JP4674592B2 - Vehicle shift control device - Google Patents

Description

  The present invention relates to a shift control device that changes the control of the automatic transmission according to a difference in vehicle running resistance during climbing or the like in a vehicle equipped with an automatic transmission, and more specifically, filter processing in the shift control, so-called annealing. It relates to processing control.

  Conventionally, as a shift control device for the automatic transmission, there is one disclosed in Patent Document 1. In the vehicle in which the automatic transmission changes gears according to a shift pattern defined by the vehicle speed and the engine load, the engine load detecting means for detecting the engine load and the torque related to the output torque of the automatic transmission are obtained. Torque detection means for detecting and acceleration detection means for detecting the acceleration of the vehicle are provided, and the shift pattern is changed according to the engine load, output torque and acceleration.

  Specifically, the reference acceleration for the transmission output torque to be obtained on a flat road is obtained, and the reference acceleration is compared with the actual acceleration obtained by the acceleration detecting means, for example, the ratio of the actual acceleration to the reference acceleration. Therefore, the downhill slope of the road on which the vehicle is traveling is estimated, the shift map is switched, and the engine brake is matched.

  When the running resistance is calculated from the vehicle weight in addition to the engine generated torque (transmission input torque) and acceleration, and the running resistance is smaller than a value set in advance by the shift speed, a predetermined engine brake is applied. There has also been devised an automatic transmission control device that commands a gear (see Patent Document 2).

JP-A-61-45160 JP-A-4-4351

  Since the reference acceleration is calculated based on the engine output torque (substantially the same as the transmission output torque due to the difference in the coefficient such as the transmission gear ratio), it is not affected by the vehicle speed and therefore the foot brake, but the actual acceleration is Since it is calculated based on the vehicle speed, it is greatly affected by the driver stepping on the brake.

Accordingly, as shown in FIG. 5, a difference between the reference acceleration α _S and the actual acceleration α _R is generated by the driver's foot brake operation (brake ON), and the road gradient is estimated by comparing both accelerations. The road gradient estimation determination is interrupted while the brake pedal switch is ON. In general, in the above-described shift control of the automatic transmission, the reference acceleration and the actual acceleration are obtained by detecting the engine output torque or the vehicle speed every predetermined time (for example, 100 ms). Each of these detection values varies greatly due to errors and noise, and is subjected to a predetermined filter process, so-called annealing process.

Therefore, as shown by the one-dot chain line in FIG. 5, it is necessary to continue the road gradient determination based on the comparison of the two accelerations for the time corresponding to the response delay time due to the smoothing process, and even after the brake pedal switch is turned off. , forced to set a relatively long delay timer time t _1.

  For this reason, when the foot brake is operated, the downhill road judgment is delayed, and the selection of the shift pattern according to the accurate road gradient is delayed. In particular, as shown in FIG. Thus, if it is repeatedly repeated immediately after the brake is turned off due to a curve or the like, the downhill road cannot be determined, and the shift pattern change control based on the road gradient may not be possible.

On the other hand, as shown in FIG. 9, when a vehicle enters an uphill road and the driver steps on the accelerator pedal, the reference acceleration is affected by an increase in the throttle opening, and the estimation of the road gradient is not possible. allow, even in this case, but stops the determination of the slope condition of the road by a timer constituting the dead zone, the moderation similarly processed, not help setting a long delay timer time t _3.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a vehicle speed change control apparatus that solves the above-described problems by shortening the delay timer time when the driver depresses the accelerator pedal and stops the determination of the road slope condition. And

The present invention according to claim 1 (see FIG. 1) includes a reference acceleration calculation means (11) for calculating a reference acceleration in a flat road traveling state based on the engine output torque,
Actual acceleration calculation means (12) for calculating actual acceleration based on the vehicle speed;
Road condition determining means (17) for determining the gradient condition of the road by comparing the reference acceleration and the actual acceleration,
In the vehicle shift control device, the shift pattern of the automatic transmission (2) is changed based on the road gradient status by the road status determination means.
Filter means (13) for smoothing the value of the reference acceleration (α _S ) by the reference acceleration calculation means;
A pause means (15) for pausing the determination of the road condition determining means (17) when the value of the reference acceleration is in a state in which the slope condition of the road cannot be determined by the driver's accelerator pedal operation;
The influence of the current actual acceleration value for each control cycle is smaller than the previous value during the pause by the pause means due to the throttle opening increasing and changing due to the driver's depression of the accelerator pedal. Gain changing means (16) for changing the gain of the smoothing process for the reference acceleration (α _S ) by the filter means to be small;
The present invention relates to a vehicle speed change control device.

