JP3362670B2 - Tire pressure estimation device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tire air pressure estimating device for estimating tire air pressure of an automobile or the like, and particularly, when estimating the tire air pressure indirectly from a vibration component of the tire when the vehicle is running, the estimation accuracy thereof is improved. It relates to the implementation of a presumed structure that can be higher.

[0002]

2. Description of the Related Art Conventionally, as a tire air pressure estimating device of this type, for example, a device disclosed in Japanese Patent Laid-Open No. 5-133831 or a device described in Japanese Patent Laid-Open No. 6-328920 is known. In any of these devices, the vibration component of the wheel speed caused by the vibration of the tire is extracted from the wheel speed signal to obtain the resonance frequency in the vertical direction of the tire, the front-rear direction, or the twist direction of the tire rotation, and the calculated resonance frequency. The air pressure of those tires is estimated based on.

According to such a tire air pressure estimating device, it is possible to estimate the air pressure without requiring a means for directly detecting the tire air pressure such as a pressure sensor.

[0004]

The technique for indirectly detecting the tire pressure focuses on the fact that a fixed relationship is established between the tire pressure and the tire rigidity. There is a part that depends on the air pressure of the inner space as well as a part that depends on the rubber hardness of the tire, and it is difficult to detect both separately. Also,
The rubber hardness of a tire changes depending on its rubber temperature.

However, the technique of indirectly detecting the tire air pressure has not hitherto been performed in consideration of the change in tire temperature. Therefore, in this conventional indirect detection technology, even if the air pressure in the tire space is the same, if the tire temperature is different, the rigidity of the entire tire will be different, and
The detected value of tire pressure will be different from the actual value. As a result, for example, when performing the conventional indirect detection technology together with the technology of warning the driver by detecting that the tire pressure is abnormally low, although the actual tire pressure is normal, Although the tire temperature has risen and the rubber hardness has decreased, an abnormally low tire pressure that should not have been detected would be detected.Although the actual tire pressure is extremely low, However, there has been a problem that there may occur a situation in which an abnormal decrease in tire air pressure is not detected, which may result in non-detection.

Therefore, an object of the present invention is to provide a tire air pressure estimating device capable of estimating tire air pressure with a single layer accuracy in consideration of the tire temperature. More preferably, the element that outputs the tire temperature related value related to the tire temperature is arranged in the signal processing device that performs the arithmetic processing of the tire pressure estimation, and the wire for taking the tire temperature into the signal processing device is unnecessary. In addition, it is an object of the present invention to provide a tire pressure estimation device that is cost effective and does not need to be specially provided on the vehicle body outside the signal processing device to be provided with a sensor or the like for detecting the tire temperature.

[0007]

In order to achieve such an object, according to the present invention, as described in claim 1, a vibration component output means for outputting a signal including a vibration component of a tire when the vehicle is running, and Extraction means for extracting the resonance frequency or tire spring constant of the vibration component from the output signal containing the vibration component of the tire, and air pressure estimation means for estimating the tire air pressure based on the extracted resonance frequency or tire spring constant. A tire temperature related value extracting means for extracting a tire temperature related value related to a tire temperature among the extracted external factors affecting the resonance frequency or the spring constant, and the extracted tire temperature related value according to the extracted tire temperature related value. And a correction means for correcting the influence on the resonance frequency or the tire spring constant , the tire temperature-related value
The extraction means calculates the signal including the vibration component of the tire.
It utilizes the elements provided in the signal processing device for
And a tire air pressure estimating device for extracting the outside air temperature as the tire temperature related value .

With such a structure, it is possible to avoid the influence of the tire temperature as an external factor in estimating the tire air pressure, and it is possible to improve the estimation accuracy of the tire air pressure. In recent years, an outside air temperature sensor may be mounted on a vehicle for the purpose of automatically controlling the air-conditioning inside the vehicle compartment (automatic air conditioner) or providing the driver with road surface freezing information while the vehicle is traveling. Has been done.

Further , as tire temperature related value extraction means ,
An outside temperature is extracted as a tire temperature related value by using an element provided in a signal processing device for a signal including a vibration component of the tire . It is, of course, desirable to detect the temperature of the rubber of the tire itself as the temperature (value related to the tire temperature) that causes a change in the rubber hardness of the tire, but since the tire rotates, the detection Is relatively difficult. On the other hand, it is relatively easy to detect the outside air temperature of the vehicle, and it is considered that if the outside air temperature of the vehicle is high, the temperature of the tire itself will be high. Thus, a predetermined relationship is established between the outside air temperature and the temperature of the tire itself.

Therefore, paying attention to this relationship, the outside air temperature is used to improve the estimation accuracy of the tire air pressure. When an outside air temperature sensor used for air conditioning is also used for tire air pressure estimation as described above, a transmission path for sending a signal from the outside air temperature sensor to the signal processing device (CPU) of the tire air pressure estimation device. (Transmission wiring) is required, which affects mounting. Alternatively, this transmission path (wire for transmission wiring) is required, and the transmission path may be affected by magnetic noise or the like. However, as described above, if the outside air temperature is detected by using the element provided in the signal processing device, it is not necessary to take in a signal related to the outside air temperature from the outside to the signal processing device, resulting in mounting, cost, magnetic noise, etc. It is advantageous to Even in a vehicle that does not have an outside air temperature sensor for air conditioning, it is more advantageous to place it inside the signal processing device than to place a sensor for detecting the outside air temperature outside the signal processing device. Is.

As the element for detecting the outside air temperature, a temperature detecting sensor having a temperature detecting function or a semiconductor element having a temperature characteristic may be newly added in the signal processing apparatus. Alternatively, the temperature characteristic of the element set in the signal processing device may be used as a signal processing circuit for extracting the resonance frequency or the spring constant of the tire from the signal including the vibration component of the tire.

Further, as described in claim 2 , the tire temperature related value extracting means detects the time when the temperature of the element in the signal processing device has a predetermined correlation with the outside air temperature, and detects at that time. The tire temperature-related value may be estimated according to the temperature of the element that has been stored. In many cases, the signal processing device is often mounted in a position belonging to the vehicle interior space of the vehicle. Therefore, the element that is the detection unit for estimating the outside air temperature may be affected by the temperature of the vehicle interior space.

