JP4780035B2 - Air conditioner for vehicles - Google Patents

Description

  The present invention relates to a vehicle air conditioner and a control method therefor, and more particularly, to a vehicle air conditioner that automatically optimizes an air condition according to a passenger's sense of temperature or situation and a control method therefor.

  In general, in a vehicle air conditioner, the temperature, air volume, etc. of conditioned air sent from each outlet are automatically determined according to various parameters such as a set temperature, an outside air temperature, an inside air temperature, and an amount of solar radiation. However, there are individual differences in the passenger's sense of warmth (hot, cold, etc.). For this reason, the automatically determined temperature and air volume of the conditioned air may not be optimal values. In such a case, the passenger operates the operation panel as necessary to adjust the air conditioner so as to increase or decrease the set temperature, or increase or decrease the air volume. Therefore, when the passenger changes the set temperature, air volume, etc. by operating the operation panel, learning control is incorporated to correct the relational expressions that determine the temperature and air volume of the conditioned air using the various parameters at that time. An air conditioning control device has been developed (see Patent Document 1).

  By the way, the passenger changing the setting of the air conditioner is not necessarily due to a difference in warmth or the like, but may be due to an external environmental factor under a specific situation. For example, when the passenger is exercising immediately before driving, the set temperature may be lower than usual. In addition, in order to prevent the exhaust gas of the vehicle from filling the interior of the vehicle when a traffic jam is always reached, the inside air circulation mode may be set. However, the air conditioning control device described in Patent Document 1 cannot distinguish whether the setting of the air conditioning device has been changed due to an external environmental factor under a specific situation or whether the setting has been changed due to a difference in warmth or the like. For this reason, it has been difficult to automatically optimize the air conditioning temperature and the like in accordance with the specific situation as described above.

  On the other hand, an air conditioner for automobiles has been developed in which data indicating the position of a traveling vehicle is added to learning data so that temperature adjustment learning and other learning can be distinguished (see Patent Document 2). However, the automotive air conditioner described in Patent Document 2 only determines whether or not to perform temperature adjustment learning with reference to the position and date and time of the host vehicle, and a specific determination method is described. In addition, it has not been considered to optimize the air conditioning temperature in accordance with the specific situation as described above.

JP 2000-293204 A JP 2000-62431 A

  SUMMARY OF THE INVENTION An object of the present invention is to provide a vehicle air conditioner and a control method thereof that can recommend not only optimization according to a passenger's sense of temperature but also optimal air conditioning settings according to a specific situation to the passenger. There is.

  Another object of the present invention is to provide a vehicle air conditioner capable of automatically learning an optimal air conditioning setting for a passenger's sense of warmth or a specific situation, and a control method thereof.

  Still another object of the present invention is to more appropriately recommend the optimal air conditioning setting for the passenger by considering the reliability of the data used for learning or the response during the passenger's setting operation. An object is to provide a vehicle air conditioner and a control method thereof.

A vehicle air conditioner according to one embodiment of the present invention is provided. The vehicle air conditioner includes a storage unit (61) that stores, as a learning data group, a plurality of state information representing a state relating to the vehicle acquired by the information acquisition unit (51 to 53, 55 to 58), and the state information. A learning unit (68) that uses a learning data group to construct a probability model for calculating a recommendation probability for the occupant to perform a predetermined setting operation by inputting, and a probability model constructed by the learning unit (68) A recommendation probability calculation unit (64) for inputting a current state information representing a current state of the vehicle and calculating a recommendation probability for performing a predetermined setting operation, and a recommendation probability correction unit (for correcting the recommendation probability according to a predetermined rule) 65), a control information correction unit (66) for correcting the setting information or control information related to the setting operation of the occupant so as to be a predetermined setting operation according to the corrected recommendation probability, and the corrected setting Information According to the control information, with the air-conditioning control unit that performs air conditioning control of the air conditioning unit for supplying conditioned air into the vehicle (10) and (67).

As described in claim 1, it is preferable that the recommendation probability correcting unit (65) increases the recommendation probability as the reliability of the current state information is higher.
Alternatively, as described in claim 2 , the recommendation probability correcting unit (65) preferably increases the recommendation probability as the number of state information included in the learning data group is smaller.

Further, as described in claim 3 , the recommendation probability correcting unit (65) has a large difference between the setting information or control information corrected to be a predetermined setting operation and the setting information or control information before the correction. It is preferable to increase the recommendation probability.

Furthermore, as described in claim 4, it is preferable that the recommendation probability correcting unit (65) increases the recommendation probability as the frequency of the setting operation performed on the vehicle air conditioner increases.
Alternatively, as described in claim 5 , the recommendation probability correction unit (65) increases the recommendation probability as the frequency of the setting operation performed on the vehicle air conditioner when the current state information has a predetermined value is increased. It is preferable.

Also, the automatic air conditioning system for a vehicle according to the present invention presents a passenger the contents of a predetermined setting operation, and confirmation operation unit for confirming the occupant whether to perform a predetermined setting operation to (59) If it is confirmed that the predetermined setting operation is performed through the confirmation operation unit (59), the control information correction unit (66) preferably corrects the setting information or the control information.

In this case, as described in claim 6 , the storage unit (61) continues from the presentation by the confirmation operation unit (59) until an operation for determining whether or not a predetermined setting operation is performed by the passenger. It is preferable that the recommendation probability correction unit (65) increases the recommendation probability as the average value of the reaction time is shorter.

Alternatively, as described in claim 7 , the storage unit (61) is provided by the passenger through the confirmation operation unit (59) and the number of presentations that the predetermined operation is presented by the confirmation operation unit (59). The number of affirmative operations in which an operation for determining to perform a predetermined setting operation is performed is stored in association with the probability model, and the recommendation probability correcting unit (65) increases the recommendation probability as the ratio of the number of affirmative operations to the number of presentations increases. Is preferably increased.

Also, the vehicle air conditioner according to another embodiment of the present invention is provided. The vehicle air conditioner includes a storage unit (61) that stores, as a learning data group, a plurality of state information that represents a state relating to the vehicle acquired by the information acquisition unit (51-53, 55-58), and learning data A data weighting unit (69) that weights state information included in the group according to a predetermined rule, and a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting the state information, A learning unit (68) constructed using groups, and a probability model constructed by the learning unit (68) are input with current state information representing the current state of the vehicle to calculate a recommendation probability, and according to the recommendation probability Then, according to the control information correction unit (66) for correcting the setting information or control information related to the setting operation of the occupant so as to be a predetermined setting operation, and the corrected setting information or control information, And a air-conditioning control unit that performs air conditioning control of the air conditioning unit to supply in the vehicle (10) (67) for regulating air.

Further, as described in claim 8, it is preferable that the data weighting unit (69) performs weighting so that the higher the reliability of the state information included in the learning data group, the higher the specific gravity of the state information.
Alternatively, as described in claim 9, when the number of state information included in the learning data group is equal to or less than a predetermined number, the data weighting unit (69) compares the number of state information with a number greater than the predetermined number. Thus, it is preferable to perform weighting so as to increase the specific gravity.

Furthermore, as described in claim 10 , the information acquisition unit (51-53, 55-58) acquires the state information when the passenger performs the setting operation of the vehicle air conditioner, and the data weighting unit (69 ) Is preferably weighted so that the greater the difference between the setting information or control information before performing the setting operation and the setting information or control information after performing the setting operation, the higher the specific gravity of the state information.

Furthermore, as described in claim 11, it is preferable that the data weighting unit (69) performs weighting so that the specific gravity of the state information acquired when the frequency of the setting operation performed on the vehicle air conditioner is high. .
Alternatively, as described in claim 12 , the data weighting unit (69) increases the frequency of the setting operation performed on the vehicle air conditioner when the state information included in the learning data group has a predetermined value. It is preferable to perform weighting so that the specific gravity of the state information having a predetermined value is high.

Also, the vehicle air conditioner according to the present invention presents a passenger the contents of a predetermined setting operation, and have a confirmation operation unit for confirming the passenger (59) whether to perform a predetermined setting operation When it is confirmed that the predetermined setting operation is performed through the confirmation operation unit (59), the control information correction unit (66) preferably corrects the setting information or the control information.

In this case, as described in claim 13 , the storage unit (61) continues from the presentation by the confirmation operation unit (59) until the passenger performs an operation for determining whether or not to perform a predetermined setting operation. It is preferable that the data weighting unit 69 increases the specific gravity of the state information related to the recommendation probability calculated for the predetermined setting operation as the average value of the reaction time is shorter.
Alternatively, as described in claim 14 , the storage unit (61) is provided by the passenger through the confirmation operation unit (59) and the number of presentations that the predetermined operation is presented by the confirmation operation unit (59). The number of affirmative operations in which an operation for determining the setting operation is performed is stored in association with the probability model, and the data weighting unit (69) sets a predetermined setting as the ratio of the number of affirmative operations to the number of presentations increases. It is preferable to increase the specific gravity of the state information related to the recommendation probability calculated for the operation.

In addition, as described in claim 15 , the data weighting unit (69) weights the state information included in the learning data group so that the specific gravity of the state information having a longer elapsed time is lower. It is preferable.

Also, the vehicle air conditioner according to another embodiment of the present invention is provided. The vehicle air conditioner includes a storage unit (61) that stores, as a learning data group, a plurality of state information representing a state relating to the vehicle acquired by the information acquisition unit (51 to 53, 55 to 58), and the state information. A learning unit (68) that uses a learning data group to construct a probability model for calculating a recommendation probability for the occupant to perform a predetermined setting operation by inputting, and a probability model constructed by the learning unit (68) A recommendation probability calculation unit (64) for inputting a current state information representing a current state of the vehicle and calculating a recommendation probability for performing a predetermined setting operation, and a threshold setting unit (set a predetermined threshold value according to a predetermined rule) 70) and a control information correction unit (66) that corrects the setting information or control information related to the occupant setting operation so as to be a predetermined setting operation when the recommendation probability is equal to or higher than the first threshold. Setting information Has in accordance with the control information, the air conditioning control unit for air conditioning control of the air-conditioning unit for supplying the conditioned air inside the vehicle (10) and (67).

According to the sixteenth aspect of the present invention, in the vehicle air conditioner according to the present invention, the recommendation probability obtained by the recommendation probability calculating unit (64) is less than the first threshold and lower than the first threshold. If it is equal to or greater than the second threshold value, it has a confirmation operation unit (59) for presenting the content of the predetermined setting operation to the passenger and confirming with the passenger whether or not to perform the predetermined setting operation. When it is confirmed that the predetermined setting operation is performed through the unit (59), it is preferable that the control information correction unit (66) corrects the setting information or the control information.

In this case, as described in claim 17, it is preferable that the threshold setting unit (70) lowers the first threshold or the second threshold as the reliability of the current state information is higher.
Alternatively, as described in claim 18 , the threshold setting unit (70) preferably lowers the first threshold or the second threshold as the number of state information included in the learning data group is smaller.

Furthermore, as described in claim 19 , the threshold value setting unit (70) has a large difference between the setting information or control information corrected so as to be a predetermined setting operation and the setting information or control information before the correction. It is preferable to lower the first threshold value or the second threshold value.

Further, as set forth in claim 20, it is preferable that the threshold value setting unit (70) lowers the first threshold value or the second threshold value as the frequency of the setting operation performed on the vehicle air conditioner increases.
Alternatively, as described in claim 21 , the threshold value setting unit (70) increases the first threshold value or the first threshold value as the frequency of the setting operation performed on the vehicle air conditioner when the current state information has a predetermined value. It is preferable to lower the threshold value of 2.

Further, as described in claim 22 , the storage unit (61) has a reaction time from the presentation by the confirmation operation unit (59) until an operation for determining whether or not to perform a predetermined setting operation by the passenger is performed. The threshold setting unit (70) preferably lowers the first threshold or the second threshold as the average value of the reaction time is shorter.

Further, as described in claim 23 , the storage unit (61) is provided by the passenger through the confirmation operation unit (59) and the number of presentations that the confirmation operation unit (59) is presented to perform a predetermined setting operation. The number of affirmative operations in which an operation for determining the setting operation is performed is stored in association with the probability model, and the threshold value setting unit (70) increases the first threshold value as the ratio of the number of affirmative operations to the number of presentations increases. Alternatively, it is preferable to lower the second threshold value.

Furthermore, according to another aspect, according to another aspect of the present invention, a control method for a vehicle air conditioner having a conditioning unit for supplying conditioned air into the vehicle (10) is provided. The control method includes a step of storing a plurality of state information representing a state relating to the vehicle as a learning data group, and a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting the state information. A step of constructing using a learning data group, a step of inputting current state information representing the current state of the vehicle into a probability model, calculating a recommended probability of performing a predetermined setting operation, and a recommended probability according to a predetermined rule The setting information or control information related to the occupant setting operation according to the corrected recommendation probability, and the corrected setting information or control information. And performing an air conditioning control of the air conditioning unit (10).

Furthermore, according to another aspect, according to another aspect of the present invention, a control method for a vehicle air conditioner having a conditioning unit for supplying conditioned air into the vehicle (10) is provided. The control method includes a step of storing a plurality of state information representing a state relating to the vehicle as a learning data group, a step of weighting the state information included in the learning data group according to a predetermined rule, and inputting the state information. A step of constructing a probability model for calculating a recommendation probability for the occupant to perform a predetermined setting operation using the learning data group, and inputting the current state information representing the current state of the vehicle into the probability model, A step of calculating a recommendation probability of performing the setting operation, a step of correcting setting information or control information related to the setting operation of the occupant so as to be a predetermined setting operation according to the recommendation probability, and a corrected setting And air conditioning control of the air conditioning unit (10) according to the information or control information.

Furthermore, according to another aspect, according to another aspect of the present invention, a control method for a vehicle air conditioner having a conditioning unit for supplying conditioned air into the vehicle (10) is provided. The control method includes a step of storing a plurality of state information representing a state relating to the vehicle as a learning data group, and a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting the state information. A step of constructing using the learning data group, a step of inputting current state information representing the current state of the vehicle into the probability model, calculating a recommended probability of performing a predetermined setting operation, and a predetermined rule according to a predetermined rule A step of setting a threshold value, a step of correcting setting information or control information related to an occupant setting operation when the recommendation probability is equal to or higher than a predetermined threshold value, to be a predetermined setting operation; And performing air conditioning control of the air conditioning unit (10) according to the control information.

The state information represents a state related to the vehicle, and air conditioning information inside and outside the vehicle (specifically, outside air temperature, inside air temperature and solar radiation amount), vehicle position information, vehicle behavior information, time information or vehicle Including at least one of the biological information of the passengers. The predetermined setting operation refers to an operation for changing the operating state of the vehicle air conditioner, such as changing the set temperature, changing the air flow, setting the inside air circulation mode, or operating or stopping the defroster. The setting information refers to information that defines the operation of the vehicle air conditioner, such as the set temperature, the air volume, the intake ratio of the inside and outside air, and the air volume ratio of the conditioned air sent from each outlet. Further, the control information is information that is obtained based on setting information such as the temperature of the air-conditioned air, the rotation speed of the blower fan, the blower voltage, and the opening degree of the air mix door, and controls the operation of each part of the air-conditioning unit. The construction of the probability model includes generating a new probability model and modifying and updating the already generated probability model.
In addition, the code | symbol in the parenthesis attached | subjected to each said means is an example which shows a corresponding relationship with the specific means as described in embodiment mentioned later.