According to a second aspect of the present invention (see FIGS. 10 and 11), the gain changing means changes the increase of the throttle opening so as to reduce the gain for a predetermined time (t _M ).
The vehicle shift control device according to claim 1, wherein:

According to a third aspect of the present invention (see FIG. 2), the road condition judging means is configured to determine whether the road is a flat road or an uphill road based on the difference (a) between the actual acceleration (α _R ) and the reference acceleration (α _S ). Or downhill, further determine the road slope,
Based on the determination by the road condition determination means, a flat road map, an uphill road map, and a downhill road map are selected.
The vehicle shift control device according to claim 1 or 2, wherein

According to a fourth aspect of the present invention (see FIG. 3), the flat road map and the uphill road map are composed of shift lines based on vehicle speed and throttle opening,
The uphill road map includes a plurality of types in which the shift line is biased toward the high speed side compared to a flat road map, and these maps are selected based on the determined road gradient. Item 3. A vehicle gear change control device according to Item 3 .

[Action]
Based on the above configuration, for each control cycle, the reference acceleration calculation means (11) calculates the reference acceleration (α _S ) in a flat road running state based on the engine output torque, and the actual acceleration calculation means (12) Based on the above, the actual actual acceleration (α _R ) is calculated. The road condition determination means (17) compares the actual acceleration (α _R ) and the reference acceleration (α _S ) by, for example, the difference between them (a = α _R −α _S ), and the vehicle is flat, uphill or downhill. The road pattern and the road gradient are determined. Based on the determination, for example, a flat road map, an uphill road map, and a downhill road map are selected, and the change pattern is changed according to the road condition.

For example, when the accelerator pedal is stepped on when entering the uphill road, the calculation of the reference acceleration becomes inappropriate, and the determination of the road condition is stopped by the stop means (15) during that time. At this time, since the smoothing process by the filter means (13) is performed when calculating the reference acceleration (α _S ), the response due to the smoothing process is delayed even after the driver's operation is released. The predetermined delay timer is set. The gain changing means (16) changes the gain of the smoothing process in response to the driver's operation, for example, an increase change in the throttle opening, the reference acceleration is returned to the steady state early, and the set time of the delay timer is increased. shorten.

Specifically, when depressing the accelerator pedal on an upward slope, a predetermined time (t _M), to reduce the gain by increasing the coefficient of the previous smoothed value of the processing, the predetermined time (t _M) after Return to normal annealing.

  In addition, although the code | symbol in the said parenthesis is for contrast with drawing, it does not have any influence on the structure of Claim description.

According to the first aspect of the present invention, when the determination of the road gradient condition is stopped by the driver's accelerator pedal operation, even when the vehicle enters an uphill road and the driver steps on the accelerator pedal, for example, it is small. Since the change in the reference acceleration is reduced by the gain smoothing process and the reference acceleration returns to the steady state at an early stage, it becomes possible to shorten the timer time for the pause and to stabilize the slope of the road Based on the situation determination, the shift pattern of the automatic transmission can be changed in accordance with the road gradient situation.

According to the second aspect of the present invention, since the gain is reduced for a predetermined time from the start of the increase change in the throttle opening, the basic acceleration is surely converged to a steady state with simple control, and the quick return is achieved. It is possible to determine the road condition.

According to the third aspect of the present invention, the flat road, the uphill road, and the downhill road are discriminated based on the difference between the actual acceleration and the reference acceleration, the road gradient is also judged, and an appropriate shift map is selected. Thus, accurate shift control according to the road gradient can be performed.

According to the fourth aspect of the present invention, when climbing, it is possible to select a climbing road map corresponding to the road gradient and perform appropriate shift control according to the road gradient.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing an overall outline of a speed change control device according to the present invention, and an automatic engine having a large number of speed stages such as forward speed 4 and reverse speed 1 by changing an engine 1, a torque converter and a transmission path. A transmission (transmission) 2 and an electronic control unit (ECU) 3 that outputs a shift signal to the transmission are provided. Further, a sensor 5 for detecting the engine speed, a sensor 6 for detecting the speed of the input part of the transmission, a sensor 7 for detecting the speed of the output part of the transmission, that is, a vehicle speed, and a throttle opening based on the driver's accelerator pedal operation. And a brake switch 10 for detecting the driver's operation of the foot brake pedal.

