JP2001156618A - Slew rate controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a slew rate controller that is hardly susceptible to the effect of noise and stabilizes the slew rate. SOLUTION: An AND circuit 322 ANDs a pulse signal from a pulse generating circuit 320 and a clock signal from a PLL circuit 321 and provides an output of an AND signal, and a frequency divider circuit 323 receives the AND signal and generates frequency divider circuit output signals with different frequencies. Exclusive OR circuits 324-326 generate control signals from the frequency divider circuit output signals and a data signal. Furthermore, an impedance control circuit 20 generates a control signal. The various control signals are used to control output buffers 1-13. The outputs from the control output buffers 1-13 are given to an output terminal 15 and to a termination resistor 16. A termination voltage 17 is applied to a termination resistor 16.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a slew rate control device, and more particularly to a slew rate control device in which a plurality of output buffers having different impedance values are incorporated in parallel, and the output buffers are alternately turned on and off during signal transition. And a slew rate control device for controlling rise and fall times of signals.

[0002]

2. Description of the Related Art As the speed of a bus increases, it has become an important issue to reduce waveform distortion generated in the bus.
In order to speed up the bus, it is desirable to use an output buffer having an optimum impedance for the bus. If an output buffer with an excessively low impedance is used, the reflection noise generated on the bus becomes large, and if an impedance with a high impedance is selected, the time for switching the bus potential becomes slow due to a low current drawing ability. .

However, the output impedance does not always become the target value in the design due to manufacturing variations of LSIs, changes in temperature and power supply voltage.

For this reason, a plurality of impedances are provided in the LSI (in the LSI, the impedance is changed by changing the physical size of the transistor, and thus may be called “transistor size” or simply “size”).
There is a technique called "impedance control" in which an output buffer having a "?" Is connected in parallel and some (or all) of the buffers are enabled to obtain a desired impedance.

It is also very effective to reduce reflection noise caused by impedance mismatch generated at a connection point of a bus by a technique called “slew rate control”.

Generally, the slew rate control is realized by dulling the input signal at the last stage of the output buffer. However, if noise is applied to a blunt waveform, the timing exceeding the threshold voltage changes. It is difficult to keep the output slew rate constant.

Further, when the slew rate control is performed in an open drain type bus format such as GTL, the slew rate is controlled depending on the impedance of the output buffer even if the same input signal of the final stage of the output buffer is applied. There is a problem that it changes greatly.

In an open drain type bus, when the bus signal falls, the output transistor is turned on, the output impedance changes from infinity to a certain value, and switching is performed by drawing current from the bus. When the signal is low, the ability to draw current is high, so that even when an input signal having the same waveform rounding is given, the falling slew rate is increased.

Conversely, when the bus signal rises, if the output impedance is low, the rising slew rate becomes slow because of the high ability to draw current.

For example, the technique described in Japanese Patent Application Laid-Open No. 11-17516 is a technique for controlling a slew rate by devising connection of an output buffer.

[0011]

SUMMARY OF THE INVENTION The above-mentioned "Japanese Patent Application Laid-Open
The technology described in US Pat. No. 17,516, has a disadvantage that it is easily affected by noise because the slew rate is reduced.

An object of the present invention is to use a PLL circuit and a frequency divider circuit, connect output buffers having different impedance values in parallel, improve the slew rate, and realize a slew rate control device which is less affected by noise. It is to be.

[0013]

