JP2510415B2 - Electronic clock - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an electronic timepiece having a temperature gradient adjusting circuit of a temperature-compensating electronic timepiece having a temperature-sensitive oscillator formed in a MOS-IC.

<Outline of the Invention> The present invention adds a variable frequency divider circuit for temperature gradient coarse adjustment for variable frequency division of an output signal of a temperature-sensitive oscillator in an electronic timepiece with temperature compensation, and the temperature gradient adjustment circuit is temperature gradient adjustment numerical information. It is possible to widen the temperature gradient adjustment range without lowering the temperature gradient adjustment resolution of the temperature-sensitive oscillator by operating with a value to which a certain amount of numerical value is added.

<Prior Art> Conventionally, there is no variable frequency dividing circuit for coarse adjustment of the temperature gradient between the temperature sensitive oscillator and the temperature gradient adjusting circuit as in Japanese Patent Laid-Open No. 58-223088, and the temperature gradient adjusting circuit has a temperature gradient. It worked only with the adjusted numerical information.

A conventional temperature-sensitive oscillator adjusting method will be described below with reference to the drawings.

FIG. 5 is a block diagram showing the basic configuration of a conventional temperature-sensitive oscillator adjusting method, and is a block diagram when the output signal period τs of the temperature-sensitive oscillator changes linearly with temperature.

The temperature compensation operation will be briefly described with reference to FIG.
The temperature measurement is performed by the control circuit 6 at regular time intervals.
When the time to measure the temperature comes, the control circuit 6 sets the adjustment numerical information B and A in the offset adjustment counter 10 and the gradient adjustment counter 8, respectively, and then the control circuit 6 sets the latch 11 and the AND gate 12. When the signal fc from the frequency dividing circuit 2 starts to be input to the offset adjusting counter 10 through the same, the output signal τs of the temperature-sensitive oscillator 7 starts to be input to the gradient adjusting counter 8 at the same time. The gradient adjusting counter 8 adjusts the numerical information A by the signal τs.
When it counts down only, the 0 detection circuit 9 detects 0, resets the latch 11, and the AND gate 12 inhibits the signal fc from the frequency dividing circuit 2. The temperature information T obtained as a result can be expressed by the following equation.

T = [A · τs · fc] + B−2 ^L · m (1) τs = β · θ · + τ ₀ (2) where L is the number of bits of the offset adjustment counter 10 and m is the number of overflows. Is shown. θ indicates temperature, τ ₀ indicates the cycle at 0 ° C., and β indicates the temperature coefficient. In addition, “[]” indicates a Gauss symbol, which indicates an integerization that means a maximum integer that does not exceed the number in parentheses.

<< Problems to be Solved by the Invention >> In the temperature gradient adjusting circuit configured as described above, the temperature gradient adjustment resolution (1 / A: the reciprocal of the adjustment numerical value information A is set as Had a problem that the value of () was decreased. In other words, there is a problem that the usable temperature gradient adjustment range is narrowed without lowering the temperature gradient adjustment resolution.

Hereinafter, a specific numerical value is substituted into the equations (1) and (2) to find the temperature gradient adjustment range. When a term which depends on the temperature at the temperature information T and T _theta, can be expressed (1) and the T _theta from (2) by the following equation.

T _θ = [Aβfcθ] (3) The appropriate upper limit and lower limit of β, that is, the temperature gradient adjustment range will be calculated by substituting appropriate specific numerical values into the equation (3).

When the temperature θ changes by 102.4 ° C., the temperature information T _θ becomes 1024
If the condition of changing is set, [A · β · fc] = 10 (1 / ° C) (4). Further, when the gradient adjusting counter 8 is a 10-bit counter, the adjustment numerical value information A is also 10 bits. It is assumed that fc uses the frequency divider circuit of 2048 Hz.