The temperature of the vehicle interior space is greatly affected by the air conditioner of the vehicle while the vehicle is running and by the solar radiation when the vehicle is stopped. In addition, it may be affected by heat generation of the element itself due to energization or the like. However, when the relationship between the outside air temperature and the temperature of the element is estimated from the way the vehicle is used for a relatively long time, it can be considered as shown in FIG. The existence of a sufficient vehicle stoppage time that is consistent with the above is sufficiently conceivable even under actual use conditions. Therefore, more accurate estimation can be realized by estimating the tire temperature-related value by capturing the opportunity that the temperature of the element in the signal processing device converges to the outside air temperature while the vehicle is stopped.

Further, as described in claim 3 , the tire temperature related value extraction means calculates the outside air temperature related value based on a plurality of detected values detected when the vehicle ignition switch is turned on. It may be estimated. In order to capture the opportunity for the elements in the signal processing device to converge to the outside air temperature, considering the heat generated by the element itself after the signal processing device is powered on, it is detected immediately after the vehicle ignition switch is turned on. It is effective to adopt the temperature of the element to be used for estimating the outside air temperature. That is, if the outside air temperature is detected immediately after the ignition switch is turned on as described above, the influence of heat generation due to the energization of the element can be avoided and the accuracy of the outside air temperature estimation can be improved. Note that the outside air temperature detected at this time may be stored until the next outside air temperature detection when the ignition switch is turned on, and may be used for estimating the tire air pressure.

In addition, the number of times the ignition switch is turned on a predetermined number of times is set in order to capture the opportunity for the elements in the signal processing device to converge to the outside air temperature. By setting the number of times of this setting to be larger than the number of times of turning on the ignition switch, which generally operates in one day, the elements in the signal processing device are at least once out of the plurality of times of setting. It can be assumed that there is an opportunity to converge to ambient temperature. For example, at night, there is a high probability that the vehicle will be left unattended, and therefore, there is a high probability that the element will converge to the outside air temperature. In this way, by increasing the probability that the elements in the signal processing device will converge to the outside air temperature, the number of times that the tire air pressure can be accurately estimated increases.

Further, as described in claim 4 , the tire temperature related value extracting means is configured to detect the tire temperature based on the minimum value of a plurality of detected values detected immediately after the ignition switch of the vehicle is turned on. The related value may be estimated. This is because, as shown in FIG. 6, the temperature of the element in the signal processing device when the ignition switch is turned on is an actual value due to the effect of heat generation of the element itself, the effect of the vehicle interior temperature due to the air conditioning control, and the effect of solar radiation. It may be different from the outside temperature. However, considering the contribution degree of each influence on the temperature of the element in the signal processing device, the only factor that lowers the temperature of the element is the air conditioning control of the vehicle. However, considering both the cooling effect by the air conditioning control and the heat generation effect by the element itself, it is considered that the temperature of the element is always higher than the outside air temperature while the vehicle is traveling (the ignition switch is in the ON state). Also, due to the influence of solar radiation, the vehicle interior space should be higher than the outside air temperature, and the temperature of the element in the signal processing device affected by the influence is also higher than the outside air temperature.

That is, at each temperature of the element in the signal processing device when the ignition switch is turned on a plurality of times, the lowest temperature is shown when the temperature of the element converges to the outside air temperature. Therefore, for example, a predetermined plurality of outside air temperature values detected in the element when the ignition switch is turned on may be stored, and the minimum value among them may be used to correct the influence on the tire air pressure estimation. .

According to a fifth aspect of the present invention, the correction means includes the estimated tire air pressure in addition to the resonance frequency or the tire spring constant depending on the outside air temperature extracted by the tire temperature related value extraction means. You may make it correct | amend at least one of these. That is, the correction means may correct the resonance frequency or the tire spring constant indirectly indicating the change of the tire pressure or the tire pressure itself according to the tire temperature-related value, or not correcting the resonance frequency or the tire spring constant. The tire air pressure estimated based on the uncorrected resonance frequency or tire spring constant may be corrected.

Taking the case of correcting the extracted resonance frequency as an example, the correction means has the resonance frequency ω to be corrected, the detected temperature information Temp, and the resonance frequency ω based on the same temperature state. The correction amount is Δω (Temp)
Then, the corrected resonance frequency ω ′ is calculated based on the equation (2). The air pressure estimating means estimates the air pressure of the tire based on the calculated corrected resonance frequency ω ′.

[0020]

## EQU2 ## ω '= ω-Δω (Temp) (2) By adopting such a configuration, it becomes possible to easily and accurately avoid the influence of the outside air temperature. At this time, the correction amount Δω (Temp) of the resonance frequency ω based on the temperature information Temp is “when the tire air pressure is the same, the rubber portion of the tire becomes harder and the resonance frequency becomes higher when the outside air temperature becomes lower. , The rubber portion of the tire becomes softer and the resonance frequency becomes lower when the outside air temperature rises ", and a value that can cancel the influence is selected. For example,
A map or the like in which the correction amount is registered in advance corresponding to the temperature information Temp can be used.

Further, as described in claim 6 , a vibration component output means for outputting a signal including a vibration component of the tire when the vehicle is running, and a signal including the vibration component of the tire outputted from the vibration component output means Extraction means for extracting the resonance frequency or the tire spring constant, air pressure estimating means for estimating the air pressure of the tire based on the extracted resonance frequency or the tire spring constant, and an influence on the extracted resonance frequency or the spring constant External Based on the relationship between the tire temperature related value extracting means for extracting the tire temperature related value related to the tire temperature among the factors, and the relationship between the air pressure estimated by the air pressure estimating means and a predetermined determination value, the air pressure is The determination means for determining whether or not there is an abnormality, and the determination value in the determination means are determined by the tire temperature related value extraction means. A correction means for correcting, based on the tire temperature-related values extracted Te may be provided with.

As described above, even when the tire air pressure is determined based on the comparison relationship with a predetermined determination value or the like, the accuracy of the tire air pressure determination can be improved by performing the correction according to the tire temperature related value. . Further, as described in claim 7 , the extraction means introduces a linear prediction model for the same vibration into a time-series signal including the vibration component of the tire output from the vibration component output means, and introduces the linear prediction model. You may make it comprised by the linear prediction means which identifies the parameter of a prediction model and extracts the resonance frequency of the said vibration component.

That is, it becomes possible to estimate the parameter of the linear prediction model by obtaining the interphase coefficient between the time series signals including the tire vibration component, and if the parameter can be estimated against it. By using these parameters, it becomes possible to obtain the resonance frequency in the tire up-down direction, the front-rear direction, or the tire rotation torsion direction described above.