According to a first aspect of the present invention, a slew rate control device includes a phase lock loop circuit for generating a clock signal, and a clock signal from the phase lock loop circuit which is divided to have different frequencies. A frequency divider circuit for generating a first frequency divider circuit output signal, a second frequency divider circuit output signal, and a third frequency divider circuit output signal, and exclusive use of a data signal and the first frequency divider circuit output signal A first exclusive-OR circuit for generating an exclusive-OR and outputting it as a first control signal, and an exclusive-OR of the data signal and the output signal of the second frequency-dividing circuit. A second exclusive-OR circuit for outputting as a control signal of the third and a third exclusive-OR circuit for generating an exclusive OR of the data signal and the output signal of the third frequency-dividing circuit and outputting the result as a third control signal An exclusive OR circuit and the data As it is the output of the signal, or,
An impedance control circuit for controlling whether to output a [low] level signal as a fourth control signal, and an open-drain type transistor. The first control signal is input to a gate terminal, and the source terminal is A first output buffer to be grounded, and an open-drain transistor; a second output buffer to input the second control signal to a gate terminal and to ground a source terminal; and an open-drain transistor And
A third output buffer for inputting the third control signal to a gate terminal and grounding a source terminal, and an open-drain transistor; inputting the fourth control signal to a gate terminal; An output terminal for connecting an impedance adjustment output buffer to be grounded, an output terminal for connecting the first output buffer, the second output buffer, the third output buffer, and a drain terminal of the impedance adjustment output buffer; And a termination voltage connected to the termination resistor.

[0014] A second slew rate control device of the present invention is the first slew rate control device, which detects rising and falling of the data signal and outputs the clock signal from the phase lock loop circuit. A pulse generation circuit for generating a pulse signal of a constant width for making a certain number of valid signals, an AND signal of the clock signal from the phase lock loop circuit, and the pulse signal from the pulse generation circuit. An AND circuit, and dividing the AND signal from the AND circuit, the first divider output signal, the second divider output signal, and the third divider having different frequencies. The frequency divider circuit for generating a circuit output signal.

[0015] A third slew rate control device of the present invention is the second slew rate control device, wherein the data signal is input, the first frequency divider circuit output signal from the frequency divider circuit, A delay element that outputs the data signal with a delay for a fixed time in order to synchronize with the second frequency divider circuit output signal and the third frequency divider circuit output signal; and a data signal from the delay element and the first signal. The first exclusive OR circuit for generating an exclusive OR with the frequency divider output signal of
The second exclusive-OR circuit for generating an exclusive-OR of the data signal from the delay element and the output signal of the second frequency-dividing circuit and outputting the result as a second control signal; And the third exclusive OR circuit that creates an exclusive OR of the data signal from the third and the third frequency divider circuit output signal and outputs it as a third control signal.

A fourth slew rate control device of the present invention is the third slew rate control device, wherein the first slew rate control device is synchronized with the first control signal, the second control signal, and the third control signal. 4. The apparatus according to claim 3, further comprising: the impedance control circuit including a delay circuit for outputting the fourth control signal.
The described slew rate control device.

A fifth slew rate control device of the present invention is the fourth slew rate control device, wherein the impedance value of the first output buffer, the impedance value of the second output buffer, and 3 is a combination of the impedance value of the first output buffer, the impedance value of the second output buffer, and the impedance value of the third output buffer, and the second output buffer And the third impedance value
A combined impedance value of the impedance values of the output buffers, a combined impedance value of the impedance values of the first output buffer, and the impedance value of the third output buffer, an impedance value of the third output buffer, The impedance value of the output buffer, the combined impedance value of the impedance values of the second output buffer, the impedance value of the second output buffer, and the impedance value of the first output buffer are sequentially larger. 5. The slew rate control device according to claim 4, wherein:

A sixth slew rate control device according to the present invention is the third, fourth, or fifth slew rate control device, wherein the pulse generation circuit, the phase lock loop circuit, the logical product circuit,
The frequency divider, the first exclusive OR circuit, the second
, And the third exclusive OR circuit are constituted by one chip.

[0019]

Next, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of the present invention. Referring to FIG.
In the embodiment of the present invention, an output buffer 11, an output buffer 12, an output buffer 13, an output buffer 14 for impedance adjustment, and an output terminal 15 are four transistors of an open drain type having different impedance values.
, An impedance control circuit 20, and a slew rate control circuit 30 for controlling gate input signals of the output buffers 11 to 13.

The impedance value R of the output buffer 11
1, the magnitude of the impedance value R2 of the output buffer 12 and the magnitude of the impedance value R3 of the output buffer 13 are determined by the output buffer 11, the output buffer 12, and the output buffer
(R1>R2> R3). Further, the impedance value R4 of the impedance adjustment output buffer 14 is
It is set appropriately.