When the conditions are set as described above, the adjusted numerical information A is
Since it is 10 bits, it takes an integer value of 0 to 1023, but since it is an integer, a maximum error of 0.5 occurs when adjusting. The influence of the error of 0.5 on the temperature information T _θ and the temperature gradient adjustment resolution increase as the adjustment numerical value information A decreases. For example, the error in the compensation temperature characteristic of the crystal is 0.1 [pp
m] or less, the temperature gradient adjustment resolution is reduced to 1/5.
It must be 12 or less, and the possible range of the adjustment numerical value information A must be 512 to 1023. Therefore, in this case, the adjustable range of the temperature gradient β is β = 4.77 to 9.54 (μsec / ° C.) from the equation (4). Also in this case, when β is 4.77 (μsec / ° C) or less, the adjustment numerical information A becomes 1024 or more and cannot be adjusted, and when β is 9.54 (μsec / ° C) or more, the adjustment numerical information A is
Becomes 511 or less and the adjustment resolution becomes 1/512 or more.

Even if the number of bits of the gradient adjustment counter 8 and the adjustment numerical information A is simply increased in order to widen the adjustable range of the temperature gradient β, it is necessary to lengthen the temperature measurement time or use a higher frequency for fc. However, there was a problem that it was difficult to realize.

<< Means for Solving the Problems >> In order to solve the above problems, in the present invention, a variable frequency divider circuit for temperature gradient coarse adjustment for variable frequency division of the output signal of the temperature sensitive oscillator is added to adjust the temperature gradient. By operating the circuit with a value obtained by adding a certain amount of numerical value to the temperature gradient adjustment numerical information, the temperature gradient adjustment range can be expanded without lowering the temperature gradient adjustment resolution of the temperature-sensitive oscillator. .

<< Operation >> According to the above configuration, it is possible to widen the temperature gradient adjustment range without lowering the temperature gradient adjustment resolution of the temperature-sensitive oscillator.

«Examples» Examples of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the basic configuration of the temperature-sensitive oscillator adjusting device of the present invention.

FIG. 1 shows a configuration in which a variable frequency dividing circuit 13 according to the present invention is added to the configuration of FIG.

The temperature information T in FIG. 1 can be expressed by the following equation.

T = [(A + D) ・ τs ・ 2 ^c・ fc] + B-2 ^L・ m ...
(5) However, τs = β · θ + τo (6)

D34 is a constant numerical value (hereinafter referred to as added numerical value D) added to the temperature gradient adjustment numerical value information A31 (hereinafter referred to as adjusted numerical value A), and C33 is a flip-frequency divider that divides the output signal of the temperature-sensitive oscillator 7 in half. This is temperature gradient coarse adjustment numerical value information (hereinafter referred to as adjustment numerical value C) indicating how many flops are inserted.

2 and 3 are diagrams specifically showing the contents of 4a and 4c in the block diagram of the embodiment of the present invention shown in FIG. 1, and FIG. 4 is for explaining the operation thereof. It is a time chart figure of. In FIG. 2, it is assumed that the temperature-sensitive oscillator 7 has a cycle of its output signal τs that changes linearly with temperature. The output signal .tau.s is input to the frequency dividing stage 50 including seven flip-flops. The selection circuit 40 is composed of eight transmission gates (hereinafter referred to as TG) and a decoder, and is 8 depending on the value set in the 3-bit adjustment value C33.
Only one of the TGs is selected and turned on. The output signal τs1 of the variable frequency divider obtained as a result is expressed by the following equation.