Hereinafter, the vehicle air conditioner according to the first embodiment of the present invention will be described.
The vehicle air conditioner according to the first embodiment of the present invention is based on at least one probability model learned in accordance with the passenger's sense of warmth or specific situation, and the recommended probability of estimating the passenger's air conditioning setting operation. The air conditioning setting considered to be appropriate is automatically executed or recommended to the passenger according to the recommendation probability. In particular, the optimum air conditioning setting is appropriately executed or recommended by correcting the recommendation probability according to the parameters used for calculating the recommendation probability, the response at the time of the passenger's past setting operation, and the like.

  FIG. 1 is a configuration diagram showing an overall configuration of a vehicle air conditioner 1 according to a first embodiment of the present invention. As shown in FIG. 1, the vehicle air conditioner 1 includes an air conditioning unit 10 mainly composed of a mechanical configuration, and a control unit 60 that controls the air conditioning unit 10.

  First, the configuration of the refrigeration cycle R of the air conditioning unit 10 will be described. The refrigeration cycle R of the vehicle air conditioner 1 is configured as a closed circuit, and the closed circuit includes a condenser 15, a receiver 16, an expansion valve 17, and an evaporator 18 in a clockwise direction from the compressor 11. Then, the compressor 11 compresses the refrigerant into high pressure gas. Further, the compressor 11 includes an electromagnetic clutch 14 for power interruption that is transmitted from the vehicle-mounted engine 13 via the belt 12. The condenser 15 cools and liquefies the high-temperature and high-pressure refrigerant gas sent from the compressor 11. The receiver 16 stores the liquefied refrigerant gas. Further, in order to prevent the cooling performance from being deteriorated, gaseous bubbles contained in the liquefied refrigerant are removed, and only the completely liquefied refrigerant is sent to the expansion valve 17. The expansion valve 17 adiabatically expands the liquefied refrigerant to lower the temperature and pressure, and sends the refrigerant to the evaporator 18. The evaporator 18 performs heat exchange between the low-temperature and low-pressure refrigerant and the air sent to the evaporator 18 to cool the air.

  Next, the configuration in the air conditioning case 20 of the air conditioning unit 10 will be described. A blower fan 21 is disposed on the upstream side of the evaporator 18. The blower fan 21 is a centrifugal blower fan, and is driven to rotate by a drive motor 22. An inside / outside air switching box 23 is arranged on the suction side of the blower fan 21. Inside the inside / outside air switching box 23, an inside / outside air switching door 25 driven by an inside / outside air servomotor 24 is arranged. The inside / outside air switching door 25 opens and closes by switching between the inside air inlet 26 and the outside air inlet 27. Then, the air taken in from the inside air suction port 26 or the outside air suction port 27 is sent to the evaporator 18 by the blower fan 21 via the inside / outside air switching box 23. In addition, the air volume sent from the vehicle air conditioner 1 can be adjusted by adjusting the rotational speed of the blower fan 21.

  On the downstream side of the evaporator 18, an air mix door 28 and a heater core 29 are arranged in this order from the evaporator 18 side. The heater core 29 is circulated and supplied with cooling water used for cooling the in-vehicle engine 13 in order to warm the air passing through the heater core 29. The air conditioning case 20 has a bypass passage 30 that bypasses the heater core 29. The air mix door 28 is rotated by the temperature control servo motor 31 and passes through the bypass passage 30 and the warm air from the passage 32 passing through the heater core 29 in order to bring the air sent from each outlet to a predetermined temperature. Adjust the air volume ratio with the cool air.

  Further, on the downstream side of the air mixing section 33 where the cold air passing through the bypass passage 30 and the warm air from the passage 32 passing through the heater core 29 are mixed, a foot outlet 34 for sending conditioned air into the vehicle interior, A face outlet 35 and a defroster outlet 36 are provided. Each outlet is provided with a foot door 37, a face door 38, and a defroster door 39 for opening and closing each outlet. The foot outlet 34 sends conditioned air to the feet of the driver seat or passenger seat, and the face outlet 35 sends conditioned air from the front panel toward the driver seat or passenger seat. Further, the defroster outlet 36 sends conditioned air toward the windshield. Each door 37, 38 and 39 is driven by a mode servo motor 40.

Next, various sensors that function as an information acquisition unit included in the vehicle air conditioner 1 will be described. The inside air temperature sensor 51 is installed together with an aspirator on an instrument panel or the like in the vicinity of the steering wheel in order to measure the temperature _{Tr in the} vehicle interior. The outside air temperature sensor 52 for measuring the temperature T _am of the vehicle exterior, is located outside the front of the vehicle front radiator grille of the condenser 15. Further, in order to measure the intensity (intensity of solar radiation) S of the sunlight shining into the vehicle interior, a solar radiation sensor 53 is attached in the vicinity of the windshield in the vehicle interior. The solar radiation sensor 53 is composed of a photodiode or the like.

  Furthermore, an evaporator outlet temperature sensor for measuring the temperature of the air blown out from the evaporator 18 (evaporator outlet temperature), a heater inlet water temperature sensor for measuring the coolant temperature of the engine coolant to the heater core 29, and refrigeration A pressure sensor for measuring the pressure of the refrigerant circulating in the cycle R is provided. In addition, in the passenger compartment, one or more in-vehicle cameras 54 that function as a passenger information acquisition unit and photograph the faces of passengers on the driver's seat and other seats are installed. In addition, an out-of-vehicle camera 55 that captures the appearance outside the vehicle is also installed.

The vehicle air conditioner 1 acquires position information such as the current position of the vehicle, the traveling direction, the surrounding area information, and Gbook information from the navigation system 56 in addition to the sensing information from each sensor described above. Also, various operation information such as accelerator opening, steering wheel, brake, power window opening, wiper, turn lever or car audio ON / OFF, vehicle speed, vehicle behavior information, and the like are acquired from the vehicle operating device 57. Further, time information such as the day of the week and the current time is acquired from the in-vehicle clock 58. In addition, the vehicle air conditioner 1 may obtain a passenger's biological information by installing an electrocardiogram detection sensor, a heartbeat / respiration sensor, a body temperature sensor, a skin temperature sensor, or the like in a driver's seat or the like.
Thus, the navigation system 56, the vehicle operating device 57, and the in-vehicle clock 58 also function as an information acquisition unit.

FIG. 2 is a functional block diagram of the control unit 60 of the vehicle air conditioner 1.
The control unit 60 includes one or a plurality of microcomputers (not shown) including a CPU, ROM, RAM, etc. (not shown), peripheral circuits thereof, a storage unit 61 consisting of an electrically rewritable nonvolatile memory, The communication unit 62 communicates with various sensors, the navigation system 56, the vehicle operation device 57, and the like according to an in-vehicle communication standard such as a control area network (CAN).

  Furthermore, the control unit 60 includes a verification unit 63, a recommendation probability calculation unit 64, a recommendation probability correction unit 65, a control information correction unit 66, as functional modules realized by the microcomputer and a computer program executed on the microcomputer. An air conditioning control unit 67 and a learning unit 68 are included.

  When the control unit 60 acquires state information such as the sensing information, position information, and vehicle behavior information from various sensors, navigator systems, vehicle operating devices, and the like, the control unit 60 temporarily stores them in the RAM. Similarly, the operation signal acquired from the A / C operation panel 59 as the operation unit is also temporarily stored in the RAM. Then, the control unit 60 controls the air conditioning unit 10 based on the state information and the operation signal. For example, the control unit 60 controls the electromagnetic clutch 14 to switch the compressor 11 on and off, and controls the drive motor 22 for adjusting the rotational speed of the blower fan 21. The controller 60 controls the inside / outside air servo motor 24, the temperature control servo motor 31, and the mode servo motor 40 to adjust the opening of each door. By performing these controls, the air volume ratio of the conditioned air sent from each outlet, the overall air volume, and the temperature are adjusted so that the temperature in the passenger compartment approaches the temperature set by the passenger. Here, the control unit 60 inputs predetermined state information into an available probability model in order to determine the temperature of the conditioned air, the air volume, etc., and the passenger performs a predetermined operation (for example, lowers the set temperature, air volume, , Etc., and the probability of performing the setting in the inside air circulation mode, etc. If the probability is equal to or higher than a predetermined threshold, the predetermined operation is automatically performed.

  Furthermore, when the passenger operates the vehicle air conditioner 1, the control unit 60 accumulates the operation content and various information at the time of the operation. When a predetermined number of such information is accumulated, a statistical learning process is performed to generate a probability model. Hereinafter, each functional module that performs these operations will be described.

  When the engine switch is turned on, the verification unit 63 performs verification and authentication of the passenger based on the image captured by the in-vehicle camera 54 and the verification information regarding the registered user registered in advance in the vehicle air conditioner 1. , It is determined which registered user the passenger is. Then, the identification information (ID) of the registered user determined to be the passenger and the personal information related to the registered user are read from the storage unit 61.

  Here, the collation part 63 performs a collation and authentication of a passenger, for example with the following method. The collating unit 63 binarizes an image photographed by the in-vehicle camera 54 or performs edge detection to identify an area corresponding to the passenger's face. Then, characteristic parts such as eyes, nose and lips are detected from the identified face area by means such as edge detection, and the size and relative positional relationship of the characteristic parts are used as a set of feature values. Extract. Next, the collation unit 63 compares the extracted feature quantity set with the feature quantity set obtained for each registered user stored in the storage unit 61 in advance, and uses a correlation calculation or the like. The degree of coincidence is calculated. And when the highest matching degree becomes more than a predetermined threshold value, the collation part 63 authenticates a passenger as the registered user who became the highest matching degree. In addition, said collation method is only an example and the collation part 63 can perform a collation and authentication of a passenger using another known collation method. For example, the collation unit 63 can use a face authentication system for a vehicle described in JP-A-2005-202786. It is also possible to use a method other than image authentication. For example, a passenger may be verified and authenticated using a smart key system. Further, as in the vehicle antitheft device described in Japanese Patent Application Laid-Open No. 2005-67353, the smart key system and image authentication may be combined for verification and authentication.

The recommendation probability calculation unit 64 has at least one probability model associated with a predetermined setting operation, and calculates a recommended probability of performing the predetermined setting operation by inputting state information into the probability model.
In this embodiment, a Bayesian network is used as the probability model. A Bayesian network models a probabilistic causal relationship between a plurality of events, and is a network represented by an acyclic directed graph in which propagation between nodes is obtained with a conditional probability. For details on the Bayesian network, see Yoichi Motomura, Hirotoshi Iwasaki, “Bayesian Network Technology”, first edition, Denki University Press, July 2006, Kazuo Shigeru et al. July 2006, or supervised by Morio Onoe, “Pattern Identification”, first edition, New Technology Communications, July 2001, etc.

In the present embodiment, the probability model is generated for each user registered in the vehicle air conditioner 1. Further, the probability model is generated for each setting operation (for example, lowering or raising the _set temperature Tset, adjusting the air volume W, or setting the inside air circulation mode). The storage unit 61 stores probability model structure information in association with each user information and setting operation. Specifically, the user structure is identified along with a graph structure representing the connection relationship between each node constituting the probability model, the type of input information given to the input node, and a conditional probability table (hereinafter referred to as CPT) of each node. Number (ID), setting operation number k uniquely corresponding to the content of the setting operation, setting information or control information corrected by the setting operation and its correction value (for example, when the set temperature T _set is lowered by 3 ° C. , (T _set , −3), and (W, W _max ) when the air volume W is _set to the maximum value W _max ) is defined for each probability model and stored in the storage unit 61.

  The recommendation probability calculation unit 64 reads out from the storage unit 61 a probability model associated with a registered user identified as a passenger by the verification unit 63. The recommendation probability calculation unit 64 inputs predetermined state information to each of the read one or more probability models, and the probability that the occupant performs the setting operation associated with each probability model (that is, the recommendation probability). Ask for. That is, the probability of performing the setting operation that is uniquely defined for each probability model and is represented by the setting operation number k stored in the storage unit 61 together with each probability model is obtained. The probability can be calculated using, for example, a belief propagation method.

  The recommendation probability correction unit 65 corrects the recommendation probability obtained by the recommendation probability calculation unit 64 based on the reliability of parameters input to the probability model. The recommendation probability correcting unit 65 corrects the recommendation probability according to rules set from various viewpoints. Hereinafter, the correction of the recommendation probability will be described using some examples.

  The first rule relating to the correction of the recommendation probability is based on the reliability of the input parameter input to the probability model in order to obtain the recommendation probability. For example, when the position information acquired from the navigation system 56 is used as an input parameter in order to obtain the recommendation probability, the recommendation probability correction unit 65 increases its position as the communication state between the navigation system 56 and the GPS satellite becomes better. It is determined that the reliability of information is high. Then, the recommendation probability correcting unit 65 increases the recommendation probability as the reliability of the position information is higher. For example, it is assumed that the communication state between the navigation system 56 and the GPS satellite is expressed in four stages of 0 to 3 (however, the larger the numerical value, the better the communication state). At this time, the recommendation probability correcting unit 65 sets the recommendation probability to 0 when the communication state is 0. When the communication state is 1, the recommendation probability correction unit 65 multiplies the recommendation probability calculated by the recommendation probability calculation unit 64 by 1/3. Similarly, when the communication state is 2, the recommendation probability correction unit 65 multiplies the recommendation probability calculated by the recommendation probability calculation unit 64 by 2/3. Furthermore, when the communication state is 3, the recommendation probability correction unit 65 does not correct the recommendation probability calculated by the recommendation probability calculation unit 64.

The second rule regarding the correction of the recommendation probability is that when the recommended setting operation is presented to the occupant, the average value of the reaction time required from the time of the presentation until the occupant performs some setting operation It is based on. When the second rule is applied, as will be described later, when the recommended probability of performing a predetermined setting operation is within a predetermined range, the control information correcting unit 66 indicates the content of the predetermined setting operation to the passenger. Present. When the passenger performs an operation for approving the setting operation, the control information correcting unit 66 corrects the setting information or the control information so that the setting operation is performed. Here, whenever the recommended setting operation is presented, the control unit 60 measures the reaction time using a built-in timer. Then, the control information correction unit 66 stores the reaction time in the storage unit 61 in association with the probability model used for calculating the recommendation probability related to the recommended setting operation.
The recommendation probability correcting unit 65 obtains an average value of reaction times stored in association with the probability model used for calculating the recommendation probability. And the recommendation probability correction part 65 makes recommendation probability high, so that the average value of reaction time is short. For example, the recommendation probability correcting unit 65 multiplies the recommendation probability calculated by the recommendation probability calculating unit 64 by 1.1 if the average value of the reaction time is less than 5 seconds, and if the average value of the reaction time is 5 seconds or more. The recommendation probability calculated by the recommendation probability calculation unit 64 is not corrected. Note that the recommendation probability correcting unit 65 may classify the average value of the reaction time into three or more stages, and increase the coefficient by which the recommendation probability is multiplied as the average value is shorter.

The third rule relating to the correction of the recommendation probability is based on the ratio of performing the approval operation for the recommended setting operation when the recommended setting operation is presented to the passenger. Since it is considered that the higher the ratio of approving the setting operation presented by the vehicle air conditioner 1, the more recommending the setting operation according to the needs of the passenger, the recommendation probability correcting unit 65 has an approval ratio of The higher the recommendation probability, the higher the recommendation probability.
Even when the third rule is applied, since it is necessary to record whether or not the passenger has performed an approval operation for the recommended setting operation, the control information is similar to the second rule. The correction unit 66 presents the contents of the predetermined setting operation to the passenger when the recommended probability of performing the predetermined setting operation is within a predetermined range. Then, the control information correction unit 66 obtains the cumulative number of times that the predetermined setting operation has been presented and the cumulative number of times that the passenger has performed an approval operation for the presentation, and is used to calculate the recommendation probability for the predetermined setting operation. The data is stored in the storage unit 61 in association with the stored probability model.

