/1025 instead of integer division has been proposed (see US Patent No. 5,499,280). 1 shows a 512/1025 clock divider circuit for generating a clock signal of 9.8304Mhz used in a CDMA phone.

Referring to FIG. 1, a conventional 512/1025 frequency division circuit includes a clock generator 10 for generating a predetermined clock signal, for example, a clock signal clk of 19.68Mhz, and is output from the clock generator 10. An 11-bit counter 20 that generates an overflow signal OF when the clock signal clk is counted and the 1024 clock signal clk is input, and an overflow signal OF generated from the 11-bit counter 20. By the 1025th clock signal, the M / N counter 30 is disabled to generate a predetermined clock signal, for example, a clock signal CLKout of 9.8304Mhz.

FIG. 2 is a detailed circuit diagram of an 11-bit counter and an M / N counter in the 512/1025 clock divider circuit of FIG. 1. Referring to FIG. 2, the 11-bit counter 20 includes five 2-bit counters 21-25 for counting the clock signal clk generated from the clock oscillator 10 and T (toggle) which is a 1-bit counter. The flip-flop 26 is configured to generate an overflow signal OF when the 1024th clock signal clk is applied. The M / N counter 30 is a T flip-flop 31 and a 2-bit counter 32 which are disabled in the 1025th clock signal clk when the overflow signal OF is applied from the 11-bit counter 20. It consists of. In FIG. 1, when the clock signal CLKout of 9.8304Mhz is generated using the clock signal clk of 19.68Mhz, the M / N counter 30 becomes a half counter.

Referring to the operation of the conventional 512/1025 clock divider circuit as described above, the clock oscillator 10 receives a predetermined clock signal clk, for example, a clock signal clk of 19.68Mhz. And the clock signal of the M / N counter 30.

The 11-bit counter 20 inputs and counts the clock signal clk generated from the clock oscillator 10. When the 1024 th clock signal clk is input, the overflow signal OF is shown in FIG. ) And the 11-bit counter 20 is reset by the enable bar signal ENB generated by this overflow signal OF.

In addition, the M / N counter 30 generates the clock signal CLKout as shown in FIG. 3 according to the clock signal clk applied from the clock oscillator 10. From the 11-bit counter 20 When the overflow signal OF is generated, the M / N counter 30 is disabled by the enable signal bar ENB. Therefore, the M / N counter 30 does not operate on the 1025th clock signal clk, and the clock signal CLKout of 9.8304Mhz divided by 512/1025 divided by the 19.68Mhz clock signal clk as shown in FIG. The conventional 512/1025 clock divider circuit as described above uses an 11-bit counter to generate an overflow signal as a control signal of the M / N counter. There is a limit that cannot be used except for non-integer division such as 1025.

The present invention has been proposed to solve the problems of the prior art as described above, and provides a clock generation circuit which is simple in circuit construction and can be used not only for non-integer division but also for integer division (even or odd division). There is a purpose.

1 is a block diagram of a 512/1025 clock divider circuit used in a conventional CDMA phone.

FIG. 2 is a detailed circuit diagram of an 11-bit counter and an M / N counter in the 512/1025 clock divider circuit of FIG. 1; FIG.

3 is an operation waveform diagram of a conventional 512/1025 clock divider circuit.

4 is a block diagram of a clock generation circuit capable of 512/1025 clock division for use in a CDMA phone according to an embodiment of the present invention.

5 is a detailed circuit diagram of two or three dividers in the clock generation circuit capable of 512/1025 clock division of FIG.

6 is a state diagram of the two or three dividers of FIG.

7 is an operation waveform diagram of the two or three dispensing means of FIG.

8 is a detailed view of control signal generating means in the clock generation circuit of FIG.

9 is an operational waveform diagram of the control signal generating means of FIG. 8;

10 is an operation waveform diagram of the clock generation circuit of the present invention of FIG.