The electronic control unit 3 also includes a means 11 for calculating a reference acceleration α _S based on the output torque (ie, engine output torque) of the transmission 2, a means 12 for calculating an actual acceleration α _R based on the actual vehicle speed, and the reference When it becomes impossible to determine road conditions by means of a filter process that absorbs errors and noises in acceleration calculation and actual acceleration calculation, so-called smoothing process 13, and the operation of a driver such as a foot brake pedal or an accelerator pedal. Pausing means 15 for pausing the determination, means 16 for changing the gain of the filtering process (hereinafter referred to as annealing process), or annealing process stopping means 16a for stopping the annealing process itself (ie, setting the gain to 1). When, and by comparing the smoothing process has been the reference acceleration alpha _S and the actual acceleration alpha _R, flat road, uphill, downhill determine Road condition determining means 17 for determining the gradient of one road, shift pattern changing means 19 for selecting a shift map based on the determination, and shift output for outputting a predetermined gear stage signal to the transmission 2 based on the shift map And means 20.

Specifically, the reference acceleration calculation means 11 obtains the engine output torque from the throttle opening by the throttle opening sensor 9 and the engine speed from the E / G rotation sensor 5, and shifts from the input / output speed of the torque converter. A torque ratio is calculated based on the ratio, an input torque of the transmission is obtained from the engine output torque and the torque ratio, and an output torque of the transmission 2 is calculated based on a gear ratio based on the T / M input rotation sensor 6 and the vehicle speed sensor 7. The output torque of the engine 2 in the state where the vehicle is traveling on the flat surface (reference state) from the output torque and a predetermined value consisting of the running resistance on the flat road, the vehicle mass and the driving wheel radius ( Therefore, the reference acceleration α _S based on the automatic transmission output torque) is calculated.

On the other hand, the actual acceleration calculation means 12 calculates the actual acceleration by differentiating the vehicle speed detected by the vehicle speed sensor 7. These reference acceleration and actual acceleration values are calculated every predetermined time, for example, every 100 ms. Since these actual calculated values are values having a large jagged deviation, the filter processing means 13 performs a predetermined annealing process. I do. Here, the annealing process is calculated by adding the previous calculated value obtained by averaging the past detected values instead of directly adopting the detected value at the time of sampling detection at a predetermined time. In this embodiment, when the previous smoothed value is E (n-1) and the actual or reference acceleration based on the current detection is e (n), The acceleration E (n) by the current annealing process is obtained by E (n) = {3 × E (n−1) + e (n)} / 4. In this way, the reference acceleration α _S and the actual acceleration α _R that are updated every predetermined time and subjected to the annealing process are sequentially obtained.

  The gain changed by the gain changing means is a ratio between the current smoothed value and the current detected value in the smoothing process. Specifically, E (n) The coefficient of the current detection value e (n) at the time of determination (1 in the above embodiment) and the coefficient of the value E (n−1) subjected to the previous smoothing process (3 in the above embodiment) are calculated. . In the above embodiment, the gain is [1/4]. For example, when the coefficient of the annealing process E (n-1) is 9 and the coefficient of the detected value e (n) is 1, the gain [1/10] and becomes smaller. In addition, when the previous annealing process E (n-1) is not employed and only the current detection value e (n) is employed, that is, when the annealing process is stopped, the gain is 1.

Then, as shown in FIG. 2, the reference acceleration α _S (S1) calculated and processed by the reference acceleration calculating means 11 and the actual acceleration calculated and processed by the actual acceleration calculating means 12 are processed. α _R (S2) is compared by the road condition determination means 17 (S3). Specifically, a difference (α _R −α _S = a) between the actual acceleration α _R and the reference acceleration α _S is obtained, and when this value a is larger than a predetermined positive value b (b <a ), It is determined that the vehicle is traveling on the downhill road, the downhill road map is selected (S4), and if the value a is smaller than the predetermined negative value -c (a <-c), the uphill road is When it is determined that the vehicle is traveling, an uphill road map is selected (S5), and when the value a is between the positive value b and the negative value -c (-c <a <b), the vehicle is traveling on a flat road. And a flat road map is selected (S6).