  The recommendation probability correcting unit 65 obtains a ratio of the cumulative number of times that the approval operation is performed to the cumulative number of times that the predetermined setting operation is stored, which is stored in association with the probability model used for calculating the recommendation probability. And the recommendation probability correction part 65 makes recommendation probability high, so that the ratio is high. For example, the recommendation probability correction unit 65 multiplies the recommendation probability calculated by the recommendation probability calculation unit 64 by 0.9 if the obtained ratio is less than 50%, and calculates the recommendation probability if the obtained ratio is 50% or more. The recommendation probability calculated by the unit 64 is not corrected. Note that the recommendation probability correcting unit 65 may divide the above ratio into three or more stages, and the coefficient with which the recommendation probability is multiplied becomes smaller as the ratio is lower.

  Further, instead of the cumulative number of approval operations, the cumulative number of operations that are the same as the manually set setting operations within a predetermined period (for example, 1 minute) after the presentation of the refusal operation or the recommended setting operation. The number of times may be used. In this case, the recommendation probability correcting unit 65 increases the recommendation probability as the ratio of the cumulative number of rejection operations and the like to the cumulative number of times that the setting operation is presented is small.

The fourth rule regarding the correction of the recommendation probability is based on the number of learning data used for the construction of the probability model. When the number of learning data is small, that is, when it is considered that the number of days has not passed since the passenger started using the vehicle automatic air conditioner 1 according to the present invention, the recommendation probability is set high. By correcting the recommendation probability in this way, it becomes easier for the passenger to experience that the vehicular automatic air conditioner 1 is learning. Details of the learning data used for constructing the probability model will be described later.
For example, the recommendation probability correcting unit 65 multiplies the recommendation probability calculated by the recommendation probability calculating unit 64 by 1.1 if the number of sets of state information included in the learning data used for learning the probability model is less than 30. If the number of sets of state information is 30 or more, the recommendation probability calculated by the recommendation probability calculation unit 64 is not corrected.
On the contrary, the recommendation probability correcting unit 65 may correct the recommendation probability so that the recommendation probability increases as the number of learning data used for constructing the probability model increases. This is because as the number of learning data increases, it is considered that the situation in which the passenger performs the setting operation can be accurately grasped.

The fifth rule relating to the correction of the recommendation probability is based on the difference between the setting information or control information corrected by the recommended setting operation and the setting information or control information before the setting operation is performed, that is, based on the correction amount. It is. In this case, the recommendation probability correction unit 65 increases the recommendation probability as the correction amount of the setting information or control information by the recommended setting operation increases. For example, when the set temperature T _set is changed by 3 ° C. or more by the recommended setting operation, the recommended probability correcting unit 65 multiplies the recommended probability calculated by the recommended probability calculating unit 64 by 1.1 and sets the set temperature T _set . When the change amount is less than 3 ° C., the recommendation probability calculated by the recommendation probability calculation unit 64 is not corrected. Similarly, the recommended probability correcting unit 65 is calculated by the recommended probability calculating unit 64 when the blower voltage is changed by 3 V or more by the recommended setting operation or when the direction of blowing the conditioned air is changed by 30 degrees or more. If the recommended probability is multiplied by 1.1, and the blower voltage and the conditioned air blowing direction are not changed so much, the recommended probability is not corrected. The recommendation probability correcting unit 65 divides the correction amount into two stages as described above, and divides the correction amount into three or more stages. As the correction amount increases, the coefficient multiplied by the recommendation probability increases. It may be.

  The sixth rule relating to the correction of the recommendation probability is based on the operation frequency at which the passenger performs the setting operation in a specific situation. As the operation frequency is higher, it is considered that the setting content of the vehicle air conditioner 1 for the specific situation does not match the passenger's feeling of warmth, so it is preferable that the setting operation is recommended more easily. Therefore, the recommendation probability correction unit 65 increases the recommendation probability as the operation frequency increases.

In this case, a specific situation for checking the operation frequency is set in advance. Then, the control unit 60 determines whether or not the state information obtained from each sensor has a value corresponding to the specific situation. The controller 60 checks whether or not the passenger has performed the setting operation of the vehicle air conditioner 1 during a predetermined period (for example, 1 minute) after determining that the specific situation has been reached. Then, the control unit 60 obtains the cumulative number of times that the specific situation has been reached and the cumulative number of times that the passenger has performed the setting operation in the specific situation, and associates it with data representing the specific situation in the storage unit 61. Remember. The data representing the specific situation is, for example, a combination of the state information type related to the specific situation and its value. Further, as examples of the specific situation, the inside temperature _Tr or the outside temperature _Tam is a predetermined temperature (for example, 30 ° C., 0 ° C., etc.), the vehicle is in a predetermined position (for example, on the national road, the place of work of the passenger, etc.) ) In the vicinity.
Further, the recommendation probability calculation unit 64 calculates a recommendation probability for performing a predetermined setting operation using a probability model corresponding to the specific situation.

  The recommendation probability correcting unit 65 multiplies the recommendation probability calculated by the recommendation probability calculating unit 64 by 1.1 when the ratio of the cumulative number of times that the setting operation has been performed to the specific number of times reaches 50% or more. If the ratio is less than 50%, the recommendation probability is not corrected. Note that the recommendation probability correcting unit 65 may divide the above ratio into two stages, and divide the ratio into three or more stages so that the coefficient with which the recommendation probability is multiplied increases as the ratio increases.

  The seventh rule regarding the correction of the recommendation probability is based on the operation frequency at which the passenger performs the setting operation within a predetermined period. As the operation frequency is higher, it is considered that the setting content of the vehicle air conditioner 1 does not match the sensation of the passenger, so it is preferable that the setting operation is recommended more easily. Therefore, the recommendation probability correction unit 65 increases the recommendation probability as the operation frequency increases.

In this case, the control unit 60 detects that the setting operation is performed through the A / C operation panel 59 or the like regardless of the content of the setting operation and the situation when the setting operation is performed, and within a predetermined period. The total number of times that the setting operation has been performed is obtained. The predetermined period can be, for example, one boarding (a period from when the engine is started until it stops), one week, one month, or the like.
For example, if the average value of the operation frequency per boarding is 5 or more, the recommendation probability correction unit 65 multiplies the recommendation probability obtained by the recommendation probability calculation unit 64 by 1.1, and the average value is 5 If it is less, the recommendation probability is not corrected.

  The recommendation probability correction unit 65 corrects the recommendation probability according to all of the various rules described above. Alternatively, the recommendation probability correction unit 65 may correct the recommendation probability based on some of the rules. Then, when the recommended recommendation probability exceeds the predetermined upper limit value, the recommendation probability correction unit 65 sets the recommendation probability to the predetermined upper limit value. Similarly, when the recommended recommendation probability is lower than the predetermined lower limit value, the recommendation probability correcting unit 65 sets the recommended probability to the predetermined lower limit value. Here, the predetermined upper limit value can be, for example, 1.0 or a value obtained by multiplying the recommendation probability obtained by the recommendation probability calculation unit 64 by a predetermined coefficient (for example, 1.3). Further, the predetermined lower limit value can be, for example, 0.0 or a value obtained by multiplying the recommendation probability obtained by the recommendation probability calculation unit 64 by a predetermined coefficient (for example, 0.7).

Based on the obtained recommendation probability, the control information correction unit 66 sets information that can be set by the occupant, such as the _set temperature T _set and the air volume W, or the temperature of the conditioned air, the rotation speed of the blower fan, the blower voltage, It is determined whether to automatically adjust control information such as the opening of the air mix door.
When the obtained recommendation probability is equal to or higher than a first threshold value Th1 (for example, Th1 = 0.9) considered to be almost certain that the passenger will perform the setting operation, the control information correction unit 66 Automatically execute the setting operation. Specifically, the value of the setting information or control information related to the setting operation is associated with the probability model, that is, uniquely defined for the probability model, and stored in the storage unit 61 together with each probability model. The setting information or the correction information of the control information is used for correction.

  In addition, when the recommended probability obtained is less than the first threshold Th1, but is greater than or equal to the second threshold Th2 (for example, Th2 = 0.6) that is considered to be highly likely that the passenger will perform the setting operation. The control information correction unit 66 displays the setting operation content through a display unit such as the A / C operation panel 59 or the navigation system 56 to notify the passenger. And it confirms whether a passenger performs the setting operation. When an operation for authorizing the passenger to perform the setting operation (for example, pressing a predetermined operation button) is performed through the A / C operation panel 59 or the like, the control information correction unit 66 performs the setting operation. . The passenger may be notified of the setting operation content by voice through the A / C operation panel 59 or the navigation system 56. Further, by connecting a microphone to the vehicle air conditioner 1 and installing a voice recognition program in the control unit 60, it may be confirmed whether or not the setting operation is performed in response to the voice of the passenger.

Hereinafter, the processing of the recommendation probability calculation unit 64 and the control information correction unit 66 will be described in detail by taking as an example a case where the set temperature T _set is lowered by 3 ° C. Here, the first threshold Th1 is set to 0.9, and the second threshold Th2 is set to 0.6. In the following description, it is assumed that the recommendation probability correction unit 65 has not corrected the value of the recommendation probability calculated by the recommendation probability calculation unit 64 in order to facilitate understanding of the contents.
FIG. 3 shows an example of such a specific situation. The situation shown here is that the passenger (Mr. A) always plays tennis in an athletic park on a Saturday afternoon, and then gets into a private car at around 4 o'clock to lower the set temperature of the vehicle air conditioner than usual. Like that. On the other hand, in other cases, for example, a case where such a setting operation is not performed when going home from work is considered.

FIG. 4 shows a graph structure of an example of a probability model used for automatically adjusting the setting information or control information of the vehicle air conditioner 1. In the probability model 101 shown in FIG. 4, three input nodes 102, 103, and 104 are connected to the output node 105, respectively. Further, the day of the week (x ₁ ), the time zone (x ₂ ), and the current position (x ₃ ) are given to the input nodes 102, 103, and 104 as state information that is input. The output node 105 outputs the probability of lowering the set temperature T _set by 3 ° C.

  5A to 5D show CPTs 106 to 109 for the nodes of the probability model 101 shown in FIG. The CPTs 106 to 108 correspond to the input nodes 102 to 104, respectively, and define prior probabilities for input state information. The CPT 109 corresponds to the output node 105 and defines a conditional probability distribution assigned to each input node information value.

Here, if the day of the week is Saturday (x ₁ = 1), the time zone is noon (x ₂ = 1), the current position is park (x ₃ = 1), and all the information given to each input node is known, the set temperature The probability P (x ₄ = 1 | x ₁ = 1, x ₂ = 1, x ₃ = 1) of lowering T _set by 3 ° C. is 0.95 from FIG. Therefore, since the obtained recommendation probability is equal to or higher than the first threshold Th1, the control information correcting unit 66 lowers the set temperature _Tset by 3 ° C.

If the day of the week is Saturday (x ₁ = 1) and the time zone is noon (x ₂ = 1), for example, when the navigation system 56 is not turned on and the current position cannot be known, FIG. P (x ₄ = 1 | x ₁ = 1, x ₂ = 1, x ₃ ) is calculated using the prior probability P (x ₃ ) when the current position shown in (c) is a park. in this case,
P (x ₄ = 1 | x ₁ = 1, x ₂ = 1, x ₃ )
= P (x ₄ = 1 | x ₁ = 1, x ₂ = 1, x ₃ = 1) ・ P (x ₃ = 1)
+ P (x ₄ = 1 | x ₁ = 1, x ₂ = 1, x ₃ = 0) ・ P (x ₃ = 0)
= 0.95 ・ 0.15 + 0.55 ・ 0.85 = 0.61
It becomes. Therefore, since the obtained probability is smaller than the first threshold value Th1 but is equal to or greater than the second threshold value Th2, the control information correction unit 66 determines whether or not to lower the set temperature _Tset by 3 ° C. Confirm with the passenger through the operation panel 59 or the like.

Furthermore, if the day of the week is Monday (x ₁ = 0), the time zone is night (x ₂ = 0), and the current position is the workplace (x ₃ = 0), the probability P (x ₄ = 1 | x ₁ = 0, x ₂ = 0, x ₃ = 0) is 0.1 from FIG. Therefore, the probability obtained because less than the first threshold value Th1 and the second threshold value Th2, the control information correcting unit 66 does not change the set temperature T _{The set,} for changing the set temperature T _{The set,} We do not check with the passenger.

  In the above example, a two-layer network configuration is used for simplification, but a three-layer or more network configuration including an intermediate layer may be used. Moreover, although the day of the week as input information is divided into Saturday and other than that, it may be divided into other divisions, for example, every day of the week. Similarly, the current position may not be classified into a park and others, but may be classified for each place where a passenger frequently visits. Further, the time zone may be further subdivided or divided into morning, afternoon and the like.

In addition, when there are multiple probability models related to the same operation group (such as correction of set temperature, change of air volume, switching of inside / outside air or setting of air volume ratio), that is, correction of specific setting information or control information When there are a plurality of probability models whose outputs are the probabilities to be performed, the recommendation probability calculation unit 64 calculates the probability for each of the plurality of probability models. Then, among the obtained probabilities, the highest probability is selected as the recommended probability P. For example, consider a case where there are a probability model M1 (maximizing the air volume W) and M2 (making the air volume W medium) regarding the air volume setting. In this case, the recommendation probability calculation unit 64 obtains a probability P _M1 that maximizes the air volume W based on the probability model M1, and similarly calculates a probability P _M2 that makes the air volume W moderate based on the probability model M2. . Then, if P _M1 > P _M2 , the control information correction unit 66 compares P _M1 with the threshold values Th1 and Th2, and determines whether or not the air volume W is maximized. On the other hand, if P _M2 > P _M1 , P _M2 is compared with the above-mentioned threshold values Th1 and Th2, and it is determined whether or not the air volume W is moderate.

In the above, in order to facilitate understanding, it is defined that the probability models M1 and M2 are associated with different setting operations. However, the probability models M1 and M2 may be associated with the same setting operation (for example, both maximize the air volume W). This corresponds to, for example, that the same operation may be performed in two or more situations where one passenger is different (one is sunny in the day and the other is on the way back to the gym). . If probability models corresponding to the respective situations are generated, these probability models are associated with setting operations belonging to the same operation group.
When the setting information or control information is corrected as necessary by the above-described processing, the control information correction unit 66 makes the setting information or control information available to each unit of the control unit 60 so that the RAM of the control unit 60 can be used. Temporarily store.

  The air conditioning control unit 67 reads the value of each setting information or control information and the sensing information acquired from each sensor from the RAM, and controls the air conditioning unit 10 based on those values. For this purpose, the air conditioning control unit 67 includes a temperature adjustment unit 671, a compressor control unit 672, an outlet control unit 673, an inlet control unit 674, and an air flow rate setting unit 675. Further, when the setting information or control information corrected by the control information correction unit 66 is stored in the RAM, the air conditioning control unit 67 reads and uses the corrected information.