* Description of the symbols for the main parts of the drawings *

100: 2 or 3 division means 200: control signal generating means

300: synchronization means 101: end gate

102, 104: D flip-flop 103: Noah gate

201-209: D flip-flop

According to an aspect of the present invention for achieving the above object, by receiving an input clock signal having a predetermined frequency divided by 2 or 3 at the first edge of the input clock signal according to the first control signal as an output clock signal Two or three dispensing means for generating; Control signal generating means for generating a second control signal by counting an output clock signal of said two or three division means; And synchronizing means for synchronizing the second control signal output from the control signal generating means to the second or third division means as the first control signal in synchronization with the second edge of the input clock signal. Or the third dividing means comprises: an AND gate for making the control signal provided from the synchronizing means a first input; A first D flip-flop for outputting the AND gate as an input signal, inputting the input clock signal as a clock signal, and providing an inverted output thereof to a second input of the AND gate; A noah gate having the output of the first D flip-flop as one input; And an output signal of the NOR gate as an input signal, the clock input signal as a clock signal, and an output signal of the NOR gate as a clock signal divided by two or three, and at the same time, the third input and the noah of the AND gate. A clock signal generation circuit is provided, comprising a 2D flip-flop for providing with a gate type force.

In the above two or three division means, when the control signal is in the low state, the first D flip-flop does not affect the two-division operation, and the output of the second D flip-flop is in the first state and the high state in the low level. Move to the second state and divide the input clock signal into two, or if the control signal is in the high state, divide into three through the first and second D flip-flops so that its output is in the first state at the low level, the second state at the high level, The apparatus may move to the third low level state and divide the input clock signal into three divisions.

The clock signal generation circuit generates an output signal of 9.8304Mhz by dividing an input clock signal of 19.69Mhz by 512/1025.

The control signal generating means comprises a 9-bit counter which counts the output signal of the 2 or 3 division means at the falling edge of the output clock signal of the 2 or 3 division means, and the 512th output clock from the 2 or 3 division means. The second control signal is generated when a signal is input.

The second or third dividing means divides two times until the 1022th input clock signal is applied to generate the 511th output clock signal, and divides the second or third division to generate a 512th output clock signal when 1023 to 1025th input clock signal are applied. It features.

The synchronizing means may be implemented as a flip-flop which provides the first control signal by synchronizing the second control signal at a falling edge of the input clock signal.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the accompanying drawings in order to describe the present invention in more detail.

4 is a block diagram of a clock generation circuit capable of dividing 512/1025 according to an embodiment of the present invention.

Referring to FIG. 4, the clock generation circuit capable of dividing 512/1025 according to an embodiment of the present invention divides the input clock signal, for example, the input clock signal clk of 19.68Mhz by two divisions according to the control signal DDiv3En. 2 or 3 divider means 100 for generating the divided or 3 divided clock signal CLKout by 3 division and the output signal CLKout of the 2 or 3 divider means 100 are counted and controlled. The control signal generating means 200 for generating the signal Div3En and the control signal Div3En outputted from the control signal generating means 200 in synchronization with the input clock signal clk for the second or third division means. Synchronizing means 300 for providing as control signal DDiv3En of 100 is provided.

The operation of the clock generation circuit of the present invention having the configuration as described above will be described with reference to FIG.

When a clock signal of 19.68Mhz is applied as the input clock signal clk, the dividing or tri-dividing means 100 divides the input clock signal clk into two at the rising edge of the clock input signal to generate the clock signal CLKout. do.

The clock signal CLKout output from the second or third division means 100 is provided to the control signal generating means 200. The second or third division means 100 is applied when the 1022th input clock signal clk is applied. Up to 511 output signals CLKout are generated.

Therefore, the control signal generating means 200 generates the control signal Div3En by counting the clock signal CLKout output from the dividing means 100 at the falling edge of the clock signal CLKout. The means 200 counts the clock signal CLKout of the second or third division means 100 and generates a high control signal Div3En when the 511 th clock signal is applied.