  Steps S4, S5, and S6 correspond to the shift pattern changing unit 19, and based on the selected map, the shift output unit 20 outputs a predetermined shift signal to shift the automatic transmission 2 to a predetermined shift stage. To do.

The flat road map is a shift map composed of a normal shift pattern based on the throttle opening and the vehicle speed as shown in FIG. 3 (a), and the uphill road map is as shown in FIG. 3 (b). Each shift line is deviated from the flat road map by a predetermined amount toward the high speed side. In FIG. 3, the solid line is a shift line in an upshift, and the dotted line is a shift line in a downshift. Road gradient is determined from the magnitude of the absolute value of the difference a between the actual acceleration alpha _R and the reference acceleration in step S3, the gradient of the determination has been uphill road, the the gradient from uphill maps are a number The corresponding map is selected. The uphill road map may be one in which only the high speed side such as the third speed and the fourth speed is biased to the high speed side to prevent frequent shifts during normal driving, and the low throttle opening degree It may be biased toward the high speed side alone.

As shown in FIG. 4, the downhill road map is a diagram based on downhill road slope [%] and vehicle speed [km / h]. The solid line is a shift line of 3 → 4 upshift, and the hatched part decelerates the vehicle by the acceleration applied to the vehicle based on the downhill slope, that is, the force in the vehicle forward direction based on the vehicle gravity due to the downhill, and the engine brake This is a line that balances the force in the reverse direction. Note that the downhill slope is determined based on the value of the difference a between the actual acceleration alpha _R and the reference acceleration alpha _S in the step S3.

  Specifically, although there is a 3 → 4 shift line at the intersection of the gradient e (for example, 5%) and the vehicle speed f (for example, 80 km / h), the vehicle speed increases by g (for example, 90 km / h) while maintaining the gradient e. Then, the engine braking force increases with respect to the forward force based on the vehicle weight by the difference i from the shift line, and when the vehicle speed is reduced to h (for example, 70 km / h) while maintaining the gradient e, the difference j from the shift line j Only the forward force based on the vehicle weight becomes larger than the engine braking force.

  Therefore, when the vehicle is on the road gradient e, if the vehicle speed f exceeds the vehicle speed f, the engine braking force is reduced by upshifting 3 → 4, and if the vehicle speed is lower than the vehicle speed f, the engine braking force is reduced by 4 → 3. The vehicle forward direction force based on the road gradient e and the engine braking force are balanced at the vehicle speed f, and the driver holds the vehicle speed h with the accelerator pedal turned off. Become. Note that if one shift line consisting of the same solid line is used on both the upshift side and the downshift side, a hunting state in which the shift operation is frequently switched across the vehicle speed h is entered. Hysteresis is provided between the downshift line and the hunting is avoided. The shift line may be slightly shifted to the right or left from the balanced state shown in the figure. In this case, an engine brake effect can be obtained more when the slope is shifted to the right, and a moderate engine brake effect can be obtained when the slope is shifted to the left. In FIG. 4, only the 3-4 shift has been described. However, a shift line may be set in the same manner even in other shift speeds. In other shift speeds, shift lines that depend only on the vehicle speed ( A vertical line extending in the vertical direction in FIG. 4 may be set.

  Next, the gain changing means 16 and the pause means 15 shown in FIG. 1 will be described in detail with reference to FIGS.

First, for reference, a state where the driver steps on the brake pedal on a downhill road will be described with reference to FIGS. When the vehicle enters the downhill road and the driver performs the foot brake operation, the reference acceleration α _S is calculated based on the engine output torque with reference to the flat road as described above. Although it is maintained at the same constant value as when running on a flat road without being affected by the increase in running resistance due to the foot brake operation, the actual acceleration α _R is affected by the increase in running resistance due to the foot brake operation. The travel resistance increase amount decreases.

  Actually, as shown by the dotted lines in FIGS. 5 and 6, the smoothing process by the filter processing means decreases with a predetermined response delay with respect to the raw actual acceleration not shown in the solid line. Therefore, in the brake operation state, that is, in the ON state of the brake switch 10, the determination of the road gradient by the comparison between the actual acceleration and the reference acceleration is suspended.