上式において、Doは、エアミックスドア２８の開度を表す。また、係数k_set、k_r、k_am、k_s、C、a、bは定数であり、T_set、T_r、T_am、Sは、それぞれ、設定温度、内気温、外気温及び日射量を表す。ここで、制御情報修正部６６が設定温度T_setを修正している場合、その修正された設定温度T_setを使用する。また、エアミックスドア２８の開度Doは、ヒータコア２９を経由する通路３２を閉じた状態（すなわち、冷房のみが動作する状態）を０％、バイパス通路３０を閉じた状態（すなわち、暖房のみが動作する状態）を１００％として設定される。温調制御式の各係数k_set、k_r、k_am、k_s、C及びエアミックスドアの開度を求める関係式の係数a、bは温調制御パラメータとして、登録済利用者ごとに設定され、登録済利用者の個人設定情報に含まれる。
なお、温度調節部６７１は、空調温度T_ao及びエアミックスドア２８の開度を、ニューラルネットワークを用いた制御やファジイ制御など、他の周知の制御方法を用いて決定してもよい。算出された空調温度T_aoは、制御部６０の他の部で参照できるように、記憶部６１に記憶される。 Based on the set temperature T _set and the measurement signals of the temperature sensors and the solar radiation sensor 53, the temperature adjustment unit 671 determines the required air outlet temperature (air conditioning temperature T _ao ) of the conditioned air sent from each air outlet. And the opening degree of the air mix door 28 is determined so that the temperature of the conditioned air becomes the air conditioning temperature _Tao, and the opening degree of the air mix door 28 is set to the temperature control servo motor 31. A control signal is transmitted to. For example, the opening degree of the air mix door 28 is obtained by inputting a value obtained by correcting the difference between the internal temperature _Tr and the set temperature T _set by the outside air temperature T _am , the solar radiation amount S, etc. It is determined based on the relational expression Here, the opening degree of the air mix door 28 is determined at regular time intervals (for example, every 5 seconds). A relational expression between each measured value for performing such control and the opening of the air mix door 28 is shown below.

In the above formula, Do represents the opening degree of the air mix door 28. The coefficients k _set , k _r , k _am , k _s , C, a, and b are constants, and T _set , T _r , T _am , and S are the set temperature, internal temperature, external temperature, and solar radiation, respectively. Represents. Here, when the control information correction unit 66 corrects the set temperature T _set , the corrected set temperature T _set is used. The opening degree Do of the air mix door 28 is 0% when the passage 32 passing through the heater core 29 is closed (that is, only the cooling operation is performed), and when the bypass passage 30 is closed (that is, only heating is performed). The operating state) is set as 100%. Each coefficient k _set , k _r , k _am , k _s , C of the temperature control expression and the coefficients a and b of the relational expression for determining the opening of the air mix door are set for each registered user as temperature control parameters And is included in the personal setting information of registered users.
Note that the temperature adjustment unit 671 may determine the air conditioning temperature T _ao and the opening degree of the air mix door 28 using another known control method such as control using a neural network or fuzzy control. The calculated air conditioning temperature _Tao is stored in the storage unit 61 so that it can be referred to by other units of the control unit 60.

The compressor control unit 672 controls ON / OFF of the compressor 11 based on the air conditioning temperature (necessary outlet temperature) T _ao , the set temperature T _{set, the} evaporator outlet temperature, and the like obtained by the temperature adjustment unit 671. The compressor control unit 672 operates the compressor 11 and the refrigeration cycle R in principle when cooling the passenger compartment or operating the defroster, for example. However, in order to avoid the evaporator 18 from being frosted, the compressor 11 is stopped when the evaporator outlet temperature falls close to the temperature at which the evaporator 18 is frosted. Then, when the evaporator outlet temperature rises to some extent, the compressor 11 is operated again. Since the compressor 11 can be controlled using a known method such as variable displacement control, detailed description thereof is omitted here.

The air outlet control unit 673 is configured to output each air outlet based on the set value of the air flow ratio set by the passenger through the A / C operation panel 59, the air conditioning temperature T _ao obtained by the temperature adjusting unit 671, the set temperature T _{set, and the} like. The air volume ratio of the conditioned air sent from the air is determined, and the opening degree of the foot door 37, the face door 38, and the defroster door 39 is determined so as to correspond to the air volume ratio. The outlet control unit 673 sets the opening of each door 37 to 39 in accordance with a relational expression representing the relationship between the set value of the air flow ratio, the air conditioning temperature T _ao , the set temperature T _set and the opening of each door 37 to 39. decide. Such a relational expression is defined in advance and is incorporated in a computer program executed in the control unit 60. In addition, the blower outlet control part 673 can also determine the opening degree of each door 37-39 using another known method. And the mode servomotor 40 is controlled so that each door 37-39 becomes the determined opening degree.
In addition, when the control information correction unit 66 corrects the set value or the set temperature T _set of the air flow ratio, each of the outlet control units 673 uses the corrected set value or the set temperature T _set. The opening degree of the doors 37 to 39 is determined.

The inlet control unit 674 causes the vehicle air conditioner 1 to move from the inside air inlet 26 based on the inlet setting, the set temperature T _set , the air conditioning temperature T _ao , the inside air temperature _{Tr, and the} like acquired from the A / C operation panel 59. The ratio of the air to be sucked and the air to be sucked from the outside air inlet 27 is set. Inlet control unit 674 determines the opening degree of outside air switching door 25 in accordance with the relational expression representing the relationship between the outside temperature T _am, like the difference between the inner temperature T _r and the set temperature T _set and the intake ratio. Such a relational expression is set in advance and is incorporated in a computer program executed in the control unit 60. In addition, the suction inlet control part 674 can also determine the opening degree of the inside / outside air switching door 25 using another known method. The inlet control unit 674 controls the inside / outside air servomotor 24 to rotate the inside / outside air switching door 25 so as to obtain the obtained intake ratio. In addition, when the control information correction unit 66 corrects the intake set value or the set temperature T _set , the intake port control unit 674 uses the corrected intake set value or the set temperature T _set to change the inside and outside air. The opening degree of the switching door 25 is determined.

Air volume setting unit 675, based on air volume W acquired from A / C control panel 59, the set temperature T _{The set,} air-conditioning temperature T _ao, inside temperature T _r, and the like outside temperature T _am and the amount of solar radiation S, the blower fan 21 And the blower voltage to be applied to the drive motor 22 is determined. Then, the blower amount setting unit 675 applies the calculated blower voltage to the drive motor 22 so that the rotation speed of the blower fan 21 becomes a set value. For example, when the air volume setting is a manual setting, the air volume setting unit 675 determines the rotation speed or the blower voltage of the blower fan 21 so that the air volume W acquired from the A / C operation panel 59 is obtained. In addition, when the air volume setting is automatically set, the air volume setting unit 675 rotates the blower fan 21 according to the air volume control expression that represents the relationship between the internal air temperature T _r , the air conditioning temperature T _ao , and the air volume W. Determine speed or blower voltage. Alternatively, the air volume control expression may directly represent the relationship between the _set air temperature T _set, air conditioning information (inside air temperature T _r , outside air temperature _Tam, and solar radiation amount S) and the air volume W. As such an airflow control formula, various well-known ones can be used. Note that such an air flow control expression is set in advance and incorporated in a computer program executed in the control unit 60. Alternatively, the air flow rate setting unit 675 prepares a map that defines the relationship between the air conditioning information and the air flow W in advance, and performs map control that determines the air flow W corresponding to the air conditioning information measured with reference to the map. Other known methods can be used to determine the rotational speed or blower voltage of the blower fan 21. In addition, when the control information correcting unit 66 corrects the air volume W or the set temperature T _set , the air volume setting unit 675 uses the corrected air volume W or the set temperature T _set of the blower fan 21. Determine the rotation speed.

  The learning unit 68 determines whether or not to generate a new probability model or to update an existing probability model when the passenger operates the vehicle air conditioner 1, and is necessary. In this case, a probability model is generated or updated.

ここで、d_ijkは、各状態情報の値である。iは、上記の操作回数i_Akを示す。また、jは、状態情報の各値に対して便宜的に指定される状態項目番号であり、本実施形態では、j=1に対して内気温T_r、j=2に対して外気温T_am、j=3に対して日射量Sが割り当てられる。そして、j=4以降に、位置情報、車両挙動情報、生体情報などが割り当てられる。また、kは設定操作番号である。
これら学習データD_Ak及び操作回数i_Akは、登録済み利用者及び設定操作ごとに別個に記憶される。 Generally, when the passenger compartment is not in an air conditioning state appropriate for the passenger, the passenger performs a setting operation of the vehicle air conditioner 1. Therefore, when the passenger frequently performs the setting operation of the vehicular device 1, it is considered necessary to construct a probability model for estimating the passenger's setting operation. However, in order to construct an appropriate probabilistic model, enough data is needed to make a statistically correct estimate. Therefore, each time the setting operation of the vehicle air conditioner 1 is performed, the learning unit 68 acquires each state information (air conditioning information such as the outside temperature Tam, position information such as the current position of the vehicle, vehicle speed, etc.) acquired at the time of the operation. Vehicle behavior information, biological information such as heart rate) is stored as learning data in the storage unit 61 in association with the setting operation number k and the passenger ID described above. Further, the number of operations i _Ak that the passenger A has performed the setting operation α corresponding to the setting operation number k (for example, lowering the set temperature by 3 ° C. or maximizing the air volume W) is also stored in the storage unit 61. The learning data D _Ak is expressed by the following equation, for example.

Here, _dijk is a value of each state information. i indicates the number of operations i _Ak described above. Further, j is a state item number designated for convenience with respect to each value of the state information. In this embodiment, the internal temperature T _r for j = 1 and the external temperature T for j = 2. _The solar radiation amount S is assigned to _am and j = 3. Then, after j = 4, position information, vehicle behavior information, biological information, and the like are assigned. K is a setting operation number.
The learning data D _Ak and the operation count i _Ak are stored separately for each registered user and setting operation.

When the number of operations i _Ak becomes equal to a predetermined number n1 (for example, 20 times), the learning unit 68 uses the learning data D _Ak stored in the storage unit 61 to construct a probability model M _Aqk related to the setting operation. To do. Note that q (= 1, 2,...) Represents the number of probability models constructed for the setting operation of the setting operation number k of the passenger A. Thereafter, when the passenger A further repeats the setting operation α, the learning unit 68 _{causes the} number of operations i _Ak after the construction of the previous probability model M _Aqk to reach n1 times (that is, the number of operations i _Ak = n1 · j (where j = 1, 2,...), the learning model D _Ak stored in the storage unit 61 is used to update the probability model M _Aqk .

When the operation number i _Ak becomes equal to a predetermined number n2 (for example, 60 times), the learning unit 68 establishes the probability model M _Aqk stored in the storage unit 61 at that time, and thereafter The probability model M _Aqk is not updated. The learning unit 68 _attaches flag information indicating that the established probability model M _Aqk is not updated. For example, the update flag f is associated with the probability model and stored in the storage unit 61. When the update flag f is “1”, updating (that is, rewriting) is prohibited, and when the update flag f is “0”, updating is possible. As shown in FIG. Then, the learning unit 68 erases the learning data D _Ak stored in the storage unit 61, initializes the number of operations i _Ak , and resets the value to 0. Note that the predetermined number of times n2 is larger than n1 and corresponds to the number of data considered that a statistically sufficiently accurate probability model can be constructed. The predetermined times n1 and n2 can be optimized empirically and experimentally.

When the passenger A repeats the same setting operation α after the probability model M _Aqk is established, a new probability model M _{Aq + 1k} is constructed according to the same procedure as described above. In this way, by constructing a plurality of probability models as necessary, when there are a plurality of specific situations in which the same type of setting operation is performed (for example, as a situation in which an operation for setting the inside-air circulation mode is performed, In the case of being inside and in the case of being behind a large truck). In addition, for a specific situation with a high occurrence frequency, a lot of information corresponding to the situation is included in the learning data, so that a probability model corresponding to an early stage is constructed. For the specific situation where the corresponding probability model is constructed, the control information correcting unit 66 automatically performs the setting operation by the probability inference based on the probability model. The setting operation of the device 1 is not performed. Therefore, the learning unit 68 constructs a probability model corresponding to a specific situation with a low occurrence frequency because the passenger performs a setting operation only when a specific situation with a low occurrence frequency occurs as learning progresses. You can also.

Next, the procedure for constructing the probability model will be described.
In order to construct a general-purpose probability model that can cope with various situations, it is necessary to construct a very large probability model including a large number of nodes. However, learning of such a probabilistic model requires a very long calculation time, and the hardware resources necessary for learning are enormous. Therefore, in this embodiment, two layers are selected as input parameters that are likely to be particularly relevant to the setting operation from the state information, and the probability of performing the setting operation based on a conditional probability for the combination of the input parameters is obtained. Fifteen types of configuration graph structures were prepared as standard models. However, the number of standard models is not limited to 15 types. The number of standard models can be optimized as appropriate depending on the number of state information obtained and the type of setting operation to be learned. Further, the standard model may have only one input parameter, or may have all the state information that can be acquired as input parameters. Further, the standard model is not limited to the graph structure having a two-layer structure, and a graph structure having three or more layers may be used as the standard model according to the ability of the CPU constituting the control unit 60.
Those standard models are stored in the storage unit 61. At the time of learning, for each standard model, a conditional probability between each node included in the standard model is determined to construct a temporary probability model. Thereafter, a temporary probability model having the most appropriate graph structure is selected using the information criterion. The selected model becomes the constructed probability model.

Hereinafter, it demonstrates in detail using figures.
FIGS. 6A to 6D show four of the 15 standard models as an example. Each of the standard models 501 to 504 shown in FIGS. 6A to 6D is a two-layer Bayesian network composed of an input node and an output node. Each standard model 501 to 504 is different in the parameters given to the input node.

In addition, for the input nodes of the standard models 501 to 504, a CPT that defines the prior probabilities for the input parameters assigned to the input nodes is set. The input information is classified using a technique such as clustering. For example, in the standard model 502 shown in FIG. 6B, for the input node having the current position as the input parameter (parameter y ₁₁ ), the learning unit 68 uses the hierarchical data such as the shortest distance method or k− Clustering is performed using a division optimization method such as an average method. Then, the learning unit 68 sets, for each cluster, a circle whose center is the centroid of the data included in the cluster and whose radius is the farthest position from the centroid, as a parameter value classification corresponding to the cluster. Alternatively, the division of parameter values, home when _{y 11 = 0, y 11 =} 1 when the workplace, may be determined in advance classification as y ₁₁ = 2 when the neighborhood park. Similarly, a CPT indicating a conditional probability distribution based on information given to the input node is set for the output node. In the initial state, the CPT is set to be the same value for all states. Alternatively, home when _{y 11 = 0, y 11 =} 1 when the workplace, may be determined in advance classification as y ₁₁ = 2 when the neighborhood park. Similarly, a CPT indicating a conditional probability distribution based on information given to the input node is set for the output node. In the initial state, the CPT is set to be the same value for all states.

The flowchart shown in FIG. 7 is a procedure for constructing a probability model.
When learning is started, the learning unit 68 first extracts a target input parameter from the learning data D _Ak for each standard model, _obtains a conditional probability of each node, creates a CPT, and creates a probability. A model is constructed (step S201).
Therefore, the learning unit 68 counts the number n corresponding to each parameter state for each node from the learning data D _Ak read from the storage unit 61. Then, a value obtained by dividing the number n by the total number of events N is set as the value of the prior probability and the conditional probability. For example, the standard model 502 in FIG. 6B will be described as an example. Here, there is learning data D _Ak including a set of 30 data, and when checking the current position assigned to one of the input nodes, the number of times of home (y ₁₁ = 0) is 15 times , If the number of times at work (y ₁₁ = 1) is 12 times and the number of times in the neighborhood park (y ₁₁ = 2) is 3, the prior probability P (y ₁₁ ) for the current position is P (y ₁₁ = 0) = 0.5, P (y ₁₁ = 1) = 0.4, and P (y ₁₁ = 2) = 0.1. Similarly, for the output node, for each combination of possible values of the current position (y ₁₁ ), day of the week (y ₁₂ ), and time zone (y ₁₃ ) of the input information given to each input node that is the parent node, The conditional probability can be obtained by calculating the number of occurrences in the learning data D _Ak and dividing it by 30 which is the total number of data. In this way, the CPT corresponding to each node is determined by obtaining the prior probability and the conditional probability.