The slew rate control circuit 30 includes a data input terminal 301, a data output terminal 302, a control signal output terminal 311, a control signal output terminal 312, a control signal output terminal 313, a pulse generation circuit 320, A PLL circuit 321, which is a lock loop circuit, an AND circuit 322, a frequency dividing circuit 323, an exclusive OR circuit 324, an exclusive OR circuit 325, an exclusive OR circuit 326, and a delay element 327. Consists of

The outputs of the exclusive-OR circuit 324, the exclusive-OR circuit 325, and the exclusive-OR circuit 326 are output to the control signal output terminal 311 and the control signal output terminal 3 respectively.
12 and a control signal output terminal 313.

The source terminals of the output buffers 11 to 13 and the output buffer 14 for impedance adjustment are
The outputs are all connected, and a terminating resistor 16, an external input terminal (not shown),
Connected to an output terminal (not shown). In addition, termination resistor 1
A termination voltage 17 is applied to 6.

The output buffers 11 to 1
3. The gate terminals of the impedance adjustment output buffer 14 are connected to the impedance control circuit 20 respectively.
Output, control signal output terminal 311, control signal output terminal 3
12, connected to the control signal output terminal 313. The outputs of the drain terminals of the output buffers 11 to 13 and the output buffer for impedance adjustment 14 are the output of the impedance control circuit 20, the output of the control signal output terminal 311 and the output of the control signal output terminal 312, respectively.
When the output of the control signal output terminal 313 is "high", it is at the ground level, that is, "low".

Output buffer 11 to output buffer 1
3. The outputs of the drain terminals of the impedance adjustment output buffer 14 are the output of the impedance control circuit 20, the output of the control signal output terminal 311, the output of the control signal output terminal 312, and the output of the control signal output terminal 313, respectively. ”, The level of the terminal voltage 17 via the terminal resistor 16, that is,“ high ”.

Therefore, the voltage level at the output terminal 15 is determined by all the states of the inputs of the gate terminals of the output buffers 11 to 13 and the output buffer 14 for impedance adjustment.

The pulse generation circuit 320 detects a rising or falling edge of a data signal from the data input terminal 301 and outputs a "high" pulse for a predetermined time. The pulse width is set to four cycles of the output of the frequency divider circuit of the PLL circuit 321.

The PLL circuit 321 autonomously sets “high”.
And the output of the frequency dividing circuit which repeats "low".

The AND circuit 322 includes the pulse generation circuit 32
A logical product signal of the output of 0 and the output of the PLL circuit 321 is created and output.

The frequency dividing circuit 323 receives the logical product signal from the logical product circuit 322, outputs the frequency dividing circuit output signal (f) as it is, and the frequency dividing circuit output signal whose "high / low" frequency is 1/2. (F / 2) and a frequency divider circuit output signal (f / 4) having a “high / low” frequency of １ ／.

The exclusive-OR circuit 324, the exclusive-OR circuit 325, and the exclusive-OR circuit 326 output the data signal from the data input terminal 301, the frequency divider output signal (f), and the frequency, respectively. A 1/2 frequency divider output signal (f
/ 2), frequency divider circuit output signal (f / 4) whose frequency is 1/4
Is generated and output as a control signal.

The delay element 327 is connected to the data input terminal 301
Is provided for synchronizing the data signal from the output with the output of the frequency dividing circuit 323.

The impedance control circuit 20
For example, it includes a logical product circuit that generates a logical product signal of the adjustment signal from the impedance adjustment terminal 201 and the data signal from the data output terminal 302. When the adjustment signal from the impedance adjustment terminal 201 is “high”, the data signal Is output as it is, and when the adjustment signal from the impedance adjustment terminal 201 is “low”, “low” is output. Further, it includes a delay element, and is configured to output a control signal in synchronization with the output of the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326 from the data signal.

Next, the operation of the embodiment of the present invention will be described with reference to the drawings. First, the rising operation will be described. FIGS. 2 and 3 are time charts showing the rising operation of the embodiment of the present invention. Referring to FIG. 2 and FIG. 3, the PLL circuit 321 has a constant cycle,
A clock signal is output by repeating “high / low” (FIG. 2, FIG. 3, T11, T16, T21, T26, T31, T31).
36, T41, T46, T51).