In this case, in particular, as described in claim 8 , the linear predicting means sets the sampling number to k, the time series signal including the tire vibration component to y (k), and the disturbance to m.
In the case of (k), a two-hour discrete-time model such as the equation (1) is introduced as a linear prediction model for the vibration, and parameter identifying means for traveling the respective parameters c1 and c2 are identified. Parameters c1 and c2
And a resonance frequency calculating means for calculating the resonance frequency based on the above.

With such a configuration, it is possible to reduce the amount of calculation and memory capacity required for tire pressure determination. Incidentally, considering that each tire has one resonance point depending on its air pressure, the “second order” is sufficient as the order of the linear prediction model. Further, in this case, as the parameter identifying means,
, The parameter c1,
C2 may be identified, which is advantageous in performing identification with high efficiency.

Further, as compared with the case where these linear prediction models are introduced, it is disadvantageous in terms of the required calculation amount and memory capacity, but with respect to each of the configurations described in claims 1 to 6 , According to a tenth aspect of the present invention, there is provided FFT calculation means for performing a fast Fourier transform (FFT) calculation on the signal including the tire vibration component output from the vibration component output means, and the air pressure estimation means is the The tire air pressure may be estimated from the resonance frequency of the frequency spectrum obtained by the FFT calculation. Even in this case, it is possible to improve the tire air pressure estimation accuracy as compared with the conventional device.

According to the eleventh aspect of the present invention, the wheel speed detecting means for detecting the wheel speed signal of each wheel during traveling of the vehicle, and the wheel speed signal detected by the wheel speed detecting means Extraction means for extracting the resonance frequency or tire spring constant of the tire vibration component from the tire vibration component included in the wheel speed signal, and air pressure estimation means for estimating the tire air pressure based on the extracted resonance frequency or tire spring constant. And a determination means for determining whether or not the air pressure is abnormal based on the relationship between the air pressure estimated by the air pressure estimation means and a predetermined determination value, and a signal processing device provided in the cover. A tire temperature related to a tire temperature among the external factors affecting the extracted resonance frequency or spring constant. And having a correction means for correcting the determination value in the determination means based on the tire temperature related value, and the temperature in the signal processing device for extracting the tire temperature related value used in the correction means. A temperature sensing element that detects the outside air temperature may be arranged in the signal processing device.

According to a twelfth aspect of the present invention, a wheel speed detecting means for detecting a wheel speed signal of each wheel when the vehicle is traveling, and a wheel speed signal detected by the wheel speed detecting means are used to detect the wheel speed signal. Extraction means for extracting the resonance frequency or tire spring constant of the tire vibration component from the tire vibration component included in the wheel speed signal, and air pressure estimation means for estimating the tire air pressure based on the extracted resonance frequency or tire spring constant. Based on the relationship between the air pressure estimated by the air pressure estimating means and a predetermined determination value, a determining means for determining whether or not the air pressure is abnormal, and a calculation based on the wheel speed signal. The wheel speed of each wheel is used to control the wheel braking force applied to each wheel so as to mitigate the lock tendency of each wheel. A signal processing device having a kid control means in a cover, and extracting a tire temperature related value related to a tire temperature among external factors affecting the extracted resonance frequency or spring constant, and making the determination. The temperature sensing has a correction means for correcting the judgment value in the means based on the tire temperature related value, and detects the temperature in the signal processing device as the outside air temperature in order to extract the tire temperature related value used in the correction means. The element may be arranged in the signal processing device.

As described above, when the portion for estimating (determining) the tire pressure and the portion for performing anti-skid control are arranged in one signal processing device, the temperature related to the tire temperature is further measured. A temperature sensing element for extraction is also located within the signal processor. Since both the tire pressure estimation and the anti-skid control are executed based on the signal from the same wheel speed detecting means, the signal processing device for tire pressure estimation (determination) and the anti-skid control are thus executed. By integrating the signal processing device for this purpose, signal processing can be performed at one place, and the number of parts can be reduced. Further, even in such a case, if the temperature sensing element for extracting the tire temperature related value is arranged in one signal processing device, the same operational effect as described above can be obtained.

[0030]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a tire pressure estimating device according to the present invention will be described below with reference to the drawings. The device of this embodiment is configured as a device that detects the resonance frequency of each wheel speed and determines whether or not the actual tire air pressure is lower than the lower limit value based on the resonance frequency.

As described above, the relationship between the tire air pressure and the tire resonance frequency is such that the lower the tire air pressure, the lower the resonance frequency. On the other hand, the torsional vibration in the tire rotation direction is also included in the wheel speed signal, and is detected as the resonance frequency or the tire spring constant based on the wheel speed signal. That is, the relationship is also established between the tire air pressure and the resonance frequency included in the wheel speed signal, such that the lower the tire air pressure, the lower the resonance frequency.

Therefore, in the apparatus of the embodiment, as shown in FIG. 3, the tire air pressure is estimated based on the relationship map of the tire air pressure and the resonance frequency estimated from the wheel speed signal, and the estimated tire is obtained. It is determined whether or not the air pressure is lower than a lower limit value, that is, a limit value that affects driving of the vehicle. FIG. 1 is an explanatory diagram of the entire tire air pressure estimation device according to the present invention.

As shown in FIG. 1, the tires 1a to 1a of the vehicle are
Wheel speed sensors 2 to 5 are provided corresponding to 1d. The wheel speed sensors 2 to 5 are respectively connected to the rotors 2a to 2a.
5a and pickup coils 2b-5b. The rotors 2a to 5a are coaxially attached to the rotation shafts (not shown) of the tires 1a to 1d and are made of a disk-shaped magnetic body. Pickup coil 2b
5b output the alternating current signal which has a period according to the rotation speed of rotor 2a-5a, ie, tire 1a-1d, respectively.

The AC signals output from the pickup coils 2b to 5b are input to a known electronic control unit (hereinafter referred to as ECU) 6 including a microcomputer including a CPU, ROM, RAM, etc., and a waveform shaping circuit,
Predetermined signal processing including waveform shaping of the AC signals output from the pickup coils 2b to 5b is performed. The electronic control unit 6 corresponds to a signal processing device.

The result of this signal processing is output to the display unit 7 to inform the driver of the air pressure state of each tire 1a-1d. The display unit 7 may independently display the air pressure state of each tire 1a to 1d, or one warning lamp may be provided to indicate that the air pressure of any one of the tires is lower than the reference air pressure. The driver may be informed.