Note that the learning unit 68 may estimate the probability distribution using the beta distribution when it is considered that the number of data used for learning is not sufficient. In addition, if there is no combination of values of some input information in the learning data D _Ak , that is, there is unobserved data, the probability distribution for the unobserved data is estimated, and the expected value is calculated based on the distribution. By calculating, the corresponding conditional probability is calculated. As for such conditional probability learning, for example, the method described in Kazuo Shigeru et al., “Outline of Bayesian Network”, First Edition, Baifukan, July 2006, p.35-38, p.85-87. Can be used.

ここで、AIC_mは、確率モデルＭに対するＡＩＣを表す。また、θ_mは、確率モデルＭのパラメータ集合を、l_m(θ_m|X)は、データXを所与としたときの確率モデルＭにおけるそのデータの最大対数尤度の値を、k_mは確率モデルＭのパラメータ数をそれぞれ表す。ここでl_m(θ_m|X)は、以下の手順で計算できる。まず、各ノードにおいて、親ノードの変数の各組み合わせについて、学習データD_Akから出現頻度を求める。その出現頻度に条件付き確率の対数値を乗じた値を求める。最後にそれらの値を足し合わせることでl_m(θ_m|X)が算出される。また、k_mは、各ノードにおける、親ノード変数の組み合わせの数を足し合わせることで求められる。 When the CPT for each standard model is obtained, the learning unit 68 calculates an information criterion for each probability model in order to evaluate the constructed probability model (step S202).
In this embodiment, AIC (Akaike information criterion) is used as the information criterion. The AIC can be obtained based on the following equation based on the maximum log likelihood of the probability model and the number of parameters.

Here, AIC _m represents the AIC for the probability model M. Further, theta _m is the parameter set of probabilistic model _{M, l m (θ m |} X) is the value of the maximum log-likelihood of the data in the probability model M when the data X and a given, k _m Represents the number of parameters of the probability model M, respectively. Here, l _m (θ _m | X) can be calculated by the following procedure. First, in each node, the appearance frequency is obtained from the learning data D _Ak for each combination of the variables of the parent node. A value obtained by multiplying the appearance frequency by the logarithm of the conditional probability is obtained. Finally, l _m (θ _m | X) is calculated by adding these values. Also, k _m is at each node is calculated by adding the number of combinations of parent node variables.

When the learning unit 68 obtains the AIC for all the probability models, the learning unit 68 selects the model having the smallest AIC value as the probability model to be used, and stores it in the storage unit 61 (step S203). Then, other probability models are deleted (step S204).
Regarding the selection of the probability model using the information criterion (in other words, learning of the graph structure), other information such as Bayesian information criterion (BIC), Takeuchi information criterion (TIC), minimum description length (MDL) criterion, etc. An information criterion may be used. Furthermore, the information amount reference obtained by reversing the sign of the information amount reference calculation formula may be used. In this case, the probability model that maximizes the information criterion value is selected as the probability model to be used.

The learning unit 68 stores the constructed probability model in the storage unit 61. Further, the passenger ID and the setting operation number k associated with the learning data D _Ak are acquired and stored in the storage unit 61 in association with the constructed probability model. Further, the setting information or control information to be corrected based on the probability model and the correction value are specified based on the setting operation number k, and stored in the storage unit 61 in association with the probability model. The relationship between the setting operation number k, the setting information or control information to be corrected, and the correction value is defined in advance as a lookup table, for example, and held in the storage unit 61.

  Hereinafter, the air conditioning control operation of the vehicle air conditioner 1 according to the first embodiment of the present invention will be described with reference to the flowcharts shown in FIGS. 8 and 9. The air conditioning control operation is performed by the control unit 60 in accordance with a computer program incorporated in the control unit 60.

  As shown in FIG. 8, first, when the engine switch is turned on, the control unit 60 operates the vehicle air conditioner 1. And the collation part 63 of the control part 60 performs a passenger's collation and authentication (step S101). Further, the personal setting information of the registered user determined as the passenger is read from the storage unit 61 (step S102). Next, each state information is acquired from each sensor, the navigation system 56, the vehicle operating device 57, etc. through the communication part 62 (step S103). Similarly, each setting information is acquired from the storage unit 61.

Next, the control unit 60 determines whether or not the passenger has performed a setting operation of the vehicle air conditioner 1 (step S104). When an operation signal is received from the A / C operation panel 59, it is determined that a setting operation has been performed. When the passenger has not performed the setting operation, the recommendation probability calculation unit 64 of the control unit 60 sets the setting information or control information related to any operation group in the probability model M _Aqk associated with the passenger. The observed state information is input to the probability model related to the correction of (for example, the set temperature T _set ). Then, the recommendation probability calculation unit 64 calculates the probability of performing the setting operation associated with the probability model (step S105). The recommendation probability calculation unit 64 obtains the highest probability as the recommendation probability P among the probabilities calculated for the setting operations in the same operation group related to the setting information or control information.
Thereafter, the recommended probability correcting unit 65 of the control unit 60 corrects the determined recommended probability P according to the predetermined rule described above (step S106).

  Next, the control information correction unit 66 of the control unit 60 compares the corrected recommendation probability P with the first predetermined value Th1 (step S107). When the recommendation probability P is greater than or equal to a first predetermined value Th1 (for example, 0.9), the control information correction unit 66 is based on correction information associated with a probability model (hereinafter referred to as a selection probability model) that outputs the recommendation probability P. Then, the setting information or control information of the corresponding vehicle air conditioner 1 is corrected (step S108). On the other hand, when the recommendation probability P is less than the first predetermined value Th1, the control information correction unit 66 compares the recommendation probability P with a second predetermined value Th2 (for example, 0.6) (step S109). If the recommendation probability P is equal to or greater than the second predetermined value Th2, the control information correction unit 66 corresponds to the setting operation number k associated with the selection probability model through the display unit of the A / C operation panel 59 or the like. Whether or not to perform the setting operation is displayed and confirmed (step S110). When the passenger approves the setting operation, the control information correction unit 66 corrects the setting information or the control information based on the correction information associated with the selection probability model (step S108). On the other hand, if the passenger does not approve, the control information correction unit 66 does not correct the setting information or the control information. That is, the setting operation related to the setting information or control information associated with the selection probability model is not performed. In step S109, also when the recommendation probability P is less than the second predetermined value Th2, the control information correcting unit 66 does not correct the setting information or the control information.

Thereafter, the control information correction unit 66 determines whether or not adjustment of all setting information and control information has been completed by checking whether or not the probabilities have been calculated for all probability models (step S111). If there is a probability model for which the probability has not yet been calculated, that is, if there is an operation group for which the setting information has not been corrected, the control unit 60 returns control to step S105. On the other hand, when the probability calculation has been completed for all probability models, the air conditioning control unit 67 of the control unit 60 determines the desired air conditioning temperature, based on the setting information and control information modified as necessary. Air conditioning control is performed so that the air volume and the like can be obtained (step S112). Specifically, the air-conditioning control unit 67 adjusts the air mix door, the rotation speed of the blower fan, the opening degree of each outlet, and the like.
Thereafter, the control unit 60 determines whether or not the vehicle air conditioner 1 is turned off (step S120). When the vehicle air conditioner 1 is turned off, the operation of the vehicle air conditioner 1 ends. On the other hand, when the vehicle air conditioner 1 continues to operate, the control in steps S104 to S120 is repeated at regular intervals (for example, 5 seconds).

As shown in FIG. 9, when the passenger performs a setting operation of the vehicle air conditioner 1 in step S104, the setting signal is identified with reference to the setting signal (step S113). Then, the ID of the passenger, and the setting operation number k corresponding to the performed setting operation, the setting operation in association with the operation executed number i _Ak, elements of the training data D _Ak each status information obtained Is stored in the storage unit 61 (step S114).

Thereafter, the learning unit 68 of the control unit 60 determines whether or not the number of operations i _Ak is equal to the predetermined number n1 * j (j = 1, 2, 3) (step S115). The predetermined number n1 is, for example, 20 times. If the learning unit 68 determines that i _Ak = n1 * j, it uses the learning data D _Ak associated with the passenger and the setting operation number k and stored in the storage unit 61 to use the probability model M _Aqk. Is constructed (step S116). The probability model M _Aqk is constructed according to the procedure shown in the flowchart of FIG. Then, the learning unit 68 stores the probability model M _Aqk in the storage unit 61 in association with the passenger ID and the like. On the other hand, when i _Ak is not equal to n1 * j in step S115, the control unit 60 shifts the control to before step S117.

Next, the learning unit 68 determines whether or not the operation number i _Ak is equal to a predetermined number n2 (for example, n2 = 60) (step S117). If i _Ak is not equal to n2, i _Ak is incremented by 1 (step S118), and control proceeds to step S112 in FIG. On the other hand, if i _Ak = n2 in step S117, the learning unit 68 erases the learning data D _Ak stored in the storage unit 61 in association with the passenger and the setting operation number k (step S119). . Also, i _Ak is initialized and i _Ak = 0. Thereafter, the control shifts before step S112. Then, air conditioning control is performed (step S112), it is determined whether or not the vehicle air conditioner 1 is stopped (step S120). If the vehicle air conditioner 1 is not stopped, the above processing is repeated.

  Note that in step S104 of the flowchart described above, it may be determined whether to accumulate learning data or calculate a recommendation probability based on whether the state information has reached a predetermined value.

In step S115 of the above flowchart, the learning unit 68 determines the operation number i _Ak and the predetermined number n1 * j (j = 1, 2, 3) in order to determine whether or not to construct a probability model. Instead of comparing, it may be determined whether or not a first predetermined time (for example, one week, one month) has elapsed since the previous construction of the probability model related to the same setting operation. Good. In this case, the learning unit 68 constructs a probability model when the elapsed time is equal to or longer than the first predetermined time. That is, the learning unit 68 executes the processes of steps S116 to S119 described above. Thus, in order to determine whether or not to construct a probability model based on the elapsed time, the control unit 60 associates the creation date and time when the probability model is constructed with the probability model in the storage unit 61. Remember. Then, when calculating the elapsed time, the learning unit 68 acquires, from the storage unit 61, the creation date and time associated with the latest probability model among the probability models related to the setting operation α, and the difference from the current time To calculate the elapsed time.
Furthermore, when the learning unit 68 determines whether or not to construct a probability model based on the elapsed time, in step S117, the learning unit 68 sets the second time longer than the first predetermined time. You may make it compare with predetermined time (for example, 4 weeks, 6 months). When the elapsed time is longer than the second predetermined time, the learning unit 68 erases the learning data D _Ak and rewrites the update flag f.

  As described above, the vehicle air conditioner according to the first embodiment of the present invention is based on at least one probability model learned in accordance with the passenger's sense of warmth or specific situation. Since the setting operation is estimated, the optimum air conditioning setting can be automatically performed according to the passenger's sense of warmth or situation. In particular, since the recommendation probability is corrected according to the reliability of the parameters used for calculating the recommendation probability, the behavior that the passenger has recommended in the past, etc., the setting operation corresponding to the specific situation is more Can be recommended appropriately.

Next, a vehicle air conditioner according to a second embodiment of the present invention will be described. The vehicle air conditioner according to the second embodiment of the present invention weights the data used for learning based on the reliability or the response at the time of the past setting operation of the passenger, and the weighting is performed. The probability model is learned using the data.
In FIG. 10, the functional block diagram of the control part of the vehicle air conditioner which concerns on the 2nd Embodiment of this invention is shown. The control unit 60 of the vehicle air conditioner according to the second embodiment of the present invention replaces the recommendation probability correction unit 65 as compared with the control unit 60 of the vehicle air conditioner according to the first embodiment of the present invention. The only difference is that the data weighting unit 69 is provided. Moreover, the vehicle air conditioner which concerns on 1st and 2nd embodiment has the same structure regarding the other component of the vehicle air conditioner. Therefore, in the following, with respect to the control unit 60, differences from the first embodiment, particularly processing by the data weighting unit 69 will be described.

The data weighting unit 69 weights the state information stored as the learning data D _Ak in accordance with the reliability of the acquired state information, the action performed in the past with respect to the setting operation recommended by the passenger, and the like. . The weight attached to each state information is associated with the learning data D _Ak as a weight matrix W _AK and stored in the storage unit 61. In the weight matrix W _AK , A represents the passenger identification number, and k represents the set operation number. That is, the weight matrix _{WAK is} also created for each passenger and for each type of setting operation. The weight matrix W _AK has the same size as the learning data D _Ak, and the element w _ijk of the weight matrix W _AK represents the weight for the element d _ijk of the learning data D _Ak .
When the data weighting unit 69 determines the weight for the element d _ijk of the learning data D _Ak , the data weighting unit 69 writes the weight to the element w _ijk of the weight matrix W _AK .

When the learning unit 68 creates a CPT corresponding to each node of the probability model, regarding the state information used as an input parameter of each node, the learning unit 68 converts the learning data _DAk into the division for each division of the value of the state information. Instead of counting state information having an included value, the weight of the state information having a value included in the section is obtained from the weight matrix _WAK . And the learning part 68 adds the acquired weight for every division, and makes it the appearance frequency with respect to the division. Further, the learning unit 68 sets the total number of events as the sum of the appearance frequencies of the respective sections. As in the first embodiment, the learning unit 68 divides the obtained appearance frequency by the total number of events, and determines values of prior probabilities and conditional probabilities that are output from each node.
The data weighting unit 69 weights the state information in accordance with rules set from various viewpoints as in the recommendation probability correction unit 65 described above. Hereinafter, the weighting of the state information will be described using some examples.

  The first rule relating to the weighting of the state information is based on the reliability of the acquired state information. For example, when the position information acquired from the navigation system 56 is stored as learning data, the data weighting unit 69 determines that the better the communication state between the navigation system 56 and the GPS satellite, the higher the reliability of the position information. To do. The data weighting unit 69 increases the weight as the reliability of the position information is higher. For example, it is assumed that the communication state between the navigation system 56 and the GPS satellite is expressed in four stages of 0 to 3 (however, the larger the numerical value, the better the communication state). At this time, the data weighting unit 69 sets the weight to 0 when the communication state is 0. The data weighting unit 69 sets the weight to 0.3 when the communication state is 1. Similarly, the data weighting unit 69 sets the weight to 0.7 when the communication state is 2, and sets the weight to 1 when the communication state is 3.