The data signal of the data input terminal 301 is
When it becomes “low” (T0 in FIG. 2), the pulse generation circuit 320
Are output for a certain period of time (FIG. 2T10 to FIG. 3T47). Next, the logical product circuit 322 generates and outputs a logical product signal of the pulse output from the pulse generation circuit 320 and the clock signal output from the PLL circuit 321. The waveform of the AND signal is the same as that of the clock signal, and repeats “high / low” (FIG. 2, FIG. 3, T12, T17, T22,
T27, T32, T37, T42, T47).

Next, the frequency dividing circuit 323 is connected to the AND circuit 32.
2 to frequency divider circuit output signal (f), frequency is 1/2
And outputs a frequency divider circuit output signal (f / 4) having a frequency of 1/4.

The output of the delay element 327 receives the data signal, delays the data signal, and outputs the data signal ("T" at T13 in FIG. 2).

The frequency divider output signal (f), the frequency divider output signal (f / 2), and the frequency divider output signal (f / 4) are "low".
Until the time point (T13 in FIG. 2), the output of the delay element 327 is “high”, and the control signals from the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326 are “ High ”(until T14 in FIG. 2). Further, the frequency divider output signal (f), the frequency divider output signal (f /
2) When the frequency divider circuit output signal (f / 4) becomes “high” (T13 in FIG. 2), the output of the delay element 327 is “low”, and the exclusive OR circuit 324 and the exclusive OR circuit 32
5 and the control signal from the exclusive OR circuit 326 are:
It is also "high" (T14 in FIG. 2).

The impedance control circuit 2
In the case of 0, the adjustment signal from the impedance adjustment terminal 201 is “low”, and the output control signal remains “low” (shown by a solid line in FIG. 2).

Therefore, exclusive OR circuit 324, exclusive OR circuit 325, and exclusive OR circuit 326
Control signals are “high”, “high”,
"High" (T14 to T19 in FIG. 2) and the output terminal 15
Are the output buffer 11 and the output buffer 1
2. The parallel combined impedance of the output buffer 13 is L
1 = (R1 * R2 * R3) / (R1 * R2 + R2 * R3
+ R3 * R1) (FIG. 2: T15 to T2)
0).

Next, the frequency divider circuit output signal (f) becomes "low".
(T18 in FIG. 2), the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326
Control signals are “low”, “high”,
"High" (T19 to T24 in FIG. 2) and the output terminal 15
Are the output buffer 11 and the output buffer 1
2. The parallel combined impedance of the output buffer 13 is L
2 = (R2 * R3) / (R2 + R3) (FIGS. 2T20 to T25).

Next, when the frequency divider circuit output signal (f) becomes "high" and the frequency divider circuit output signal (f / 2) becomes "low" (T23 in FIG. 2), the exclusive OR circuit 324, the exclusive logic The control signals from the sum circuit 325 and the exclusive OR circuit 326 are “high”, “low”, and “high”, respectively (T24 to T29 in FIG. 2), and the voltage level of the output terminal 15 is , Output buffer 12, and output buffer 13 have a parallel combined impedance of L3 = (R3 *
R1) / (R3 + R1) (T25 in FIG. 2)
~ T30).

Next, the frequency divider circuit output signal (f) becomes "low".
(T28 in FIG. 2), the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326
Control signals are “low”, “low”,
2 (T29 to FIG. 3T34), the voltage level of the output terminal 15 is the parallel combined impedance of the output buffer 11, the output buffer 12, and the output buffer 13.
L4 = R3 (FIGS. 2T30 to 3T3)
5).

Next, when the frequency dividing circuit output signal (f) becomes "high", the frequency dividing circuit output signal (f / 2) becomes "high", and the frequency dividing circuit output signal (f / 4) becomes "low". (FIG. 3T3
3), exclusive OR circuit 324, exclusive OR circuit 32
5 and the control signal from the exclusive OR circuit 326 are:
They are "high", "high", and "low", respectively (Fig. 3
T34 to T39), the voltage level of the output terminal 15 is: the parallel combined impedance of the output buffer 11, the output buffer 12, and the output buffer 13 is L5 = (R1 * R2) /
(R1 + R2) (FIG. 3: T35 to T4)
0).