In the prior art, after the foot brake operation is lost and the brake switch is turned OFF, the above-described smoothing process continues as it is, so that it is relatively long as shown by the one-dot chain line in FIG. 5 and FIG. 6A. There is a response delay, hence the delay timer t ₁ after long brake-off is set. Specifically, as shown by conventional [E ′ (n)] (one-dot chain line) in FIG. 8, the first (n = 1) actual acceleration E ′ (1) accompanied by the smoothing process after the brake switch is turned off. ) Is performed by the value E (0) obtained by the smoothing process up to the previous time calculated when the brake switch is turned on and the actual acceleration e (1) based on the first actual vehicle speed. That is, E ′ (1) = [E (0) * 3 + e (1)] / 4 is calculated. Similarly, the actual acceleration E ′ (2) for the second time (n = 2) after a predetermined time (100 ms) has elapsed is the value E ′ (1) calculated in the first time and the actual vehicle speed for the second time. Is calculated as E ′ (2) = [E (1) * 3 + e (2)] / 4. Similarly, the third acceleration (n = 3) actual acceleration E ′ (3) is calculated by E ′ (3) = [E (2) * + e (3)] / 4.

On the other hand, according to the embodiment of the present invention, as shown in FIG. 7, it is determined whether or not there has been a switching operation of the brake switch from ON to OFF, that is, a brake off event (S10). If YES (YES), the timer means (pause means) 15 (see FIG. 1) sets a relatively short off-direct timer t ₂ (t ₂ = 1; S11). Then, from the actual vehicle speed by the vehicle speed sensor 7, a raw actual acceleration not subjected to the annealing process is calculated (S12).

When the actual acceleration is calculated from the next cycle, since there is no brake-off event in step S10 (NO), the smoothed actual acceleration is calculated (S13). Then, the calculation of the actual acceleration alpha _R, which is the smoothing process is repeated until the off-delay timer t ₂ which is the set has elapsed (NO; S14). In a state in which the off-delay timer t ₂ has elapsed, the actual acceleration alpha _R and the reference acceleration alpha _S and is compared with downhill and slope thereof as described above are determined (S15). That is, the smoothing process of the filter processing unit 13 immediately after the brake is turned off is changed to be stopped by the smoothing process stop unit 16a.

  Specifically, as shown in the present invention [E (n)] in FIG. 8, the actual acceleration E (1) for the first time (n = 1) after switching the brake switch from ON to OFF is determined at that time. Is the actual acceleration e (1) based on the vehicle speed calculated in (1). That is, E (1) = e (1). The second actual acceleration E (2) is calculated by smoothing the first actual acceleration E (1) and the actually calculated acceleration e (2). That is, E (2) = E [(1) * 3 + e (2)] / 4 is calculated. Similarly, the third actual acceleration E (3) is smoothed by the second actual acceleration E (2), and E (3) = [E (2) * 3 + e (3)] / 4. It is calculated by.

The actual acceleration calculation values after the second time (n = 2) and thereafter are smoothed as described above, the coefficient of the previous smoothing process value is 3, the coefficient of the actual detection value is 1, and the gain is [1/4] and the actual acceleration for the first time (n = 1) uses the raw detection value e (1) as it is, so that the coefficient of the previous smoothing process is 0 and the coefficient of the actual detection value is 1 and the gain is 1. Therefore, the operation of the annealing process stopping means 16a is changed so that the gain changing means 16 increases the gain of the annealing process (specifically 1). Further, the change by the gain changing means is not limited to 1 described above. For example, the gain G is set to [1/2], [1 / 3] and the like (n = 2). Further, (smoothing process aborted (G = 1) or gain to the large change) immediately after the brake switch off control cycle is not limited to one time, the setting time of the delay time t _2, the two, three, etc. For example, n = 1, G = 1, n = 2, G = 1/2, n = 3, and G = 1/3 so that the gain is gradually decreased every control cycle. And n = 4, and normal G = 1/4 may be restored.

Thus, as shown in dotted lines and the diagram of FIG 5 6 (b), the calculation of the first actual acceleration alpha _R, since using actual acceleration due to raw actual acceleration or large gain not treated moderation, by foot brake In line with the sudden increase in actual acceleration due to the absence of the increase in running resistance, it rises rapidly without causing a delay in response, and from the next cycle, the smoothing process based on the above-mentioned suddenly increased actual acceleration. the go, smoothly restored while absorbing errors and disturbances, the actual acceleration calculated value based on relatively quickly road gradient is obtained as a whole, thereby setting shorter delay timer time t ₂ after the brake off that Is possible.