  The second rule regarding weighting of state information is based on the reaction time required from when the setting operation was presented to the passenger in the past until the passenger performed some setting operation. is there. As described above, when the recommended probability of performing the predetermined setting operation is within a predetermined range, that is, when the recommended probability of performing the predetermined setting operation is less than the threshold value Th1 and greater than or equal to the threshold value Th2, the control information correction unit 66 displays the content of the predetermined setting operation to the passenger. Present. When the passenger performs an operation for approving the setting operation, the control information correcting unit 66 corrects the setting information or the control information so that the setting operation is performed. Here, every time the recommended setting operation is presented, the control unit 60 measures the reaction time using a built-in timer. Then, the control information correction unit 66 stores the reaction time in the storage unit 61 in association with the probability model used for calculating the recommendation probability related to the predetermined setting operation. In addition, when applying this rule, the data weighting unit 69 must associate the predetermined setting operation with state information used for obtaining the recommended probability of the predetermined setting operation. Therefore, the data weighting unit 69 applies the probability propagation method by setting the recommended probability to a value within the predetermined range for the probability model used for calculating the recommended probability for the predetermined setting operation, For a set of state information used as an input parameter, a set of values having the highest probability is obtained. The data weighting unit 69 performs weighting when the value of the state information acquired from each sensor corresponds to the set of values having the highest probability.

  The data weighting unit 69 obtains an average value of reaction times stored in association with the probability model used for calculating the recommendation probability. The data weighting unit 69 increases the weight as the average reaction time is shorter. For example, if the average value of the reaction time is less than 5 seconds, the data weighting unit 69 sets the weight for the related state information to 1.1, and if the average value of the reaction time is 5 seconds or more, the weight for the related state information Is 1. Note that the data weighting unit 69 may classify the average value of the reaction time into three or more levels, and increase the weight as the average value is shorter.

The third rule relating to the weighting of the state information is based on the ratio of performing the approval operation on the presented setting content when the setting operation has been presented to the passenger in the past. The higher the ratio of approving the setting operation presented by the vehicle air conditioner 1, the more recommended the setting operation according to the passenger's needs. Therefore, the data weighting unit 69 has a higher approval ratio. The higher the weight attached to the corresponding state information.
Also in this case, since it is necessary to record whether or not the passenger has performed an approval operation for the recommended setting operation, the control information correction unit 66 is not limited to the predetermined rule, as in the second rule. When the recommended probability of performing the setting operation is within a predetermined range, the contents of the predetermined setting operation are presented to the passenger. Then, the control information correction unit 66 obtains the cumulative number of times that the predetermined setting operation has been presented and the cumulative number of times that the passenger has performed an approval operation for the presentation, and is used to calculate the recommendation probability for the predetermined setting operation. The data is stored in the storage unit 61 in association with the stored probability model. Further, the data weighting unit 69 performs weighting by associating the predetermined setting operation with the state information used for obtaining the recommended probability of the predetermined setting operation in the same manner as the second rule. Is identified.

  The data weighting unit 69 obtains a ratio of the cumulative number of times that the approval operation is performed to the cumulative number of times that the predetermined setting operation is stored, which is stored in association with the probability model used for calculating the recommendation probability. The data weighting unit 69 increases the weight as the ratio increases. For example, if the obtained ratio is less than 50%, the data weighting unit 69 sets the weight for the related state information to 0.9, and corrects the weight for the state information already accumulated as learning data to 0.9. . Further, if the obtained ratio is 50% or more, the data weighting unit 69 sets the weight for the related state information to 1, and corrects the weight for the state information already accumulated as learning data to 1. . Note that the data weighting unit 69 may divide the above ratio into three or more stages so that the weight becomes smaller as the ratio is lower.

  Further, instead of the cumulative number of approval operations, the cumulative number of operations that are the same as the manually set setting operations within a predetermined period (for example, 1 minute) after the presentation of the refusal operation or the recommended setting operation. The number of times may be used. In this case, the data weighting unit 69 increases the weight as the ratio of the cumulative number of rejection operations and the like to the cumulative number of times the setting operation is presented is small.

The fourth rule regarding the weighting of the state information is based on the number of learning data used for constructing the probability model. When the number of learning data is small, that is, when it is considered that the number of days has not passed since the passenger started using the vehicle automatic air conditioner 1 according to the present invention, the weight is increased. When applying this rule, the learning unit 68 uses the number of state information accumulated in the learning data as a criterion for determining whether or not to construct the probability model, instead of using the number of state information accumulated in the learning data. The sum of the weights attached to the information is used. In this case, since learning is performed even if the state information accumulated as learning data is small, it becomes easier to experience that the vehicle automatic air conditioner 1 is learning.
For example, the data weighting unit 69 sets the weight to 2 if the number of state information sets included in the learning data used for learning the probability model is 10 or less, and the number of state information sets is 10 or more. As the number increases, all the weights for the state information accumulated as learning data so far are corrected to 1, and the weight for the state information accumulated thereafter is also set to 1.

  The fifth rule regarding the weighting of the state information is based on the difference between the setting information or control information corrected by the recommended setting operation and the setting information or control information before the setting operation is performed, that is, based on the correction amount. It is. In this case, the data weighting unit 69 increases the weight as the correction amount of the setting information or the control information by the recommended setting operation increases. Also in this case, the data weighting unit 69 associates the recommended setting operation with the state information related to the setting operation by the method described in the second rule.

For example, when the set temperature T _set is changed by 3 ° C. or more by the recommended setting operation, the data weighting unit 69 sets the weight of the related state information to 2 and the change amount of the set temperature T _set is less than 3 ° C. In this case, the weight is 1. Further, when the set temperature T _set is changed by 3 ° C. or more after the correction by correcting the probability model, the data weighting unit 69 stores the state information already accumulated as learning data. Among them, the weight of the related state information is also corrected to 2. On the other hand, when the set temperature T _set is changed by less than 3 ° C. after the correction of the probability model, the data weighting unit 69 uses the state information already accumulated as learning data. The weight of the related state information is also corrected to 1.
Similarly, when the blower voltage is changed by 3 V or more by the recommended setting operation, or when the direction of blowing the conditioned air is changed by 30 degrees or more, the data weighting unit 69 sets the weight for the related state information to 2. When the blower voltage and the blowing direction of the conditioned air are not changed so much, the weight for the related state information is set to 1. Note that the data weighting unit 69 may divide the correction amount into two stages as described above, and may divide the correction amount into three or more stages so that the weight increases as the correction amount increases.

  The sixth rule regarding the weighting of the state information is based on the operation frequency at which the passenger performs the setting operation in a specific situation. As the operation frequency is higher, it is considered that the setting content of the vehicle air conditioner 1 for the specific situation does not match the passenger's feeling of warmth, so it is preferable that the setting operation is recommended more easily. Therefore, the data weighting unit 69 increases the weight as the operation frequency increases.

In this case, a specific situation for checking the operation frequency is set in advance. Then, the control unit 60 determines whether or not the state information obtained from each sensor has a value corresponding to the specific situation. The controller 60 checks whether or not the passenger has performed the setting operation of the vehicle air conditioner 1 during a predetermined period (for example, 1 minute) after determining that the specific situation has been reached. Then, the control unit 60 obtains the cumulative number of times that the specific situation has been reached and the cumulative number of times that the passenger has performed the setting operation in the specific situation, and associates it with data representing the specific situation in the storage unit 61. Remember. The data representing the specific situation is, for example, a combination of the state information type related to the specific situation and its value. Further, as examples of the specific situation, the inside temperature _Tr or the outside temperature _Tam is a predetermined temperature (for example, 30 ° C., 0 ° C., etc.), the vehicle is in a predetermined position (for example, on the national road, the place of work of the passenger, etc.) ) In the vicinity.
Further, the recommendation probability calculation unit 64 calculates a recommendation probability for performing a predetermined setting operation using a probability model corresponding to the specific situation.

  The data weighting unit 69 sets the weight to 2 when the ratio of the cumulative number of times the setting operation is performed to the specific number of times reaches 50% or more, and sets the weight to 2 when the ratio is less than 50%. Set to 1. Note that the data weighting unit 69 may divide the above ratio into two stages, and divide the ratio into three or more stages so that the higher the ratio, the greater the weight.

  The seventh rule relating to the weighting of the state information is based on the operation frequency at which the passenger performs the setting operation within a predetermined period. As the operation frequency is higher, it is considered that the setting content of the vehicle air conditioner 1 does not match the sensation of the passenger, so it is preferable that the setting operation is recommended more easily. Therefore, the data weighting unit 69 increases the weight as the operation frequency increases.

In this case, the control unit 60 detects that the setting operation is performed through the A / C operation panel 59 or the like regardless of the content of the setting operation and the situation when the setting operation is performed, and within a predetermined period. The total number of times that the setting operation has been performed is obtained. The predetermined period can be, for example, one boarding (a period from when the engine is started until it stops), one week, one month, or the like.
For example, the data weighting unit 69 sets the weight to 1.5 if the average value of the operation frequency per boarding is 5 or more, and sets the weight to 1 if the average value is less than 5.

  The eighth rule relating to the weighting of the state information is based on the acquisition timing of the state information. The data weighting unit 69 increases the weight as the acquisition timing of the state information is newer. For example, when storing the newly acquired state information as learning data, the data weighting unit 69 sets the weight for the state information to 1.5. At the same time, the data weighting unit 69 associates the acquired date and time with each status information, and stores it in the storage unit 61. The data weighting unit 69 acquires the current date and time from the navigation system 56 or the like when the vehicle air conditioner 1 is started up, and the date and time of each state information included in the learning data stored in the storage unit 61. Compare with Then, the data weighting unit 69 corrects the weight to 1 for each piece of state information included in the learning data whose elapsed date and time since the acquisition is over 10 days.

  The data weighting unit 69 weights the state information according to all of the various rules described above. Alternatively, the data weighting unit 69 may weight the state information based on some of the rules. Also, if the weights calculated based on some of the above rules contradict each other, for example, the weight is 0.3 according to the first rule, but the weight is 1.1 according to the second rule. There are cases. Therefore, the data weighting unit 69 sets the priority for each rule in advance, and adopts the weight obtained according to the rule with the highest priority when the weights obtained according to each rule contradict each other.

  In FIG. 11, the operation | movement flowchart of the vehicle air conditioner which concerns on the 2nd Embodiment of this invention is shown. In addition, FIG. 11 shows only the part which is different from the operation flowchart of the vehicle air conditioner according to the first embodiment of the present invention shown in FIGS. In the operation flowchart shown in FIG. 11, the same steps as those in the operation flowcharts shown in FIGS.

  First, when the vehicle air conditioner is activated and personal setting information is acquired (step S102), the data weighting unit 69 of the control unit 60 checks the acquisition date and time of each state information included in the learning data. And according to said 8th rule, the data weighting part 69 makes the weight with respect to what has passed the predetermined elapsed time after acquisition about each status information (step S121).

Thereafter, when the setting operation by the passenger is performed and the setting operation performed in step S113 is specified, the data weighting unit 69 specifies a probability model related to the specified setting operation. Then, as described in the second rule and the like, the data weighting unit 69 specifies state information to be weighted based on the probability model (step S122). Thereafter, data weighting unit 69, a weight for the identified status information determined according to the rules described above to update the weight matrix W _AK (step S123). Then, it progresses to step S114 and memorize | stores the acquired status information.
If the passenger does not perform the setting operation in step S104 and the recommendation probability calculation unit 64 of the control unit 60 calculates the recommendation probability for the predetermined setting operation in step S105, the control information correction unit 66 of the control unit 60 Using the recommendation probability without modification, the processing after step S107 is performed.

  As described above, the vehicle air conditioner according to the second embodiment of the present invention weights the state information included in the learning data used for constructing the probability model based on the reliability of each state information. The probability model is constructed using the weight. As a result, adverse effects due to data inappropriate for learning can be reduced, and the vehicle air conditioner can recommend an appropriate setting operation according to a specific situation to the passenger.

Next, a vehicle air conditioner according to a third embodiment of the present invention will be described. The vehicle air conditioner according to the third embodiment of the present invention determines whether the recommended setting operation is to be automatically performed or whether the recommended setting operation is presented to the passenger. The threshold value Th2 is corrected based on the reliability of the state information used for calculating the recommendation probability or the response of the passenger during past setting operations.
FIG. 12 shows a functional block diagram of the control unit of the vehicle air conditioner according to the third embodiment of the present invention. The control unit 60 of the vehicle air conditioner according to the third embodiment of the present invention replaces the recommended probability correction unit 65 as compared with the control unit 60 of the vehicle air conditioner according to the first embodiment of the present invention. The difference is only in that the threshold setting unit 70 is provided. In addition, the vehicle air conditioner which concerns on 1st and 3rd embodiment has the same structure regarding the other component of the vehicle air conditioner. Therefore, in the following, with respect to the control unit 60, differences from the first embodiment, in particular, processing by the threshold setting unit 70 will be described.

  The threshold setting unit 70 corrects the threshold Th1 or the threshold Th2 in accordance with rules set from various viewpoints. Hereinafter, this threshold value correction will be described using some examples.

  The first rule regarding the correction of the threshold value is based on the reliability of the input parameter input to the probability model in order to obtain the recommendation probability. For example, when the position information acquired from the navigation system 56 is used as an input parameter in order to obtain the recommendation probability, the threshold setting unit 70 indicates that the position information is improved as the communication state between the navigation system 56 and the GPS satellite is better. Is determined to have high reliability. And the threshold value setting part 70 makes a threshold value low, so that the reliability of the positional information is high. For example, it is assumed that the communication state between the navigation system 56 and the GPS satellite is expressed in four stages of 0 to 3 (however, the larger the numerical value, the better the communication state). At this time, when the communication state is 0, the threshold setting unit 70 sets the threshold Th1 and the threshold Th2 to values larger than 1. In other words, the recommended setting operation based on the probability model is not automatically performed or presented to the passenger. When the communication state is 1, the threshold setting unit 70 multiplies the initial setting values of the thresholds Th1 and Th2 by 1.2. Note that the initial setting value of the threshold value Th1 is 0.9, for example, and the initial setting value of the threshold value Th2 is 0.6, for example. Similarly, when the communication state is 2, the threshold setting unit 70 multiplies the initial setting values of the thresholds Th1 and Th2 by 1.1. Further, when the communication state is 3, the threshold setting unit 70 does not correct the initial setting values of the thresholds Th1 and Th2.

The second rule relating to the correction of the threshold is based on the reaction time required from when the setting operation was presented to the passenger in the past until the passenger performed some setting operation. . The measurement of the reaction time is performed in the same manner as described in the second rule for correcting the recommendation probability in the first embodiment.
The threshold setting unit 70 obtains an average value of reaction times stored in association with the probability model used for calculating the recommendation probability. And the threshold value setting part 70 makes a threshold value low, so that the average value of reaction time is short. For example, if the average value of the reaction time is 5 seconds or more, the threshold value setting unit 70 multiplies the initial values of the threshold values Th1 and Th2 by 1.1, and if the average value of the reaction time is less than 5 seconds, the threshold value Th1 and Do not modify the default value of Th2. The threshold setting unit 70 may divide the average value of the reaction time into three or more stages, and the lower the average value, the lower the coefficient multiplied by the thresholds Th1 and Th2.

The third rule relating to the correction of the threshold is based on the ratio of performing the approval operation on the presented setting content when the setting operation has been presented to the passenger in the past. The threshold setting unit 70 has a higher approval ratio because it is considered that the higher the ratio of approving the setting operation presented by the vehicle air conditioner 1, the more recommending the setting operation according to the passenger's needs. The lower the threshold is,
Also in this case, since it is necessary to record whether or not the passenger has performed an approval operation for the recommended setting operation, the control information correction unit 66 indicates the cumulative number of times that the predetermined setting operation has been presented, In addition, the cumulative number of times that the passenger performs an approval operation for the presentation is obtained, and stored in the storage unit 61 in association with the probability model used for calculating the recommended probability for the predetermined setting operation.