Next, the frequency divider circuit output signal (f) becomes "low".
(T38 in FIG. 3), the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326
Control signals are “low”, “high”,
"Low" (T39 to T44 in FIG. 3) and the output terminal 15
Are the output buffer 11 and the output buffer 1
2. The parallel combined impedance of the output buffer 13 is L
6 = R2 (T40 to T45 in FIG. 3).

Next, when the frequency divider circuit output signal (f) becomes "high" and the frequency divider circuit output signal (f / 2) becomes "low" (T43 in FIG. 3), the exclusive OR circuit 324, the exclusive logic The control signals from the sum circuit 325 and the exclusive OR circuit 326 are “high”, “low”, and “low”, respectively (T44 to T49 in FIG. 3), and the voltage level of the output terminal 15 is , Output buffer 12 and output buffer 13 are determined by L7 = R1 (T45 to T50 in FIG. 3).

Next, the frequency divider circuit output signal (f) becomes "low".
(T48 in FIG. 3), the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326
Control signals are “low”, “low”,
The voltage level of the output terminal 15 is "low", and the parallel combined impedance of the output buffer 11, the output buffer 12, and the output buffer 13 is determined by L8 = infinity (from T50 in FIG. 3).

L1 <L2 <L3 <L4 <L5 <L6 <L
7, the impedance values R1, R2, and R3 are set, and the waveform of the output terminal 15 is as shown in FIGS. 2 and 3 (shown by solid lines in FIGS. 2 and 3).

Next, the fall operation will be described. FIGS. 4 and 5 are time charts showing the fall operation of the embodiment of the present invention. Referring to FIG. 4 and FIG. 5, the PLL circuit 321 repeats “high / low” at a constant cycle and outputs a clock signal (FIGS. 4 and 5T).
11, T16, T21, T26, T31, T36, T4
1, T46, T51).

The data signal of the data input terminal 301 is
When it becomes "high" (T0 in FIG. 4), the pulse generation circuit 320
Are output for a certain period of time (FIG. 4T10 to FIG. 5T47). Next, the logical product circuit 322 generates and outputs a logical product signal of the pulse output from the pulse generation circuit 320 and the clock signal output from the PLL circuit 321. The waveform of the AND signal is the same type as the clock signal, and repeats “high / low” (FIG. 4, FIG. 5, T12, T17, T22,
T27, T32, T37, T42, T47).

Next, the frequency dividing circuit 323 is connected to the AND circuit 32.
2 to frequency divider circuit output signal (f), frequency is 1/2
And outputs a frequency divider circuit output signal (f / 4) having a frequency of 1/4.

The output of the delay element 327 receives a data signal, delays the data signal, and outputs it ("T" in FIG. 4T13).

The frequency divider output signal (f), the frequency divider output signal (f / 2), and the frequency divider output signal (f / 4) are "low".
Until the time point (T13 in FIG. 4), the output of the delay element 327 is “low”, and the control signals from the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326 are “ Low "(until T14 in FIG. 4). Further, the frequency divider output signal (f), the frequency divider output signal (f /
2) When the frequency divider output signal (f / 4) becomes “high” (T13 in FIG. 4), the output of the delay element 327 is “high”, and the exclusive OR circuit 324 and the exclusive OR circuit 32
5 and the control signal from the exclusive OR circuit 326 are:
It is also "low" (T14 in FIG. 4).

The impedance control circuit 2
In the case of 0, the adjustment signal from the impedance adjustment terminal 201 is “low”, and the output control signal remains “low” (shown by a solid line in FIG. 4).

Therefore, exclusive OR circuit 324, exclusive OR circuit 325, and exclusive OR circuit 326
Control signals are “low”, “low”,
"Low" (T14 to T19 in FIG. 4) and the output terminal 15
Are the output buffer 11 and the output buffer 1
2. The parallel combined impedance of the output buffer 13 is L
8 = determined by infinity (FIGS. 4T15 to T20).