Next, the operation of the ECU 6 will be described with reference to FIG. The ECU 6 uses the wheel speed sensors 2 to 2
Based on the output of 5 (wheel speed signal) and the output of the temperature sensing element 6i (signal corresponding to the tire temperature related value), it is determined whether or not the tire air pressure of each wheel is abnormal. The ECU 6 also outputs a drive signal for display to the display unit 7.

In the ECU 6, a resonance point detector 6 for detecting the resonance frequency from the wheel speed signals from the wheel speed sensors 2 to 5 and the outside air temperature signal from the temperature sensing element 6i.
a to 6d, and determination units 6e to 6h for determining the presence or absence of tire pressure abnormality for each tire based on the detected resonance frequencies, and a temperature sensing element 6i. Note that the ECU 6 has a microcomputer 600 as shown in FIG. 4, and the functions as the resonance point detection units 6a to 6d and the determination units 6e to 6h are achieved by utilizing the arithmetic function of the microcomputer. Will be realized. This microcomputer 600 is the arithmetic processing unit C
It is a well-known fact that it is configured to include a PU 601 as well as a ROM 602 mainly used as a program memory and a RAM 603 used as a data memory.

The microcomputer 600 and the temperature sensing element 6i are integrally covered by a cover 6j forming the outer shell of the ECU 6. Next, the ECU 6
The details of the signal processing executed in step 1 will be described.
First, the basic principle of the resonance frequency estimation based on the wheel speed signal performed by the resonance frequency calculators 6a to 6d of the ECU in FIG. 2 will be described.

The physical model for tire pressure estimation is
It can be represented as in FIG. That is, the road surface disturbance m (k), which is white noise, is applied as an input to the tire suspension system, and as a result, the wheel speed signal y (k) is output. At this time, the wheel speed signal y (k) contains a resonance component depending on the tire pressure. Note that instead of the road surface disturbance m (k),
Brake fluid pressure vibration due to the ON-OFF duty of the solenoid valve may be transmitted from the vehicle brake system to the tire of the wheel via the wheel cylinder, and may be used as an external vibration input that forms resonance of the tire.

In the tire air pressure estimating apparatus according to the embodiment, the tire / suspension system is approximated by a linear prediction model, and the parameters of the model are identified by using the least square method. If there is one resonance point depending on the air pressure for each tire, the degree of this linear prediction model is sufficient to be "second order". In addition, the order of the model is 2
By the following, the calculation amount and the data memory (RAM 603) capacity required for the ECU 6 can be minimized.

Now, assuming that the number of samplings is k, the road surface disturbance is m (k) and the wheel speed signal is y as described above.
Assuming (k), the second-order discrete-time model has the following (3)
It can be expressed as an expression.

[0042]

[Mathematical formula-see original document] y (k) =-c1y (k-1) -c2y (k-2) + m (k) (3) Here, the purpose of parameter identification is to obtain a finite number of observation data y (k). Is to estimate the unknown parameters c1 and c2. Here, the unknown parameters c1 and c2 are identified using the least squares method.

That is, with θ being a parameter vector and z being a measurement value vector, two-dimensional vectors of the following equations (4) and (5) are defined.

[0044]

[Equation 4]

(4)

[0046]

[Equation 5]

(5) As a result, the above equation (3) becomes

[0048]

[Equation 6]

It becomes possible to express it in the form of (6). As described above, m (k) in the equation (6) is road surface disturbance and can be regarded as white noise. Therefore, the unknown parameter estimation by the least square method is performed by the evaluation function.

[0050]

[Equation 7]

The value of the equation (4) that minimizes (7) is obtained. The estimated value of the equation (4) that minimizes the equation (7) can be expressed by the following equation (8) according to the congruent least squares method (for example, “Introduction to Robust Adaptive Control”, Kimio Kanai). Author, Ohmsha, or System Control Information Library 9
See "Introduction to System Identification", Toru Katayama, Asakura Shoten).

[0052]

[Equation 8]

(8) Next, from c1 and c2 thus identified, the resonance frequency ω
Ask for. Parameters c1, c of the second-order discrete-time model
2 and the resonance frequency ω and the damping coefficient ζ, the sampling period is T, and the following formulas (9) and (1
Equation (0) is obtained.

[0054]

[Equation 9]

(9)

[0056]

[Equation 10]

(10) Therefore, the resonance frequency ω and the damping coefficient ζ can be calculated by the following equations (11) and (12), respectively.

[0058]

[Equation 11]

(11)

[0060]

[Equation 12]

(12) As described above, the resonance frequency ω obtained from the equation (11)
It has already been described that the value is affected by the tire temperature related value, for example, the outside air temperature, and the effect needs to be corrected. As a means for estimating a tire temperature-related value (for example, outside air temperature), which is the gist of the present invention, the principle that the outside air temperature can be estimated by the temperature sensing element 6i set in the ECU 6 will be described below with reference to FIG. .

FIG. 6 schematically shows the relationship between the outside air temperature and the temperature sensing element set in the ECU 6 from a typical traveling pattern of the vehicle for one day. In this case, considering the most general condition, the first ignition switch (IG)
Before turning on, it is considered that the vehicle was left in a stopped state for a sufficient time and the E / G started. In such a situation, the temperature of the temperature sensing element set in the ECU 6 can be considered to be the same temperature as the vehicle interior temperature because it does not generate self-heating due to energization and is not affected by past temperature history. .

On the other hand, considering the relationship between the indoor temperature of the vehicle and the outside air temperature, it can be considered that the indoor temperature of the vehicle and the outside air temperature become substantially equal when the effect of solar radiation is small. Therefore, since the temperature sensing element and the vehicle interior temperature are equal, and further the vehicle interior temperature and the outside air temperature are equal,
At point a, the temperature sensing element and the outside air temperature become equal,
The temperature sensing element makes it possible to estimate the outside air temperature. After that, the vehicle is left for a long period of time before the ignition switch is turned on and the ignition switch is turned on when the temperature of the temperature sensing element and the outside air temperature are equal to each other, which is referred to as a cold start.

As shown in FIG. 6, when the IG switch is turned on and the vehicle is started, the temperature of the temperature sensing element provided in the ECU 6 is at a balance point b between self-heating due to energization and the temperature inside the vehicle. It becomes temperature. When the surroundings are cooled by the air conditioner, the balance point b is lower than the point b like the point b ′. Next, when the ignition switch is turned off and the vehicle is stopped, the temperature sensing element is also de-energized, so that the temperature of the temperature sensing element starts decreasing and drops to point c.