  The threshold setting unit 70 obtains a ratio of the cumulative number of times that the approval operation is performed to the cumulative number of times that the predetermined setting operation is stored, which is stored in association with the probability model used for calculating the recommendation probability. And the threshold value setting part 70 makes a threshold value low, so that the ratio is high. For example, if the obtained ratio is 50% or more, the threshold setting unit 70 multiplies 0.9 by the initial setting values of the thresholds Th1 and Th2, and if the obtained ratio is less than 50%, the initial setting of the thresholds Th1 and Th2. Do not modify the value. Note that the threshold setting unit 70 may classify the ratio into three or more stages, and increase the coefficient by which the thresholds Th1 and Th2 are multiplied as the ratio is lower.

  Further, instead of the cumulative number of approval operations, the cumulative number of operations that are the same as the manually set setting operations within a predetermined period (for example, 1 minute) after the presentation of the refusal operation or the recommended setting operation. The number of times may be used. In this case, the threshold value setting unit 70 lowers the threshold value as the ratio of the cumulative number of rejection operations and the like to the cumulative number of times that the setting operation is presented is small.

The fourth rule relating to the correction of the threshold is based on the number of learning data used for constructing the probability model. When the number of learning data is small, that is, when it is considered that the number of days has not passed since the passenger started using the vehicle automatic air conditioner 1 according to the present invention, the threshold value is set low. By correcting the threshold value in this way, it becomes easier for the passenger to experience that the vehicular automatic air conditioner 1 is learning.
For example, if the number of sets of state information included in the learning data used for learning of the probability model is less than 30, the threshold setting unit 70 multiplies the initial setting values of the thresholds Th1 and Th2 by 0.9 to obtain the state information If the number of sets is 30 or more, the initial setting values of the thresholds Th1 and Th2 are not corrected.
Contrary to the above, the threshold value setting unit 70 may correct the threshold values Th1 and Th2 to be lower as the number of learning data used for constructing the probability model is larger. This is because as the number of learning data increases, it is considered that the situation in which the passenger performs the setting operation can be accurately grasped.

The fifth rule regarding the correction of the threshold value is based on the difference between the setting information or control information corrected by the recommended setting operation and the setting information or control information before the setting operation is performed, that is, the correction amount. is there. In this case, the threshold value setting unit 70 decreases the threshold value as the correction amount of the setting information or control information by the recommended setting operation increases. For example, when the set temperature T _set is changed by 3 ° C. or more by the recommended setting operation, the threshold setting unit 70 multiplies the initial setting values of the thresholds Th1 and Th2 by 0.9, and the change amount of the set temperature T _set is 3 When the temperature is lower than ° C, the initial setting values of the threshold values Th1 and Th2 are not corrected. Similarly, when the blower voltage is changed by 3 V or more by the recommended setting operation, or when the direction of blowing the conditioned air is changed by 30 degrees or more, the threshold setting unit 70 sets the initial values of the thresholds Th1 and Th2. When 0.9 is multiplied and the blower voltage and the blowing direction of the conditioned air are not changed so much, the initial setting values of the threshold values Th1 and Th2 are not corrected. As described above, the threshold setting unit 70 divides the correction amount into two stages, and divides the correction amount into three or more stages. The larger the correction amount, the smaller the coefficient multiplied by the thresholds Th1 and Th2. You may do it.

  The sixth rule relating to the correction of the threshold is based on the operation frequency at which the passenger performs the setting operation in a specific situation. As the operation frequency is higher, it is considered that the setting content of the vehicle air conditioner 1 for the specific situation does not match the passenger's feeling of warmth, so it is preferable that the setting operation is recommended more easily. Therefore, the threshold setting unit 70 decreases the threshold as the operation frequency increases.

In this case, a specific situation for checking the operation frequency is set in advance. Then, the control unit 60 determines whether or not the state information obtained from each sensor has a value corresponding to the specific situation. The controller 60 checks whether or not the passenger has performed the setting operation of the vehicle air conditioner 1 during a predetermined period (for example, 1 minute) after determining that the specific situation has been reached. Then, the control unit 60 obtains the cumulative number of times that the specific situation has been reached and the cumulative number of times that the passenger has performed the setting operation in the specific situation, and associates it with data representing the specific situation in the storage unit 61. Remember. The data representing the specific situation is, for example, a combination of the state information type related to the specific situation and its value. Further, as examples of the specific situation, the inside temperature _Tr or the outside temperature _Tam is a predetermined temperature (for example, 30 ° C., 0 ° C., etc.), the vehicle is in a predetermined position (for example, on the national road, the place of work of the passenger, etc.) ) In the vicinity.
Further, the recommendation probability calculation unit 64 calculates a recommendation probability for performing a predetermined setting operation using a probability model corresponding to the specific situation.

  The threshold value setting unit 70 multiplies the initial setting values of the threshold values Th1 and Th2 by 0.9 when the ratio of the cumulative number of times that the setting operation has been performed to the specific number of times reaches 50% or more, and the ratio is If it is less than 50%, the initial setting values of the threshold values Th1 and Th2 are not corrected. Note that the threshold setting unit 70 may divide the above ratio into two stages, and divide the ratio into three or more stages so that the coefficient with which the thresholds Th1 and Th2 are multiplied decreases as the ratio increases. .

  The seventh rule regarding the correction of the threshold is based on the operation frequency at which the passenger performs the setting operation within a predetermined period. As the operation frequency is higher, it is considered that the setting content of the vehicle air conditioner 1 does not match the sensation of the passenger, so it is preferable that the setting operation is recommended more easily. Therefore, the threshold setting unit 70 decreases the threshold as the operation frequency increases.

In this case, the control unit 60 detects that the setting operation is performed through the A / C operation panel 59 or the like regardless of the content of the setting operation and the situation when the setting operation is performed, and within a predetermined period. The total number of times that the setting operation has been performed is obtained. The predetermined period can be, for example, one boarding (a period from when the engine is started until it stops), one week, one month, or the like.
For example, if the average value of the operation frequency per boarding is 5 or more, the threshold value setting unit 70 multiplies the initial values of the threshold values Th1 and Th2 by 0.9, and if the average value is less than 5, The initial setting values of the threshold values Th1 and Th2 are not corrected.

  The threshold setting unit 70 corrects the thresholds Th1 and Th2 according to all of the various rules described above. Alternatively, the threshold setting unit 70 may correct the thresholds Th1 and Th2 based on some of the rules. Then, when the modified threshold values Th1 and Th2 exceed a predetermined upper limit value, the threshold setting unit 70 sets the threshold values Th1 and Th2 to the predetermined upper limit value. Similarly, when the modified threshold values Th1 and Th2 are below a predetermined lower limit value, the threshold setting unit 70 sets the threshold values Th1 and Th2 to the predetermined lower limit value. Here, the predetermined upper limit value can be, for example, 1.1 or a value obtained by multiplying the initial setting values of the threshold values Th1 and Th2 by a predetermined coefficient (for example, 1.3). Further, the predetermined lower limit value may be, for example, 0.5 or a value obtained by multiplying the initial setting values of the threshold values Th1 and Th2 by a predetermined coefficient (for example, 0.7).

  In FIG. 13, the operation | movement flowchart of the vehicle air conditioner which concerns on the 3rd Embodiment of this invention is shown. FIG. 13 shows only the parts different from the operation flowchart of the vehicle air conditioner according to the first embodiment of the present invention shown in FIGS. In the operation flowchart shown in FIG. 13, the same steps as those in the operation flowcharts shown in FIGS. 8 and 9 are given the same numbers.

  In step S105, when the recommendation probability calculation unit 64 of the control unit 60 calculates a recommendation probability for a predetermined setting operation, the threshold setting unit 70 of the control unit 60 sets the thresholds Th1 and Th2 for the recommendation probability according to the above rules. Is corrected (step S131). Thereafter, the control information correction unit 66 of the control unit 60 performs the processes after step S107 using the corrected threshold values Th1 and Th2.

  As described above, the vehicle air conditioner according to the third embodiment of the present invention has performed in the past with respect to the reliability of parameters used for calculating the recommendation probability and the setting operation recommended by the passenger. Depending on the behavior, etc., the threshold for judging whether or not the recommended setting operation is automatically executed or the threshold for judging whether or not to present it to the passenger is corrected, so that the setting corresponding to the specific situation is made. The operation can be recommended more appropriately.

In addition, this invention is not limited to said embodiment. For example, regarding the operation of the vehicle air conditioner according to any one of the above-described embodiments, the processing of the above steps S109 to S110 is omitted, and only the determination of whether or not the recommended setting operation is automatically executed is performed. You may do it. Further, the process of step S108 may be omitted, and it may be determined only whether or not the recommended setting operation is presented to the passenger. In this case, the rules relating to the correction of the recommendation probability or the threshold value or the weighting of the learning data are also appropriately selected according to the embodiment.
Further, the control unit 60 presents the recommended setting operation to the passenger when automatically executing the recommended setting operation based on the ratio of rejecting the recommended setting operation or the operation interval at which the passenger performs the setting operation. You may change the content of the message used at the time. In this case, the control unit 60 can obtain the ratio for rejecting the recommended setting operation by the same method as described in the third rule regarding the correction of the recommendation probability. Further, the control unit 60 can obtain the operation interval as follows. The control unit 60 detects that a predetermined setting operation, for example, switching between inside air circulation and outside air introduction, has been performed through the A / C operation panel 59 and the like, and since the previous predetermined setting operation has been performed. Find the elapsed time. Then, every time the predetermined setting operation is performed, the control unit 60 obtains an average value of the elapsed time and sets it as an operation interval.

  FIG. 14 shows a flowchart of the operation of the vehicle air conditioner in the case where the recommended setting operation is automatically executed or the message when presenting to the passenger is changed. FIG. 14 shows only the parts different from the operation flowchart of the vehicle air conditioner according to the first embodiment of the present invention shown in FIGS. Furthermore, in FIG. 14, the same number was attached | subjected to the step same as the operation | movement step of the vehicle air conditioner which concerns on said embodiment.

In step S107, when the recommendation probability P for the predetermined setting operation is greater than or equal to the threshold Th1, that is, when the predetermined setting operation is recommended, the control information correction unit 66 of the control unit 60 performs the setting operation target. It is determined whether or not the set temperature T _set , the air volume W, or the wind direction is operated relatively frequently (step S141). When the target of the setting operation is not any of the above, the control information correction unit 66 determines whether or not the average operation interval related to the target of the setting operation is a predetermined value (for example, 5 minutes) or less (step S142). When the average operation interval is equal to or greater than a predetermined value, it is considered that the passenger performs the recommended setting operation only occasionally. Therefore, the control information correction unit 66 displays a message informing the details of the recommended setting operation on the A / C operation panel 59 or the like so that the passenger can grasp the content of the recommended setting operation (step S143). On the other hand, when the average operation interval is less than the predetermined threshold value in step S142, it is considered that the passenger frequently performs the recommended setting operation. Therefore, the control information correcting unit 66 displays a message on the A / C operation panel 59 or the like so that the passenger does not feel bothersome (step S144).
Here, examples of the detailed message and the simple message will be given. For example, if the recommended setting operation is to change to the inside air circulation mode due to approaching the tunnel, the detailed message informs the contents of the setting operation and the specific situation that caused the setting operation. Like, “I'm approaching the tunnel, so I ’m going to enter the inside air circulation mode.” On the other hand, a simple message is simply “set to inside air circulation mode”.

In step S141, if the recommended setting operation target is one of the set temperature T _set , the air volume W, or the wind direction that is operated relatively frequently, the control information correction unit 66 displays any message. No (step S145). Then, after steps S143 to S145, the control information correction unit 66 corrects the setting information or the control information so that the recommended setting operation is performed (step S108).

If the recommended probability P for the predetermined setting operation is less than the threshold value Th1, but it is determined in step S109 that the recommended probability P is equal to or greater than the threshold value Th2, the control information correcting unit 66 is recommended. Regarding the setting operation, it is determined whether or not the ratio of rejecting operation when proposed in the past is 0.5 or more (step S146). When the ratio is 0.5 or more, the passenger is highly likely not to perform the setting operation. Therefore, the control information correction unit 66 does not notify the passenger of the setting operation and sets the setting operation. The information and control information are not corrected.
On the other hand, when the ratio is less than 0.5 in step S146, the control information correction unit 66 determines whether the target of the setting operation is the set temperature T _set , the air volume W, or the wind direction that is operated relatively frequently. It is determined whether or not there is (step S147). If the recommended setting operation target is any of the above, the control information correction unit 66 does not display any message (step S145) and automatically corrects the setting information or control information (step S108). ).

On the other hand, if the recommended setting operation target does not correspond to any of the above in step S147, the control information correction unit 66 determines that the average operation interval related to the setting operation target is equal to or less than a predetermined value (for example, 5 minutes). And whether or not the number of state information included in the learning data used for constructing the probability model for which the recommendation probability P is calculated is equal to or less than a predetermined number (for example, 20) (step S148). When the average operation interval is equal to or greater than a predetermined value, it is considered that the passenger performs the recommended setting operation only occasionally. Therefore, the control information correcting unit 66 displays a confirmation message informing the details of the recommended setting operation on the A / C operation panel 59 so that the passenger can grasp the details of the recommended setting operation (step S149). Further, even when the number of state information used for constructing the probability model is small, it is highly likely that the passenger does not know the reason why the setting operation is recommended, so a detailed confirmation message is displayed. On the other hand, when the average operation interval is less than the predetermined threshold in step S148, it is considered that the passenger frequently performs the recommended setting operation. Therefore, the control information correcting unit 66 displays a confirmation message on the A / C operation panel 59 or the like so that the passenger does not feel bothersome (step S150).
Here, examples of the detailed confirmation message and the simple confirmation message will be given. For example, if the recommended setting operation is to change to the inside air circulation mode due to approaching the tunnel, the detailed message informs the contents of the setting operation and the specific situation that caused the setting operation. Like, “You are approaching the tunnel. Do you want to enter the inside air circulation mode?”. On the other hand, the simple message is simply “Do you want to enter the inside air circulation mode?”.

  Further, the learning unit and the storage unit may be provided in a server installed separately from the vehicle, and generation or update of the probability model may be performed by the server. In this case, when the vehicle air conditioner acquires the state information, the vehicle air conditioner adds the vehicle identification information and transmits it to the server. And a server distinguishes each information for every vehicle, and accumulate | stores it as learning data. When learning data for a specific vehicle is sufficiently accumulated, the server uses the learning data to generate or update a probability model for the vehicle. Thereafter, the server refers to the vehicle identification information and transmits the probability models to the corresponding vehicle. Note that it is preferable to store these probability models in the server as a backup. This is because the server can use the backup probability model without acquiring information about the probability model to be updated from the vehicle when updating the probability model.

In the above embodiment, the passenger is not limited to the driver. By determining who performed the setting operation of the vehicle air conditioner, it can be suitably used even when a passenger other than the driver operates. For example, when two A / C operation panels 59 for a vehicle air conditioner are prepared for a driver seat and a passenger seat, the control unit 60 determines which A / C operation panel 59 is operated, It may be determined whether the driver has operated or the passenger has operated. Further, as described in Japanese Patent Application Laid-Open No. 2002-29239, the control unit 60 is provided with an operation occupant detection sensor composed of an infrared temperature sensor or the like on the A / C operation panel 59, so It may be determined which of the persons has performed the operation.
When the passenger performs an operation, as in the case of the driver's verification and authentication, the passenger is also verified and authenticated based on the image data captured by the in-vehicle camera 54. Status information such as values is stored in association with the passenger, not the driver.