Accordingly, as shown in FIG. 5, after the elapse of the delay timer t _2, downhill road by the difference a (= α _R -α _S) between the actual acceleration alpha _R and the reference acceleration alpha _S is determined, Figure 4 early The downhill road map is selected, and the gear position is obtained from the road gradient and the vehicle speed calculated based on the numerical value of the difference a. As a result, when the curve is intermittent on a downhill road, even if the foot brake is intermittently operated, it returns early after the brake switch is turned off, and the gear position corresponding to the road gradient is set.

  Next, the operation of the gain changing means 16 (FIG. 1) immediately after the vehicle enters the uphill road will be described with reference to FIGS.

When the vehicle enters the uphill road, the driver depresses the accelerator pedal and the throttle opening increases. As shown in FIG. 9, since the actual acceleration α _R depends on the vehicle speed, it is not affected by the change in the throttle opening, but the actual acceleration α _R calculated by the engine output torque that depends on the throttle opening. Since the reference acceleration is affected by the throttle opening and changes as indicated by the thin solid line e (n) in FIG. 10, a delay timer that constitutes a predetermined dead zone is used so as not to affect the road condition determination. Is set. Further, when the reference acceleration α _S is calculated, a predetermined smoothing process is performed to absorb errors and disturbances caused by slipping of the torque converter, and therefore the delay timer may be set longer. .

  In the case of the prior art, at the start of the throttle opening change, the same processing as the normal annealing processing, that is, the value E () obtained by the previous annealing processing as shown by E ′ (n) shown by the one-dot chain line in FIG. n−1) and an average value obtained by multiplying a predetermined coefficient between the actual acceleration e (n) calculated based on the vehicle speed in the current cycle (n), that is, E ′ (n) = [E (n−1) * 3 + e (n)] / 4. Specifically, in the first cycle (n = 1) after changing the throttle, E ′ (1) = [E (0) * 3 + e (1)] / 4, and in the second cycle (n = 2). , E ′ (2) = [E (1) * 3 + e (2)] / 4 In the third cycle (n = 3), E ′ (3) = [E (2) * 3 + e (3)] / 4

Therefore, in the prior art, as shown by the one-dot chain line in FIG. 9, a long delay timer corresponding to the above-described annealing process with a relatively large response delay based on a relatively large gain (G = 1/4). time t ₃ has been set.

On the other hand, according to the embodiment of the present invention, as shown by the solid line in FIG. 10 and FIG. 11, the depression of the accelerator pedal, that is, the increase event of the throttle opening (S20), the timer means 15 (FIG. 1) The timer t is set to 0 and time counting is started (t = 0; S21). Then, the time t by the timer is compared with a predetermined time t _M set in advance (S22). If the time t is within the predetermined time t _M (t> t _M ), the previous annealing process has been completed. value E (n-1) factor largely were performed smoothing process of the reference acceleration by a small gain (S23), the processing moderation by the small gain as long as the measured time t does not exceed the predetermined time t _M The process is repeated a plurality of times every predetermined cycle (100 ms).

Specifically, as shown by the solid line in FIG. 10, in the first cycle (n = 1) from the increase change in the throttle opening, the reference acceleration annealing process E (1) is performed by the previous annealing process. If the value is E (0) and the reference acceleration value based on the throttle opening detected in the cycle is n (1), E (1) = [E (0) * 9 + e (1)] / 10. That is, the coefficient for the value of the previous annealing process is increased from 3 to 9 times that in the normal case, and the gain G is reduced to [G = (1/10)] accordingly, and the reference acceleration of the change in the throttle opening is reduced. The effect of. Second cycle (n = 2) is likewise in the range E (2) = [E of (1) * 9 + e ( 2)] / 10 , and the measured time t does not exceed the predetermined time _{t M,} for example, 9 th This cycle is repeated until n cycles (n = 9).

When the measured time t exceeds the predetermined time _{t M} (NO at step S22; _{t> t} M), for example, similar to conventional annealing process, moderation due to a large gain processing is performed (S24). Process moderation by the large gain, the timing t is repeated a plurality of times in the range (t> t ₄₎ that does not exceed a predetermined time t ₄ when set in advance (S25). When the time t has passed the predetermined time t ₄ , that is, a predetermined time t ₄ (t ₄ <t ₃ ; see FIG. 9) that becomes a preset relatively short delay timer, the reference acceleration α _S is The state is restored to the steady state where the influence of the change in the throttle opening is eliminated, the actual acceleration α _R is compared with the reference acceleration α _S , the judgment of the uphill road and the gradient thereof are estimated, and the road gradient is calculated. A corresponding predetermined uphill road shift map is selected (S26).