However, considering the general usage of the vehicle, there is not always a sufficient vehicle stop time until the temperature history of the temperature sensing element disappears, and as shown at the time point c, cooling is performed. In some cases, the ignition switch may be turned on again to start traveling. Note that point a
Is ON for the first ignition switch in FIG.
At this point c, the second ignition switch in FIG. 6 is turned on.

As described above, the temperature of the temperature sensing element set in the ECU 6 converges again to the outside air temperature and reaches the point d while being affected by the ignition switch OFF duration, radiant heat and air conditioner. To do. As described above, considering the usage of the vehicle, as illustrated in FIG. 6, the temperature of the temperature sensing element set in the ECU 6 may be the same as the outside air temperature as indicated by the point a. It is considered to exist.

The point where the temperature of the temperature sensing element converges to the outside air temperature is point a, but heat is generated by energization after the ignition switch is turned on, which causes noise in the outside air temperature estimation. , It is not preferable to estimate the outside air temperature after the point a. Therefore, it is necessary to read the temperature of the temperature sensing element at the moment when the ignition switch is turned on.

The temperature of the temperature sensing element at the time of IG-ON is not necessarily converged to the outside air temperature like point a, but may be dragging the past temperature history like point c. . However, since it is the point a that can estimate the outside air temperature, in order to reliably capture the point a at which the temperature of the temperature sensing element converges to the outside air temperature, the IG must be preset a predetermined number of times.
-It is necessary to set ON. By properly selecting this predetermined number of times, it is possible to guarantee the opportunity that the point a, that is, the outside air temperature, matches the temperature of the temperature sensing element at least once within the predetermined number of times.

The predetermined number of times set here has no meaning in a long-term span in which the outside air temperature changes due to seasonal changes. Therefore, if the ignition switch is turned on every few days, it is possible to avoid fluctuations in the outside air temperature due to seasonal changes, and to guarantee at least one cold start. Next, let us consider the point a at which the temperature of the temperature sensing element converges to the outside air temperature and the temperature of the temperature sensing element at other times. The basic temperature characteristic of the temperature sensing element is basically higher than the ambient temperature (vehicle interior temperature) because of self-heating due to energization. The temperature of the temperature sensing element is cooled when the air conditioner is operating, but as described above, the temperature of the temperature sensing element is detected only at the moment when the ignition switch is turned on. The cooling effect of the air conditioner is considered to have almost no effect.

From these facts, among the temperatures of the temperature sensing element detected when the ignition switch is turned on a plurality of times, when the past temperature history is dragged, it has a characteristic that it is always higher than the vehicle interior temperature. Conceivable. On the contrary, when the temperature of the temperature sensing element is converged to the outside air temperature, it should be the lowest temperature among the temperatures of the temperature sensing element observed when the ignition switch is turned on a plurality of times.

From the above, among the temperatures of the temperature sensing element observed when the ignition switch is turned on a plurality of times, mi,
By setting the n value (minimum value) to the outside air temperature, the ECU 6
The outside air temperature can be estimated by the temperature of the temperature sensing element set to. FIG. 7 assumes FIG. 6 on a half-yearly basis. The greatest influence on tire pressure estimation is the fluctuation of the outside air temperature depending on the season. If the outside air temperature can be estimated at the point a at which the temperature of the temperature sensing element converges to the outside air temperature, the variation in the outside air temperature due to this season can be estimated, and the tire air pressure estimation accuracy improves.

FIG. 8 shows output characteristics of a generally known semiconductor element (diode) as an example of the temperature sensing element set in the ECU 6. As shown in FIG. 8, when a semiconductor element is used, excellent linearity can be obtained, and this can be realized at a relatively low cost. Hereinafter, a specific example of the air pressure determination processing of the tire air pressure estimation device according to the present invention will be described based on a flowchart showing the processing content of the ECU 6. Since the ECU 6 performs the same processing on each tire 1a to 1d, the flowchart described below shows only the processing relating to the tire 1a.

FIG. 9 is a flowchart showing an example in which the resonance frequency or the tire spring constant is corrected by a tire temperature related value (for example, an outside air temperature estimated value). First, when the ignition switch of the vehicle is turned on, the process proceeds to step 10 and the number of times the ignition switch is turned on is determined. In step 10, the ignition switch-O
If it is determined that the N number of times is the first time, step 70
Then, as the outside air temperature estimated value Temp, the temperature of the temperature sensing element set in the ECU 6 (tire temperature related value: outside air temperature estimated value) observed at the first ignition switch-ON is read.

Next, at step 10, if the ignition switch-ON count is the second or later, the routine proceeds to step 80, where the outside air temperature observation value Ti observed at the ignition switch-ON at that time is the past outside air temperature estimated value Temp.
If it is lower, in step 90, the outside air temperature estimated value T
The outside air temperature observation value Ti of this time is read as emp.

In step 80, if the outside air temperature observation value Ti observed by turning on the ignition switch at that time is not lower than the past (previous) outside air temperature estimated value Temp, the outside air temperature estimated value Temp is updated. No, the process proceeds to the next step 100. As a result, the lowest estimated outside air temperature is obtained from the number of times the ignition is turned on 1 to n times. It should be noted that, for example, about 5 to 10 times may be used as a reference for n times, and the reference number of times is such that the vehicle is left for a long time while the ignition switch is OFF,
The estimated average number of times until the vehicle is started by a drive or the like and then left for a long time may be set for each vehicle type.

First, at step 100, a pulse signal obtained by waveform-shaping the AC signal output from the pickup coil 2b is read, the pulse length is divided by the pulse time, and the wheel speed Vx is calculated independently for each wheel. As shown in the flowchart, the following linear prediction method
Based on the equation), the calculation for obtaining the tire resonance frequency or the tire spring constant is started.

The filter section in step 110 extracts a vibration frequency component used for tire pressure estimation from the wheel speed signal including the tire vibration frequency component calculated in step 100, in order to extract a predetermined frequency range ( A narrow band filter (hereinafter referred to as a band pass filter) set to about 30 Hz to 50 Hz or about 60 to 90 Hz performs a process of relatively increasing the signal strength of the vibration frequency component.

The wheel speed signal passed through the band pass filter is the wheel speed signal y defined in the above description of the principle.
(K) That is, the equation (3) is obtained. The parameter identifying unit 120 is a unit that identifies the parameters c1 and c2 of the discrete-time model from the wheel speed signal y (k) extracted by the bandpass filter 110 based on the equation (8). .