τ _s1 = τ s × 2 ^c (7) On the other hand, in FIG. 3, the adjustment value A31 is composed of 10 bits and takes values from 0 to 1023. The adjustment value A is a 11-bit slope adjustment presettable down counter 8
Lower 10 of input D (hereinafter referred to as slope adjustment counter)
Input to the bit. Since the most significant bit of input D is fixed at "1", the added value D is 1024, and the value preset in the slope adjustment counter is the adjusted value A + 1024.
Becomes The output signal WIND (hereinafter referred to as WIND) from the control circuit 6 and τ _s1 are input to the AND14, and the output of the AND14 is input to φ of the gradient adjusting counter. The 11-bit output Q of the slope adjustment counter is all input to the 0 detection circuit 9
The output of the detection circuit 9 (hereinafter referred to as OUT9) is the RS latch 11
Input to reset. A signal obtained by inverting a 1 Hz output signal 1Q (hereinafter referred to as 1Q) from the frequency dividing stage by the inverter 15 is input to the set of the RS latch 11. The output signal of RS latch (hereinafter referred to as OUT11) and the 2KHz output signal 2KQ (hereinafter referred to as 2KQ) from the dividing stage are input to AND12, and AND12
The output (hereinafter referred to as OUT12) is input to φ of the offset adjustment presettable counter 10 (hereinafter referred to as offset adjustment counter). Offset adjustment numerical information
B32 (hereinafter referred to as adjustment value B) consists of 10 bits and is 0
Takes a value from 1023. The adjustment value B is input to D of the offset adjustment counter composed of 10 bits. The 10-bit output Q of the offset adjustment counter is the temperature information T
Is input to the frequency correction circuit 5.

Next, the operation will be described with reference to the time chart of FIG. When the time to measure the temperature comes, first, the output signal P.SEN is output from the control circuit 6 immediately before the fall of 1Q, and the gradient adjusting counter 8 and the offset adjusting counter 10 are set to the preset state. Further, an output signal P.SCL is output from the control circuit 6, and the adjustment numerical values A and B are preset in the gradient adjusting counter 8 and the offset adjusting counter 10, respectively. Next, at the falling edge of 1Q, OUT11
Rises and 2KQ starts to be input as OUT12 to φ of the offset adjustment counter 10 through AND12. At the same time, WIND rises, and τ _s1 begins to be input to φ of the slope adjustment counter 8 through AND14. When the gradient adjustment counter 8 counts down by the adjustment value A + 1024 by τ _s1 , the 0 detection circuit 9 detects 0 and OUT9 rises. When OUT9 rises, RS latch 11 is reset and OUT11 falls. AND12 when OUT11 falls
Causes 2KQ to be prohibited as shown at OUT12.

Hereinafter, the temperature gradient adjustment range in the case of the present invention will be calculated under the same conditions as in the conventional example. Assuming that the term depending on the temperature in the temperature information T is T _θ , from the equations (5) and (6), T _θ = β × θ × 2 ^c × (A + 1024) × 2048 (10) The temperature θ changes by 102.4 ° C. Temperature information T _θ is 1024
If the same condition as in the conventional example of changing is set, β × 2 ^c × (A + 1024) × 2048 = 10 (1 / ° C.) (11)

Since the possible values of the adjustment numerical values A and C are 0 to 1023 and 0 to 7, respectively, the adjustable range of the temperature gradient β is calculated from the equation (11) and β = 1.86 as shown in FIG. × 10 ^{-2 to} 4.77 (μsec / ° C), which makes it possible to adjust the gradient in a very wide range as compared with the conventional example shown by the broken line in FIG. 6.

Also in the present invention, the adjustment value A takes an integer value, which causes an error of 0.5 at the maximum. The influence of the error of 0.5 on the temperature information T _θ and the temperature gradient adjustment resolution increase as the adjustment numerical value A decreases, as in the case of the conventional example.

However, in the present invention, the gradient adjustment counter operates at a value obtained by adding a certain amount of value D to the adjustment value A. Therefore, in the case of the embodiment of D = 1024, the temperature gradient adjustment is performed even when the adjustment value A is near zero. The resolution is 1/1024 or less.