The control signal Div3En generated from the control signal generating means 200 is input to the synchronizing means 300, and the synchronizing means 300 receives the control signal Din3En at the falling edge of the input clock signal clk. Synchronization is provided as a control signal DDiv3En of the two or three division means 100.

Therefore, the two or three division means 100 divides the input clock signal clk by three when the high state control signal DDin3En is applied from the synchronization means 300. In other words, the second or third division means 100 receives the control signal DDin3En in the low state from the synchronization means 300 until the 1022th input clock signal clk is applied to generate the 511th output clock signal CLKout. Is applied to perform a two-dividing operation, and when the 1023th input clock signal clk is applied, it is generated from the control signal generating means 200 and is in a high state synchronized with the input clock signal through the synchronizing means 300. When the control signal DDin3En is input, the input clock signal clk is divided by three. Accordingly, since the second or third division means 100 generates one output clock signal, that is, the 512th (CLKout) while the 1023th to 1025th clock signals are applied, the clock generation circuit of the present invention generates an input clock of 19.68Mhz. The signal clk is divided by 512/1025 to generate an output clock signal CLKout of 9.8304Mhz.

In the clock signal generation circuit of the present invention, a reset signal RST is provided to the two or three division means 100, the control signal generation means 200, and the synchronization means 300, respectively.

Hereinafter, the configuration and operation of two or three division means 100, control signal generation means 200, and synchronization means 300 of the clock generation circuit of the present invention will be described with reference to FIGS. .

Fig. 5 shows a detailed view of the two or three division means 100 in the clock generation circuit of the present invention.

Referring to FIG. 5, the two or three division means 100 includes an AND gate 101 having a control signal DDiv3En generated from the synchronization means 300 as a first input, and an AND gate 101 of the AND gate 101. A D flip-flop 102 and the flip-flop 102 for providing an output as an input signal, inputting the input clock signal clk as a clock signal, and providing an inverted output thereof to a second input of the AND gate 101. The output signal of the NOR gate 103 and the output signal of the NOR gate 103 are input signals, and the clock input signal clk is input as a clock signal, and the output signal thereof is divided into two divisions or And a D flip-flop 104 for outputting as a three-divided clock signal CLKout and providing the third input of the AND gate 101 and the type force of the NOR gate 103. At this time, the reset signal RST is applied to the reset terminals of the D flip-flops 102 and 104.

The operation of the two or three dispensing means 100 having the above configuration will be described below with reference to the operation waveform diagrams of FIGS. 6 and 7.

First, when the two-division or tri-division means 100 performs the two-division operation, when the low state control signal DDiv3En is applied from the synchronization means 300, the output of the AND gate 101 is low. Since it is applied to the input terminal D of the D flip-flop 102, the D flip-flop 102 does not affect the dividing operation of the input clock signal clk.

Since the D flip-flop 102 has its output signal Q applied to the input terminal D through the OR gate 103, the D flip-flop 102 is triggered at the rising edge of the input clock signal clk. The input clock signal clk generates an output clock signal CLKout divided by two.

In other words, when the control signal DDiv3En is in the low state, as shown in FIGS. 6 and 8, the 2 or 3 division means 100 receives the 1022th input clock signal (if the reset signal RST is not 0). Until clk) is inputted, the two-dividing operation is performed while moving to S0 and S1.

On the other hand, when the second or third division means 100 performs a three division operation, when the high state control signal DDiv3En is applied from the synchronization means 300, the output of the AND gate 101 is in a high state. D flip-flops 102 and 103 perform a three-division operation while moving to S0, S1, and S2 from the 1023 th to 1025 th input clock signal clk, since they are applied to one input of the AND gate 101. Done.

Therefore, the 2 or 3 division circuit divides the input clock signal clk into 2 by the control signal DDiv3EN in the low state until the 1022th input clock signal clk, as shown in FIG. When CLKout is generated and the 1023th input clock signal clk is input, the 512th output clock signal CLKout is divided by three divisions from the 1023th to 1025th input clock signal clk by the high state control signal DDiv3En. Will occur).