Next, in the resonance frequency converter of step 130, the parameter c output in step 120 is output.
1 and c2, defined in the above description of the principle (11)
The resonance frequency ω1 is obtained from the equation. Next Step 14
0 is a portion for correcting the resonance frequency ω1 calculated in step 130 with the outside air temperature estimated value Temp. The estimated outside air temperature Temp, which serves as a reference for the correction here, is 1
It is the minimum value of the estimated outside air temperature measured immediately after the ignition switch is turned ON during the n times. As described above, the calculated resonance frequency ω1 is affected by the outside air temperature,
Even if the tire pressures are the same, they are affected by the outside air temperatures as shown in FIG.

That is, as shown in FIG. 10, even if the air pressure is the same, the resonance frequency ω increases as the outside air temperature T decreases. It is considered that this is because as the outside air temperature T becomes lower, the rubber portion of the tire rubber portion (particularly the tire side wall portion) becomes harder and the spring constant increases. Therefore, in order to prevent such deterioration of the detection accuracy of the resonance frequency ω due to the outside air temperature T, the resonance frequency ω is corrected based on the outside air temperature T (see FIG. 1).
1) is required.

For this purpose, the resonance frequency correction unit (step 140) has a correction map as shown in FIG. 12, and the calculated resonance frequency ω1 may be corrected based on this correction map. become. Here, if the correction amount Δω of the resonance frequency ω based on the estimated outside air temperature Temp estimated in step 90 is set, the correction resonance frequency ω ′ at this time can be expressed by the following formula.

[0082]

Ω ′ = ω−Δω (13) Next, in step 150, as the threshold value for determining the decrease in air pressure, the determination value set in advance and the corrected resonance frequency ω ′ calculated above are calculated. Based on the comparison, the presence or absence of abnormality in the air pressure of the corresponding tire is determined.

In step 150, the air pressure drop determination section determines the tire air pressure abnormality corresponding to each wheel independently for each wheel. If it is determined that the air pressure has dropped, the routine proceeds to step 160, where the warning lamp of the display 7 in FIG. 1 is driven, and it becomes possible to notify the driver. In addition, in the embodiment of the lamp, it is possible to independently display the four tire pressure abnormalities of the four wheels, or to display only one lamp that merely indicates that one of the tires is abnormal. .

For reference, FIG. 13 shows the result of calculating the tire resonance frequency by the tire air pressure estimating apparatus according to the present embodiment. According to this, it becomes possible to read that the estimated resonance frequency of the tire changes almost linearly with respect to the tire air pressure. In the embodiments described above, the vibration frequency component is extracted from the wheel speed signal, and the resonance frequency or the tire spring constant used for tire pressure estimation is set to the tire temperature related value (for example, the outside air temperature).
Although it was a case of correcting based on, in the example shown below,
This is an example of correcting the determination value of whether or not the tire air pressure is abnormal based on the calculated tire resonance frequency or tire spring constant based on a tire temperature related value (for example, outside air temperature).

FIG. 14 shows the flowchart. Since the content of each step from step 10 to step 230 until the resonance frequency ω1 is calculated is the same as the processing content of the first embodiment, it is omitted here. Step 24
At 0, the estimated outside air temperature Tem obtained in step 90
This is a portion for correcting the tire air pressure drop determination value ωk based on p. Assuming that the correction amount of the air pressure decrease determination value is Δωk, the corrected air pressure determination value ωk ′ is as shown in Expression 22. For the correction, the correction map shown in FIG. 15 is used.

[0086]

Ωk ′ = ωk−Δωk (14) Next, in step 250, the previously calculated resonance frequency ω1 and the magnitude of the air pressure drop determination value ωk are compared, and the resonance frequency ω1 becomes the determination value ωk. If it is turned on, it is determined that the tire pressure is abnormally low, and the routine proceeds to step 260, where the indicator 7 in FIG. 1 is driven to notify the driver of the low air pressure.

As described above, according to the tire air pressure estimating apparatus of the embodiment, (a) a temperature sensing element is provided in the signal processing device, and the tire temperature related value which is the detected outside air temperature information is stored. Since the resonance frequency is corrected accordingly, the estimation accuracy of the tire air pressure estimated based on the resonance frequency is naturally high. (B) Further, the tire / suspension system of the vehicle is approximated by a linear prediction model such as the above equation (3), and the parameters of the model are identified by the least squares method to obtain the tire pressure of the wheel speed signal y (k). Since the dependent resonance frequency is estimated, the required calculation amount and memory capacity can be significantly reduced as compared with, for example, the case of using the fast Fourier transform (FFT). And so on, excellent effects can be achieved.

In each of the above embodiments, the batch type least squares method is used to identify the parameters c1 and c2 of the introduced linear prediction model.
It goes without saying that multiplication and the like can be used as well. Further, including the case where the recursive least squares method is adopted in this way, as the linear prediction model, a model of third order or higher can be introduced. However, as the order increases, the required calculation amount and memory capacity also increase. Considering that each tire has only one resonance point depending on its air pressure, the linear prediction model may have a second order.

Further, compared with the case of introducing these linear prediction models, the resonance frequency extraction unit 213 is disadvantageous in terms of the required calculation amount and memory capacity.
In addition, a fast Fourier transform (FFT) is applied to a signal including the tire vibration component output from the wheel speed sensor 10 and the wheel speed calculation unit 211, which are vibration component output means.
A configuration in which the calculation is performed and the resonance frequency is calculated from the frequency spectrum obtained by the FFT calculation is also effective in suppressing the decrease in the tire air pressure estimation accuracy by the conventional device.

Further, such FFT is used for extracting the resonance frequency.
In the device of each of the above-described embodiments, including the case where the calculation is adopted, the extracted resonance frequency is corrected by the tire temperature related value, and the tire pressure is estimated based on the corrected resonance frequency. However, with respect to the resonance frequency, the extracted value may be used as it is to estimate the tire air pressure, and the estimated tire air pressure may be corrected according to the influence amount of the tire temperature-related value.

In each of the above embodiments, the device for estimating the tire air pressure and issuing a warning when the air pressure has dropped has been described. However, taking the electronic control unit 6 of FIG. 4 as an example, the estimated air pressure is sent as a tire air pressure signal to, for example, a brake control computer or a traction control computer, and the same device is used as a correction device in these controls. You can also do it.