<< Effects of the Invention >> According to the present invention, the temperature gradient adjustment range can be expanded without lowering the temperature gradient adjustment resolution. In other words, it is possible to adjust even greater variations in the temperature gradient of the temperature-sensitive oscillator that is monolithically integrated into the MOS-IC, which simplifies the design of the temperature-sensitive oscillator and facilitates process control during IC manufacturing. This leads to a reduction in the defective rate and a reduction in man-hours.

[Brief description of drawings]

1 is a block diagram showing an embodiment of the present invention, FIG. 2 is a diagram specifically showing the contents of 4a in FIG. 1, and FIG. 3 is a concrete diagram of the contents of 4c in FIG. FIG. 4 is a time chart diagram for explaining the operation of FIG. 3, FIG. 5 is a block diagram showing a conventional example, and FIG. 6 is an embodiment of the present invention.
It is the figure which showed the relationship between the temperature gradient adjustable range and adjustment numerical values A and C in the figure and FIG. 1 ... Crystal oscillator 2 ... Division circuit 3 ... Driving circuit 4 ... Temperature measuring circuit 5 ... Frequency correction circuit 6 ... Control circuit 7 ... Temperature-sensitive oscillator 8 ... Slope adjustment counter 9 ... 0 Detection circuit 10 …… Offset adjustment counter 13 …… Variable frequency dividing circuit 20 …… Display mechanism 31 …… Temperature gradient fine adjustment numerical information A 32 …… Offset adjustment numerical information B 33 …… Temperature coarse adjustment numerical information C 34 …… Certain amount of numerical value D 40 …… Selection circuit

 ─────────────────────────────────────────────────── ─── Continued Front Page (72) Inventor Hiroyuki Masaki 6-31-1, Kameido, Koto-ku, Tokyo Seiko Electronics Co., Ltd. No. SEIKO ELECTRONICS CO., LTD. (56) Reference JP-A-58-223088 (JP, A) JP-A-59-162478 (JP, A)

Claims (2)

(57) [Claims] 1. A crystal oscillator having a temperature characteristic, a frequency dividing circuit for inputting and dividing an oscillation signal output from the crystal oscillator, and a display mechanism for inputting a frequency dividing signal output from the frequency dividing circuit. A drive circuit that creates a drive signal to drive, a display mechanism that inputs the drive signal output from the drive circuit and displays information such as time, and an output signal cycle corresponding to the temperature condition near the crystal oscillator. Has a temperature sensitive oscillator that linearly changes and a plurality of frequency dividing stages, inputs an output signal of the temperature sensitive oscillator, and outputs n of 2 based on predetermined temperature gradient rough adjustment numerical information.
In addition to dividing the frequency into a power (n is a positive integer greater than or equal to 1), a selection circuit for selecting the divided signal as an output signal is provided, and the temperature gradient of the output signal cycle of the temperature-sensitive oscillator is logically roughened. A variable frequency divider circuit to be adjusted, the output signal of the variable frequency divider circuit is input, and based on the numerical information obtained by adding predetermined temperature gradient fine adjustment numerical information and a predetermined numerical value for compensating the adjustment resolution. A temperature gradient adjusting circuit for logically finely adjusting the temperature gradient of the output signal cycle of the temperature sensitive oscillator by counting the output signals of the variable frequency divider circuit, and the temperature characteristic of the output signal cycle of the temperature sensitive oscillator. Offset adjustment circuit for logically adjusting the offset of the crystal oscillator, temperature compensation of the crystal oscillator based on temperature information created by the temperature gradient adjustment circuit and the offset adjustment circuit based on the output signal of the temperature-sensitive oscillator A frequency correction circuit for performing an electronic timepiece, characterized in that a control circuit for controlling the operation of the content by inputting an output signal of frequency divider said offset adjusting circuit and the temperature gradient adjusting circuit. 2. The electronic timepiece according to claim 1, wherein the predetermined numerical value added to the temperature gradient fine adjustment numerical information is:
An electronic timepiece that is a value obtained by adding 1 to the maximum value of temperature gradient fine adjustment numerical information.