More specifically, as shown in solid line in FIG. 10, in a state where the time t exceeds the predetermined time t _M, has become, for example, 10 cycle and (n = 10), the reference in the cycle The acceleration smoothing process E (10) is represented by E (10) = [E, where E (9) is a value subjected to the ninth smoothing process and e (10) is a reference acceleration value in the tenth cycle. (9) * 3 + e (10)] / 4. That is, a normalization process consisting of a gain G (= 1/4) with a normal coefficient 3 is performed for each cycle, and errors, disturbances, etc. based on changes in the throttle opening are absorbed by the smoothing process with the large gain. , It converges to the original reference acceleration α _S.

The gain changing means according to the above embodiment has been switched gain to small → large for a predetermined time t _M, to change gradually so as to increase the gain in each control cycle (n) or every predetermined plurality control cycle Also good.

  The determination of the road condition is not limited to the difference between the actual acceleration and the reference acceleration, and may be performed by other comparison methods such as a ratio. The shift pattern change is not limited to the selection of the shift map, and other shift points. The change method may be used. Further, the annealing process by the filter processing means is not limited to the method described above, but may be another method for averaging the vertical deviation.

The block diagram which shows the outline of the shift control which concerns on this invention. The main flow figure of the shift control concerning the present invention. (A) is a flat road shift map, (b) is a diagram showing an example of an uphill road shift map. The figure which shows a downhill road shift map. The time chart which shows the action | operation when a foot brake act | operates at the time of downhill driving | running | working. (A) is a time chart which shows the operation | movement by a prior art, (b) is a time chart which shows the operation | movement by a reference example. The flowchart of the real acceleration calculation at the time of brake ON-OFF. The enlarged view which shows the specific example of an annealing process. A time chart showing the operation when the accelerator pedal is depressed during climbing. The enlarged view which shows the specific example. (A), (b) is a flowchart of the reference acceleration calculation at the time of accelerator depression.

Explanation of symbols

1 Engine 2 Automatic transmission (transmission)
3 Electronic control unit 5 E / G rotation speed sensor 6 T / M input rotation speed sensor 7 Vehicle speed sensor 9 Throttle opening sensor 10 Brake switch 11 Reference acceleration calculation means 12 Actual acceleration calculation means 13 Filter processing means 15 Pause means 16 Gain change Means 17 Road condition judging means 19 Shift pattern changing means α _S reference acceleration α _R actual acceleration

Claims (4)

Reference acceleration calculation means for calculating a reference acceleration in a flat road running state based on the engine output torque;
Actual acceleration calculation means for calculating actual acceleration based on the vehicle speed;
Road condition determination means for comparing the reference acceleration and actual acceleration to determine the road gradient condition,
In the vehicle shift control device, the shift pattern of the automatic transmission is changed based on the road gradient state by the road state determination means.
Filter means for smoothing the value of the reference acceleration by the reference acceleration calculation means;
Pausing means for pausing the determination of the road condition determination means when the value of the reference acceleration is not determined by the driver's accelerator pedal operation,
The influence of the current actual acceleration value for each control cycle is smaller than the previous value during the pause by the pause means due to the throttle opening increasing and changing due to the driver's depression of the accelerator pedal. Gain changing means for changing the gain of the smoothing process relative to the reference acceleration by the filter means to be small;
A shift control apparatus for a vehicle, comprising: The gain changing means changes so as to reduce the gain for a predetermined time from an increase change in the throttle opening.
The vehicle speed change control device according to claim 1 . The road condition determining means determines whether the road is a flat road, an uphill road or a downhill road based on the difference between the actual acceleration and the reference acceleration, further determines a road gradient, and based on the determination of the road condition determination means , Select flat road map, uphill road map, downhill road map,
The vehicle shift control device according to claim 1 or 2 , characterized in that The flat road map and the uphill road map are composed of shift lines based on the vehicle speed and the throttle opening,
And as for the uphill road map, a plurality of types in which the shift line is biased toward the high speed side as compared with the flat road map is prepared, and these maps are selected based on the determined road gradient.
4. The vehicle shift control device according to claim 3, wherein

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