As the tire temperature-related value, not only the outside air temperature but also the following conditions can be used together. For example, the vehicle body speed is somewhat high (for example, 60 km / s).
(Above) and the continuous running time (or distance) of the vehicle is a predetermined time (for example, 90 minutes or more), the tires generate heat due to the running of the vehicle. It is possible that the temperature will rise. Therefore, if the vehicle body speed is equal to or higher than the predetermined value and the continuous traveling time is equal to or longer than the predetermined time, the tire temperature may be estimated by correcting the outside air temperature detected by the temperature sensing element 40 on the plus side. Good. Further, when the correction is performed based on such a condition, it may be executed only when the outside air temperature is higher than a predetermined temperature (for example, 25 ° C.). This is because when the outside air temperature is low, it is considered that the tire does not generate heat so much even if the vehicle runs at a high speed for a continuous time.

Further, for example, in these brake control and traction control, the maximum value of the wheel speed of each wheel may be set as the vehicle speed of the vehicle. On the other hand, in those wheels, when the tire air pressure decreases, the wheel radius becomes smaller, and the wheel speed apparently becomes faster.
Therefore, if the apparently increased wheel speed is corrected based on the tire pressure signal, brake control and traction control will not be performed based on an incorrect vehicle speed.

Besides, the tire air pressure is deeply related to the friction coefficient of the road surface and the like. Therefore, the tire air pressure signal can also be used as a signal for correcting the friction coefficient and the like. As described above, the tire pressure estimation (determination) in the present invention is performed by the anti-skid control EC
The temperature sensing element 6i is disposed in the body of the U or the traction control ECU or the like. At this time, if the temperature sensing element 6i is disposed in the metallic or resinous ECU cover, the suppression of dust and the like can be simply prevented. It should be noted that a tire air pressure estimation microcomputer and a temperature sensing element 6i are provided in an antiskid control ECU which is a signal processing device 8 electronic control device for antiskid control and a body is provided in a cover of the electronic control device for antiskid control. You may assemble to.

Further, in the embodiment shown in FIG. 9, the temperature Ti detected after the second ignition switch ON is detected.
Is smaller than the estimated outside air temperature Temp, the resonance frequency is all corrected in step 140 with the estimated outside air temperature Temp based on the updated temperature.
In the above-described embodiment, the number of times the ignition switch is turned on in step 10 is determined by
With a time counter that is driven even when the ignition is off, the elapsed time from when the ignition switch is turned off to when the next ignition switch is turned on is a reference time (for example, 24 hours, that is, the ignition switch is turned on and off when the driver's vehicle is in use). The number of times the ignition switch is turned ON = i may be cleared depending on whether or not the time in which the maximum duration of driving and stopping continues is considered as a reference).

Further, regardless of such estimation of the estimated outside air temperature, the following may be performed. For example, in FIG. 9, step 10 is performed to turn off the ignition.
It is determined whether or not the counter value of the time counter, which is also driven at times, satisfies the reference time (for example, 5 hours, that is, the elapsed elapsed time of ignition OFF capable of detecting the point a in FIG. 6 is used as the reference time). Alternatively, only the estimated outside air temperature detected when the determination is affirmative may be used and the process may proceed to step 100 and below.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration relating to a tire pressure estimation device of the present invention.

FIG. 2 is a block diagram showing a configuration relating to a tire pressure estimation device of the present invention. The characteristic view which shows the physical property change characteristic of a diode.

FIG. 3 is a characteristic map showing the relationship between tire pressure and resonance frequency.

FIG. 4 is a block diagram showing a schematic configuration of a signal processing device of the tire pressure estimation device.

FIG. 5 is a physical model relating to vibration of a tire suspension system.

FIG. 6 is a characteristic diagram showing an opportunity where the temperature of the outside air and the temperature of the vehicle interior or the temperature of the element in the signal processing device match.

FIG. 7 is a characteristic diagram showing characteristics when the opportunity of matching the outside air temperature with the temperature of the vehicle interior or the temperature of the element in the signal processing device is seen in a long-term span.

FIG. 8 is a characteristic diagram showing changes in physical properties of a diode.

FIG. 9 is a flowchart showing an embodiment of the present invention.

FIG. 10 is a characteristic diagram showing an outside air temperature characteristic of a resonance frequency.

FIG. 11 is a graph showing how the resonance frequency is corrected by the outside air temperature.

FIG. 12 is a graph showing a correction amount of the resonance frequency depending on the outside air temperature.

FIG. 13 is a characteristic diagram showing a relationship between resonance frequency and tire air pressure.

FIG. 14 is a follow chart showing an embodiment of the present invention.

FIG. 15 is a characteristic diagram showing a relationship between a tire air pressure determination value and an outside air temperature.

[Explanation of symbols]

1 ... Wheel, 2-4 ... Wheel speed sensor, 11 ... Rotor, 1
2 ... Tooth (object to be detected), 6 ... Signal processing device, 6j ... Cover, 600 ... Microcomputer, 601 ... CPU,
602 ... ROM, 603 ... RAM, 6a-d ... Resonance point detecting section, 211 ... Wheel speed calculating section, 6i ... Temperature sensing element.

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yuichi Inoue, 1-1, Showa-cho, Kariya city, Aichi Prefecture, Denso Co., Ltd. (72) Inventor, Nobuyoshi Onoki 1-1-chome, Showa-cho, Aichi prefecture, Ltd., Denso Co., Ltd. (56) References JP-A-8-72515 (JP, A) JP-A-6-344734 (JP, A) JP-A-9-309304 (JP, A) JP-A-11-20429 (JP, A) Kaihei 6-278422 (JP, A) JP 5-133831 (JP, A) JP 6-328920 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) B60C 23 / 06-23/20 G01L 17/00-17/02

Claims (13)