Next, the frequency dividing circuit output signal (f) becomes "low".
(T18 in FIG. 4), the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326
Control signals are “high”, “low”,
"Low" (FIGS. 4T19 to T24), and the output terminal 15
Are the output buffer 11 and the output buffer 1
2. The parallel combined impedance of the output buffer 13 is L
7 = R1 (FIGS. 4T20 to T25).

Next, when the frequency dividing circuit output signal (f) becomes "high" and the frequency dividing circuit output signal (f / 2) becomes "low" (T23 in FIG. 4), the exclusive OR circuit 324, the exclusive logic The control signals from the sum circuit 325 and the exclusive OR circuit 326 are “low”, “high”, and “low”, respectively (T24 to T29 in FIG. 4), and the voltage level of the output terminal 15 is , The output buffer 12, and the parallel combined impedance of the output buffer 13 are determined by L6 = R2 (T25 to T30 in FIG. 4).

Next, the frequency divider circuit output signal (f) becomes "low".
(T28 in FIG. 4), the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326
Control signals are “high”, “high”,
"Low" (FIGS. 4T29 to T34) and the output terminal 15
Are the output buffer 11 and the output buffer 1
2. The parallel combined impedance of the output buffer 13 is L
5 = (R1 * R2) / (R1 + R2) (FIG. 4T30 to FIG. 5T35).

Next, when the frequency dividing circuit output signal (f) becomes "high", the frequency dividing circuit output signal (f / 2) becomes "high", and the frequency dividing circuit output signal (f / 4) becomes "low". (FIG. 5T3
3), exclusive OR circuit 324, exclusive OR circuit 32
5 and the control signal from the exclusive OR circuit 326 are:
They are “low”, “low”, and “high”, respectively (FIG. 5).
T34 to T39), the voltage level of the output terminal 15 is determined by the parallel combined impedance of the output buffer 11, the output buffer 12, and the output buffer 13 by L4 = R3 (FIGS. 5T35 to T40).

Next, the frequency divider circuit output signal (f) becomes "low".
(T38 in FIG. 5), the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326
Control signals are “high”, “low”,
“High” (FIG. 5: T39 to T44) and the output terminal 15
Are the output buffer 11 and the output buffer 1
2. The parallel combined impedance of the output buffer 13 is L
3 = (R3 * R1) / (R3 + R1) (FIGS. 5T40 to T45).

Next, when the frequency divider circuit output signal (f) becomes "high" and the frequency divider circuit output signal (f / 2) becomes "low" (T43 in FIG. 5), the exclusive OR circuit 324, the exclusive logic The control signals from the sum circuit 325 and the exclusive OR circuit 326 are “low”, “high”, and “high”, respectively (T44 to T49 in FIG. 5), and the voltage level of the output terminal 15 is , Output buffer 12, and output buffer 13 have a parallel combined impedance of L2 = (R2 *
R3) / (R2 + R3) (FIG. 5T45)
~ T50).

Next, the frequency divider circuit output signal (f) becomes "low".
(T48 in FIG. 5), the exclusive OR circuit 324, the exclusive OR circuit 325, and the exclusive OR circuit 326
Control signals are “high”, “high”,
The output terminal 15 has a voltage level of “high” (from T49 in FIG. 5), and the parallel combined impedance of the output buffer 11, the output buffer 12, and the output buffer 13 is L1 = (R
1 * R2 * R3) / (R1 * R2 + R2 * R3 + R3 *
R1) (FIG. 5T50-).

L1 <L2 <L3 <L4 <L5 <L6 <L
7, the impedance values R1, R2, and R3 are set, and the waveform of the output terminal 15 is as shown in FIGS. 4 and 5 (shown by solid lines in FIGS. 4 and 5).

Next, the impedance control circuit 2
The case where the adjustment signal from the impedance adjustment terminal 201 is set to “0” at “0” will be described. In this case, the waveform is as shown by the dotted line in FIGS.

In FIG. 2, the output of the impedance control circuit 20 is "high" until T19 in FIG. 2 corresponding to the data signal from the data output terminal 302, and the composite impedance value that determines the waveform of the output terminal 15 is , L0 = (R1 * R2 * R3 * R4) / (R2 * R3
* R4 + R3 * R4 * R1 + R4 * R1 * R2 + R1 *
R2 * R3).