FIG. 8 illustrates an example in which the control signal generator 200 of FIG. 4 is implemented with a 9-bit counter and a logic circuit.

Referring to FIG. 8, the control signal generating means 200 is composed of nine D flip-flops 201-209 and a 9-bit counter 220 composed of logic gates to output the two or three division means 100. Triggered on the falling edge of the clock signal CLKout to count the output clock signal CLKout from the two or three division means 100.

The control signal generating means 200 generates a low state control signal Div3En until the 511 th output clock signal CLKout is applied, and when the 511 th output clock signal CLKout is generated and counts, Generate a control signal Div3En.

The synchronizing means 300 synchronizes the control signal Div3En generated from the control signal generating means 200 at the falling edge of the input clock signal clk to the control signal DDiv3En by two or three division means 100. ) And a flip-flop (not shown).

Therefore, as shown in FIG. 7, the two or three division means 100 is inputted in synchronization with the falling edge of the input clock signal clk by inputting the control signal Div3En generated from the control signal generating means 200. Is provided as a control signal DDiv3En for controlling the two-division or three-division operation.

As described above, the clock generation circuit of the present invention is not only non-integer division such as 512/1025 division of the input clock signal clk, but also even division, three division, and five division (2 division, 4 division, ...). It can also be used for integer division of even divisions such as one division + one division three times), seven divisions (two division two times + one division three) ...

According to the clock generation circuit of the present invention as described above, there is an advantage of simplifying the circuit configuration by configuring a 9-bit counter with nine D flip-flops. In addition, the clock generation circuit of the present invention is capable of even and odd division as well as non-integer division, which is applicable to integer division.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

Claims (10)

delete delete Two or three division means for receiving an input clock signal having a predetermined frequency and dividing two or three at the first edge of the input clock signal according to a first control signal to generate an output clock signal; Control signal generating means for generating a second control signal by counting an output clock signal of said two or three division means; And Synchronizing means for synchronizing the second control signal output from the control signal generating means to the second or third division means as the first control signal in synchronization with the second edge of the input clock signal, The two or three dispensing means, An AND gate which uses the control signal provided from the synchronization means as a first input; A first D flip-flop for outputting the AND gate as an input signal, inputting the input clock signal as a clock signal, and providing an inverted output thereof to a second input of the AND gate; A noah gate having the output of the first D flip-flop as one input; And The output signal of the NOR gate is used as an input signal, and the clock input signal is input as a clock signal, and the output signal thereof is output as a clock signal divided by two or three. And a 2D flip-flop for providing with a type force of. The method of claim 3, When the control signal is in the low state, the 1D flip-flop does not affect the dividing operation, and the output of the 2D flip-flop moves to the low state first state and the high state second state so that the input clock signal is 2 A clock signal generation circuit characterized by dividing. The method of claim 3, When the control signal is in the high state, it is divided into three through the first and second D flip-flops, and its output is moved to the first state of the low level, the second state of the high level, and the third state of the low level so that the input clock signal is divided into three. A clock signal generation circuit characterized by dividing. The method of claim 3, The clock signal generation circuit divides the input clock signal of 19.69Mhz by 512/1025 and generates an output signal of 9.8304Mhz. The method of claim 6, And the control signal generating means comprises a 9-bit counter for counting the output signal of the two or three division means at the falling edge of the output clock signal of the two or three division means. The method of claim 7, wherein And the control signal generating means generates the second control signal when the 512th output clock signal is inputted using the output clock signal of the second or third division means as a count. The method of claim 8, The second or third dividing means divides two times until the 1022th input clock signal is applied to generate the 511th output clock signal, and divides the second or third division to generate a 512th output clock signal when 1023 to 1025th input clock signal are applied. Characterized in that the clock generating circuit. The method of claim 3, And the synchronization means includes a flip-flop for outputting the first control signal by synchronizing the second control signal generated from the control signal generation means at the falling edge of the input clock signal.