(57) [Claims] 1. A vibration component output means for outputting a signal containing a tire vibration component when a vehicle is running, and an extraction for extracting a resonance frequency or a tire spring constant of the vibration component from the outputted signal containing a tire vibration component. Means, an air pressure estimating means for estimating the tire air pressure based on the extracted resonance frequency or the tire spring constant, and an external factor affecting the extracted resonance frequency or the spring constant related to the tire temperature. The tire temperature related value extraction means for extracting the tire temperature related value, and the correction means for correcting the influence on the resonance frequency or the tire spring constant according to the extracted tire temperature related value, the tire temperature related value extraction Means is the tire
Signal processing device for processing the signal containing the vibration component of
The tire temperature-related value using the element provided in the storage
A tire air pressure estimation device characterized by extracting the outside air temperature as . 2. The tire temperature related value extraction means detects a time when a temperature of an element in the signal processing device has a predetermined correlation with an outside air temperature, and determines the temperature of the element detected at that time. tire air pressure estimating apparatus according to claim 1, characterized in that for estimating the tire temperature-related value each. 3. The tire temperature related value extraction means estimates the tire temperature related value based on a plurality of detected values detected immediately after the ignition switch of the vehicle is turned on. The tire air pressure estimation device according to claim 1 or 2 . 4. The tire temperature related value extraction means estimates the tire temperature related value based on a minimum value of a plurality of detection values detected immediately after an ignition switch of a vehicle is turned on. Claim 1 thru Claim
3. The tire pressure estimation device according to any one of 3 above. 5. The correcting means corrects at least one of the resonance frequency, the tire spring constant or the estimated tire air pressure according to the outside air temperature extracted by the tire temperature related value extracting means. The tire pressure estimation device according to any one of claims 1 to 4 . 6. A vibration component output means for outputting a signal including a tire vibration component when a vehicle is running, and an extraction for extracting a resonance frequency or a tire spring constant of the vibration component from the outputted signal including a tire vibration component. Means, an air pressure estimating means for estimating the tire air pressure based on the extracted resonance frequency or the tire spring constant, and an external factor affecting the extracted resonance frequency or the spring constant related to the tire temperature. Based on the relationship between the tire temperature related value extraction means for extracting the tire temperature related value and the air pressure estimated by the air pressure estimation means and a predetermined determination value, it is determined whether or not the air pressure is abnormal. The determination means and the determination value in the determination means are the tire temperature related values extracted by the tire temperature related value extraction means. And a correcting means for correcting, based on the value, the tire temperature associated value extracting means, said tire
Signal processing device for processing the signal containing the vibration component of
The tire temperature-related value using the element provided in the storage
A tire air pressure estimation device characterized by extracting the outside air temperature as . 7. The extracting means introduces a linear prediction model for the same vibration into a time-series signal containing the vibration component of the tire output from the vibration component output means, and sets parameters of the introduced linear prediction model. The tire air pressure estimation device according to any one of claims 1 to 7 , which comprises a linear prediction means for identifying and extracting a resonance frequency of the vibration component. 8. The linear predicting means, where k is the number of samplings, y (k) is a time-series signal including a tire vibration component, and m (k) is a disturbance, ## EQU00001 ## y (k) =-c1y (k-1) -c2y (k-2) + m (k) (1) is introduced and parameter identifying means for identifying each of the parameters c1 and c2, and these are identified. The tire air pressure estimating device according to claim 7 , further comprising: a resonance frequency calculating unit that calculates the resonance frequency based on the parameters c1 and c2. 9. The tire pressure estimating device according to claim 8 , wherein the parameter identifying means identifies the parameters c1 and c2 by a least square method. 10. The extracting means includes FFT calculating means for performing a fast Fourier transform (FFT) operation on a signal including a tire vibration component output from the vibration component outputting means, and the air pressure estimating means includes: The tire air pressure estimating device according to any one of claims 1 to 9 , wherein the tire air pressure is estimated from a resonance frequency of a frequency spectrum obtained by an FFT calculation. 11. A wheel speed detecting means for detecting a wheel speed signal of each wheel when the vehicle is running, and a tire vibration included in the wheel speed signal based on the wheel speed signal detected by the wheel speed detecting means. Extraction means for extracting the resonance frequency or tire spring constant of the tire vibration component from the component, air pressure estimation means for estimating the tire air pressure based on the extracted resonance frequency or tire spring constant, and this air pressure estimation means Based on the relationship between the air pressure and a predetermined determination value, a determination means for determining whether or not the air pressure is abnormal, and a signal processing device provided in the cover, the extracted resonance frequency or Among the external factors that influence the spring constant, a tire temperature related value related to the tire temperature is extracted, and the determination means Has a correction means for correcting the resonance frequency or the tire spring constant at the position based on the tire temperature related value, and detects the temperature in the signal processing device as the outside air temperature in order to extract the tire temperature related value used in the correction means. A tire pressure estimation device, wherein a temperature sensing element is arranged in the signal processing device. 12. A wheel speed detecting means for detecting a wheel speed signal of each wheel when the vehicle is traveling, and a tire vibration included in the wheel speed signal based on the wheel speed signal detected by the wheel speed detecting means. Extraction means for extracting the resonance frequency or tire spring constant of the tire vibration component from the component, air pressure estimation means for estimating the tire air pressure based on the extracted resonance frequency or tire spring constant, and this air pressure estimation means Based on the relationship between the air pressure and a predetermined determination value, the determination means for determining whether the air pressure is abnormal, using the wheel speed of each wheel calculated based on the wheel speed signal An anti-skid control means for controlling a wheel braking force applied to each wheel so as to alleviate the lock tendency of each wheel. A signal processing device provided therein, extracting a tire temperature related value related to a tire temperature among external factors that affect the extracted resonance frequency or spring constant, and determine the determination value in the determination means as described above. The signal processing device includes a correction unit that corrects based on a tire temperature-related value, and a temperature sensing element that detects the temperature in the signal processing device as the outside air temperature in order to extract the tire temperature-related value used in the correction unit. A tire air pressure estimating device characterized by being arranged inside. 13. A wheel speed detecting means for detecting a wheel speed signal of each wheel when the vehicle is traveling, and a tire vibration included in the wheel speed signal based on the wheel speed signal detected by the wheel speed detecting means. Extraction means for extracting the resonance frequency or tire spring constant of the tire vibration component from the component, air pressure estimation means for estimating the tire air pressure based on the extracted resonance frequency or tire spring constant, and this air pressure estimation means Based on the relationship between the air pressure and a predetermined determination value, the determination means for determining whether the air pressure is abnormal, using the wheel speed of each wheel calculated based on the wheel speed signal An anti-skid control means for controlling the wheel braking force applied to each wheel so as to alleviate the lock tendency of each wheel. In order to extract the tire temperature related value related to the tire temperature among the external factors that affect the extracted resonance frequency or spring constant, the temperature inside the signal processing device is adjusted to outside air. A temperature sensing element that detects the temperature is arranged in the signal processing device, and a correction value that corrects the determination value in the determination means or the resonance frequency or the spring constant extracted by the extraction means based on the tire temperature related value. Further, the temperature detection by the temperature sensing element is performed a predetermined number of times immediately after the ignition switch of the vehicle is turned on, and a detection value by the temperature sensing element used as the outside air temperature is obtained by the plurality of detections. As a minimum value of the detected values obtained, the correction means performs correction based on this minimum value. Tire air pressure estimation device to.