In FIG. 4, the output of the impedance control circuit 20 is “high” from T19 in FIG. 2 in response to the data signal from the data output terminal 302,
The composite impedance value that determines the waveform of the output terminal 15 is
L1 to L7 are values affected by R4. Therefore, it becomes like a dotted line.

In the case of the solid line, although the amplitude of the waveform at the output terminal 15 is small and the power consumption is small, it is easily affected by noise. Further, in the case of the dotted line, the amplitude of the waveform of the output terminal 15 is large and is not easily affected by noise, but the power consumption is large.

By appropriately selecting the adjustment signal of the impedance adjustment terminal 201, it is possible to use the system suitable for the system.

Next, an embodiment will be described. For example, R1 = 70 [Ohm], R2 = 35 [Ohm], R
3 = 17.5 [Ohm], R4 = 7.17 [Ohm],
The impedance RT of the terminating resistor 16 is 20 [ohm],
Assuming that the potential VTT of the termination voltage 17 is 1.5 [volt], L0 = 7.27 [ohm], L1 = 10 [ohm], L2 = 11.67 [ohm], L3 = 14 [ohm], L4 = 17.5 [Ohm], L5 = 23.33
[Ohm], L6 = 35 [Ohm], and L7 = 70 [Ohm].

Therefore, the potential of the output terminal 15 becomes VT
It is calculated by T * (combined impedance) / (RT + (combined impedance)), and V0 = VTT * L0, respectively.
/(RT+L0)=1.5*7.27/(20+7.2)
7) = 0.4 [volt], V1 = VTT * L1 / (RT
+ L1) = 1.5 * 10 / (20 + 10) = 0.5 [volt], V2 = VTT * L2 / (RT + L2) = 1.5
* 11.67 / (20 + 11.67) = 0.55 [volt], V3 = VTT * L3 / (RT + L3) = 1.5 *
14 / (20 + 14) = 0.62 [volt], V4 = V
TT * L4 / (RT + L4) = 1.5 * 17.5 / (2
0 + 17.5) = 0.7 [volt], V5 = VTT * L
5 / (RT + L5) = 1.5 * 23.33 / (20 + 2)
3.33) = 0.81 [volt], V6 = VTT * L6
/(RT+L6)=1.5*35/(20+35)=
0.95 [volt], V7 = VTT * L7 / (RT + L
7) = 1.5 * 70 / (20 + 70) = 1.17 [volt].

When L8 = infinity, the potential of the output terminal 15 is the same as the termination voltage 17, that is, 1.5 [volt].

In the above, three cases have been described as in the case of the output buffers 11 to 13, but any number of one or more may be used. Further, the case where one impedance control circuit 20 and one impedance adjustment output buffer 14 are provided has been described, but any number of one or more impedance control circuits may be used.

Further, for example, if the slew rate control circuit 30 is constituted by one chip, it can be used in many places, and the area can be reduced and the reliability can be improved.

[0074]

The first effect of the present invention is that it is hardly affected by noise.

The reason is that a PLL circuit and a frequency dividing circuit are used to increase the slew rate of each input signal of the final stage output buffer.

The second effect of the present invention is that the slew rate is stabilized.

The reason is that the impedance at a certain point during the rising is fixed because the number of transistors in the ON state is determined and the combined impedance of the output buffer is fixed.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

FIG. 2 is a time chart illustrating an operation of the exemplary embodiment of the present invention.

FIG. 3 is a time chart illustrating an operation of the exemplary embodiment of the present invention.

FIG. 4 is a time chart illustrating an operation of the exemplary embodiment of the present invention.

FIG. 5 is a time chart illustrating an operation of the exemplary embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 11 Output buffer 12 Output buffer 13 Output buffer 14 Output buffer for impedance adjustment 15 Output terminal 16 Termination resistor 17 Termination voltage 20 Impedance control circuit 30 Slew rate control circuit 201 Impedance adjustment terminal 301 Data input terminal 302 Data output terminal 311 Control signal output terminal 312 Control signal output terminal 313 Control signal output terminal 320 Pulse generation circuit 321 PLL circuit 322 Logical product circuit 323 Divider circuit 324 Exclusive OR circuit 325 Exclusive OR circuit 326 Exclusive OR circuit 327 Delay element

Claims (6)

[Claims] A phase-locked loop circuit for generating a clock signal; a frequency-divided clock signal from the phase-locked loop circuit; a first frequency-divided circuit output signal and a second frequency-divided circuit output having different frequencies; A frequency divider for generating a signal, a third frequency divider output signal, and an exclusive OR of a data signal and the first frequency divider output signal, and outputting the result as a first control signal A second exclusive OR circuit for generating an exclusive OR of the data signal and the output signal of the second frequency divider and outputting the same as a second control signal; The data signal and the third
A third exclusive-OR circuit for generating an exclusive-OR with the output signal of the frequency-dividing circuit and outputting the same as a third control signal; Control circuit for controlling whether or not to output the first control signal as a fourth control signal, and an open drain type transistor, wherein the first control signal is input to a gate terminal and the first terminal is connected to a source terminal to ground.
A second output buffer configured to input the second control signal to a gate terminal and grounding a source terminal, and an open drain type transistor; A third output buffer for inputting the control signal of No. 3 to the gate terminal and grounding the source terminal, and an open-drain transistor; inputting the fourth control signal to the gate terminal and grounding the source terminal; An output terminal for connecting an impedance adjustment output buffer, a drain terminal of the first output buffer, the second output buffer, the third output buffer, and a drain terminal of the impedance adjustment output buffer, and a connection to the output terminal And a termination voltage connected to the termination resistor. Control apparatus. 2. A pulse generation circuit for detecting a rising edge and a falling edge of the data signal and generating a pulse signal having a constant width for validating a predetermined number of the clock signals from the phase lock loop circuit. An AND circuit that creates an AND signal of the clock signal from the phase lock loop circuit and the pulse signal from the pulse generating circuit; and dividing the AND signal from the AND circuit to determine the frequency. 2. The frequency divider according to claim 1, further comprising: a frequency divider that generates different first frequency divider output signals, second frequency divider output signals, and third frequency divider output signals. The described slew rate control device. 3. The data signal is inputted and synchronized with the first frequency divider circuit output signal, the second frequency divider circuit output signal, and the third frequency divider circuit output signal from the frequency divider circuit. A delay element that outputs the data signal with a delay of a predetermined time, and an exclusive OR of a data signal from the delay element and the output signal of the first frequency divider circuit is created.
A first exclusive-OR circuit that outputs the first control signal as a control signal, and an exclusive-OR of the data signal from the delay element and the output signal of the second frequency-dividing circuit. The second exclusive-OR circuit outputs the data signal from the delay element and an output signal of the third frequency-dividing circuit, and outputs the result as a third control signal. 3. The slew rate control device according to claim 2, comprising: the third exclusive OR circuit. 4. The fourth control signal is synchronized with the first control signal, the second control signal, and the third control signal.
4. The slew rate control device according to claim 3, further comprising the impedance control circuit including a delay circuit for outputting the control signal. 5. An impedance value of the first output buffer, an impedance value of the second output buffer, and an impedance value of the third output buffer, the impedance value of the first output buffer, the impedance value of the second output buffer, and the impedance value of the second output buffer. , The combined impedance value of the impedance value of the third output buffer, the combined impedance value of the impedance value of the second output buffer, and the combined impedance value of the impedance value of the third output buffer, , The combined impedance value of the impedance value of the third output buffer, the impedance value of the third output buffer, the impedance value of the first output buffer, and the impedance value of the second output buffer. Synthetic impedance value 5. The slew rate control device according to claim 4, wherein the slew rate control device has a value that is larger in the order of the impedance value, the impedance value of the second output buffer, and the impedance value of the first output buffer. 6. The pulse generating circuit, the phase lock loop circuit, the AND circuit, the frequency dividing circuit, the first exclusive OR circuit, the second exclusive OR circuit,
6. The slew rate control device according to claim 3, wherein said third exclusive OR circuit is constituted by one chip.