  Further, when the passenger is limited to a specific person, or when a probability model is constructed for a setting operation that is performed regardless of who is driving, the matching unit 63 may be omitted. In this case, the learning data used for learning the probability model and the probability model is used in common regardless of who the passenger is.

  Further, in the construction of the probability model, in the above-described embodiment, a standard model that defines a graph structure is prepared in advance. Instead of preparing such a standard model, a graph structure search is performed using a K2 algorithm or a genetic algorithm. May be performed. For example, in the case of using a genetic algorithm, a plurality of genes having each element as to whether or not each node is connected is prepared. Then, the fitness of each gene is calculated using the above information criterion. Select a gene with a fitness level greater than or equal to a predetermined level, and perform the operation such as crossover and mutation to create the next generation gene. Such an operation is repeated a plurality of times to select the gene having the highest fitness. The graph structure described by the selected gene is used to construct the probability model. Furthermore, these algorithms and construction of a probability model from a standard model may be used in combination.

  The air conditioner to which the present invention is applied may be any type of front single, left and right independent, rear independent, four seat independent, and vertical independent. When the present invention is applied to any independent type air conditioner, a plurality of inside air temperature sensors, solar radiation sensors, and the like may be mounted.

  As described above, various modifications can be made within the scope of the present invention.

1 is a configuration diagram showing an overall configuration of a vehicle air conditioner according to a first embodiment of the present invention. It is a functional block diagram of the control part of a vehicle air conditioner. It is a figure which shows an example of a specific situation. It is a figure which shows the graph structure of an example of the probability model used for the automatic adjustment of the setting value of a vehicle air conditioner. (A)-(d) is a figure which shows the conditional probability table | surface about each node of the probability model shown in FIG. 4, respectively. (A)-(d) is a figure which shows the standard model which has the graph structure used as the basis of a probability model, respectively. It is a flowchart which shows the stochastic model construction operation | movement of the vehicle air conditioner which concerns on the 1st Embodiment of this invention. It is a flowchart which shows the control action of the vehicle air conditioner which concerns on the 1st Embodiment of this invention. It is a flowchart which shows the control action of the vehicle air conditioner which concerns on the 1st Embodiment of this invention. It is a functional block diagram of the control part of the vehicle air conditioner which concerns on the 2nd Embodiment of this invention. It is a flowchart which shows operation | movement of the vehicle air conditioner which concerns on the 2nd Embodiment of this invention. It is a functional block diagram of the control part of the vehicle air conditioner which concerns on the 3rd Embodiment of this invention. It is a flowchart which shows operation | movement of the vehicle air conditioner which concerns on the 3rd Embodiment of this invention. It is a flowchart of operation | movement of the vehicle air conditioner in the case of changing the message at the time of automatic execution or showing a passenger the setting operation recommended.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Vehicle air conditioner 10 Air conditioning part 11 Compressor 21 Blower fan 22 Driving motor 24 Inside / outside air servo motor 25 Inside / outside air switching door 28 Air mix door 31 Temperature control servo motor 37 Foot door 38 Face door 39 Defroster door 40 Mode servo motor 51 Inside Air temperature sensor 52 Outside air temperature sensor 53 Solar radiation sensor 54 In-vehicle camera 55 In-vehicle camera 56 Navigation system 57 Vehicle operating device 58 Car-mounted clock 59 A / C operation panel 60 Control unit 61 Storage unit 62 Communication unit 63 Verification unit 64 Recommendation probability calculation unit 65 Recommendation Probability correction unit 66 Control information correction unit 67 Air conditioning control unit 671 Temperature adjustment unit 672 Compressor control unit 673 Air outlet control unit 674 Suction port control unit 675 Air flow rate setting unit 68 Learning unit 69 Data weighting unit 70 Threshold setting 101 probability model 102 to 105 node 106 to 109 conditional probability table (CPT)
501 to 504 Standard model

Claims (23)

An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
A recommendation probability calculation unit (64) for inputting the current state information representing the current state of the vehicle to the probability model constructed by the learning unit (68) and calculating a recommendation probability for performing the predetermined setting operation;
A recommendation probability correction unit (65) for correcting the recommendation probability according to a predetermined rule;
A control information correction unit (66) for correcting setting information or control information related to the setting operation of the occupant so as to be the predetermined setting operation according to the corrected recommendation probability;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The vehicle air conditioner characterized in that the recommendation probability correcting unit (65) increases the recommendation probability as the reliability of the current state information is higher . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
A recommendation probability calculation unit (64) for inputting the current state information representing the current state of the vehicle to the probability model constructed by the learning unit (68) and calculating a recommendation probability for performing the predetermined setting operation;
A recommendation probability correction unit (65) for correcting the recommendation probability according to a predetermined rule;
A control information correction unit (66) for correcting setting information or control information related to the setting operation of the occupant so as to be the predetermined setting operation according to the corrected recommendation probability;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The vehicle air conditioner characterized in that the recommendation probability correcting unit (65) increases the recommendation probability as the number of state information included in the learning data group is smaller . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
A recommendation probability calculation unit (64) for inputting the current state information representing the current state of the vehicle to the probability model constructed by the learning unit (68) and calculating a recommendation probability for performing the predetermined setting operation;
A recommendation probability correction unit (65) for correcting the recommendation probability according to a predetermined rule;
A control information correction unit (66) for correcting setting information or control information related to the setting operation of the occupant so as to be the predetermined setting operation according to the corrected recommendation probability;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The recommendation probability correcting unit (65) increases the recommendation probability as the difference between the setting information or control information corrected to be the predetermined setting operation and the setting information or control information before the correction is larger. An air conditioner for a vehicle. An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
A recommendation probability calculation unit (64) for inputting the current state information representing the current state of the vehicle to the probability model constructed by the learning unit (68) and calculating a recommendation probability for performing the predetermined setting operation;
A recommendation probability correction unit (65) for correcting the recommendation probability according to a predetermined rule;
A control information correction unit (66) for correcting setting information or control information related to the setting operation of the occupant so as to be the predetermined setting operation according to the corrected recommendation probability;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The vehicle air conditioner characterized in that the recommendation probability correcting unit (65) increases the recommendation probability as the frequency of setting operations performed on the vehicle air conditioner increases . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
A recommendation probability calculation unit (64) for inputting the current state information representing the current state of the vehicle to the probability model constructed by the learning unit (68) and calculating a recommendation probability for performing the predetermined setting operation;
A recommendation probability correction unit (65) for correcting the recommendation probability according to a predetermined rule;
A control information correction unit (66) for correcting setting information or control information related to the setting operation of the occupant so as to be the predetermined setting operation according to the corrected recommendation probability;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The recommendation probability correcting unit (65) increases the recommendation probability as the frequency of setting operations performed on the vehicle air conditioner increases when the current state information has a predetermined value. Air conditioner. An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
A recommendation probability calculation unit (64) for inputting the current state information representing the current state of the vehicle to the probability model constructed by the learning unit (68) and calculating a recommendation probability for performing the predetermined setting operation;
A recommendation probability correction unit (65) for correcting the recommendation probability according to a predetermined rule;
A confirmation operation unit (59) for presenting the content of the predetermined setting operation to the passenger and confirming with the passenger whether or not to perform the predetermined setting operation ;
When it is confirmed that the predetermined setting operation is to be performed through the confirmation operation unit (59), setting information or control information related to the occupant setting operation is stored in the predetermined operation according to the corrected recommendation probability. A control information correction section (66) for correcting the setting operation,
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The storage unit (61) stores a reaction time from the presentation by the confirmation operation unit (59) to an operation for determining whether or not the predetermined setting operation is performed by a passenger.
The vehicle air conditioner characterized in that the recommendation probability correction unit (65) increases the recommendation probability as the average value of the reaction time is shorter . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
A recommendation probability calculation unit (64) for inputting the current state information representing the current state of the vehicle to the probability model constructed by the learning unit (68) and calculating a recommendation probability for performing the predetermined setting operation;
A recommendation probability correction unit (65) for correcting the recommendation probability according to a predetermined rule;
A confirmation operation unit (59) for presenting the content of the predetermined setting operation to the passenger and confirming with the passenger whether or not to perform the predetermined setting operation ;
When it is confirmed that the predetermined setting operation is to be performed through the confirmation operation unit (59), setting information or control information related to the occupant setting operation is stored in the predetermined operation according to the corrected recommendation probability. A control information correction section (66) for correcting the setting operation,
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The storage unit (61) performs the predetermined setting operation by the passenger through the confirmation operation unit (59) and the number of times of presentation that the predetermined operation is performed by the confirmation operation unit (59). Storing the number of positive operations that have been performed to determine that in association with the probability model,
The vehicle air conditioner characterized in that the recommendation probability correcting unit (65) increases the recommendation probability as the ratio of the number of positive operations to the number of presentations is higher . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A data weighting unit (69) for weighting the state information included in the learning data group according to a predetermined rule;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
The current probability information constructed by the learning unit (68) is inputted with current state information representing the current state of the vehicle to calculate the recommended probability, and the setting related to the occupant setting operation according to the recommended probability A control information correction unit (66) for correcting information or control information so as to be the predetermined setting operation;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The vehicle air conditioner is characterized in that the data weighting unit (69) performs weighting so that the specific gravity of the state information is higher as the reliability of the state information included in the learning data group is higher . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A data weighting unit (69) for weighting the state information included in the learning data group according to a predetermined rule;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
The current probability information constructed by the learning unit (68) is inputted with current state information representing the current state of the vehicle to calculate the recommended probability, and the setting related to the occupant setting operation according to the recommended probability A control information correction unit (66) for correcting information or control information so as to be the predetermined setting operation;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The data weighting unit (69) is configured such that when the number of state information included in the learning data group is equal to or less than a predetermined number, the specific gravity is higher than when the number of state information is greater than the predetermined number. A vehicle air conditioner characterized by weighting . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A data weighting unit (69) for weighting the state information included in the learning data group according to a predetermined rule;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
The current probability information constructed by the learning unit (68) is inputted with current state information representing the current state of the vehicle to calculate the recommended probability, and the setting related to the occupant setting operation according to the recommended probability A control information correction unit (66) for correcting information or control information so as to be the predetermined setting operation;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The information acquisition unit (51-53, 55-58) acquires the state information when a passenger performs a setting operation of the vehicle air conditioner,
The data weighting unit (69) increases the specific gravity of the state information as the difference between the setting information or control information before performing the setting operation and the setting information or control information after performing the setting operation increases. The vehicle air conditioner is weighted so as to become . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A data weighting unit (69) for weighting the state information included in the learning data group according to a predetermined rule;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
The current probability information constructed by the learning unit (68) is inputted with current state information representing the current state of the vehicle to calculate the recommended probability, and the setting related to the occupant setting operation according to the recommended probability A control information correction unit (66) for correcting information or control information so as to be the predetermined setting operation;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The vehicle air conditioner is characterized in that the data weighting unit (69) performs weighting so that the specific gravity of the state information acquired when the frequency of setting operations performed on the vehicle air conditioner is high . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A data weighting unit (69) for weighting the state information included in the learning data group according to a predetermined rule;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
The current probability information constructed by the learning unit (68) is inputted with current state information representing the current state of the vehicle to calculate the recommended probability, and the setting related to the occupant setting operation according to the recommended probability A control information correction unit (66) for correcting information or control information so as to be the predetermined setting operation;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The data weighting unit (69) has the predetermined value as the frequency of the setting operation performed on the vehicle air conditioner increases when the state information included in the learning data group has a predetermined value. The vehicle air conditioner is weighted so that the specific gravity of the vehicle becomes high . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A data weighting unit (69) for weighting the state information included in the learning data group according to a predetermined rule;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
The current probability information constructed by the learning unit (68) is inputted with current state information representing the current state of the vehicle to calculate the recommended probability, and the setting related to the occupant setting operation according to the recommended probability A control information correction unit (66) for correcting information or control information so as to be the predetermined setting operation;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information ;
A confirmation operation unit (59) for presenting the content of the predetermined setting operation to the passenger and confirming with the passenger whether or not to perform the predetermined setting operation;
Have
When it is confirmed that the predetermined setting operation is performed through the confirmation operation unit (59), the control information correction unit (66) corrects the setting information or control information ,
The storage unit (61) stores a reaction time from the presentation by the confirmation operation unit (59) to an operation for determining whether or not the predetermined setting operation is performed by a passenger.
The vehicle air conditioner is characterized in that the data weighting unit (69) increases the specific gravity of the state information related to the recommendation probability calculated for the predetermined setting operation as the average value of the reaction time is shorter . An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A data weighting unit (69) for weighting the state information included in the learning data group according to a predetermined rule;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
The current probability information constructed by the learning unit (68) is inputted with current state information representing the current state of the vehicle to calculate the recommended probability, and the setting related to the occupant setting operation according to the recommended probability A control information correction unit (66) for correcting information or control information so as to be the predetermined setting operation;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information ;
A confirmation operation unit (59) for presenting the content of the predetermined setting operation to the passenger and confirming with the passenger whether or not to perform the predetermined setting operation;
Have
When it is confirmed that the predetermined setting operation is performed through the confirmation operation unit (59), the control information correction unit (66) corrects the setting information or control information ,
The storage unit (61) performs the predetermined setting operation by the passenger through the confirmation operation unit (59) and the number of times of presentation that the predetermined operation is performed by the confirmation operation unit (59). Storing the number of positive operations that have been performed to determine that in association with the probability model,
The data weighting unit (69) increases the specific gravity of the state information related to the recommendation probability calculated for the predetermined setting operation as the ratio of the number of positive operations to the number of presentations is higher. Vehicle air conditioner. An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A data weighting unit (69) for weighting the state information included in the learning data group according to a predetermined rule;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
The current probability information constructed by the learning unit (68) is inputted with current state information representing the current state of the vehicle to calculate the recommended probability, and the setting related to the occupant setting operation according to the recommended probability A control information correction unit (66) for correcting information or control information so as to be the predetermined setting operation;
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
I have a,
The data weighting unit (69) weights the state information included in the learning data group so that the specific gravity of the state information having a longer elapsed time since acquisition is reduced. apparatus. An air conditioning unit (10) for supplying conditioned air into the vehicle;
An information acquisition unit (51-53, 55-58) for acquiring state information representing a state relating to the vehicle;
A storage unit (61) for storing a plurality of state information acquired by the information acquisition unit (51-53, 55-58) as a learning data group;
A learning unit (68) that uses the learning data group to construct a probability model for calculating a recommendation probability that the occupant performs a predetermined setting operation by inputting state information;
A recommendation probability calculation unit (64) for inputting the current state information representing the current state of the vehicle to the probability model constructed by the learning unit (68) and calculating a recommendation probability for performing the predetermined setting operation;
A threshold setting unit (70) for setting a first threshold and a second threshold lower than the first threshold according to a predetermined rule;
If the recommended probability is equal to or greater than the first threshold value, setting information or control information relating to the occupant of the setting operation, the control information correcting unit for correcting so that the predetermined setting operation and (66),
An air conditioning control unit (67) for performing air conditioning control of the air conditioning unit (10) according to the corrected setting information or control information;
Whether or not to present the contents of the predetermined setting operation to the passenger and perform the predetermined setting operation when the recommendation probability is less than the first threshold and not less than the second threshold A confirmation operation unit (59) for confirming to the passenger,
I have a,
When it is confirmed that the predetermined setting operation is performed through the confirmation operation unit (59), the control information correction unit (66) corrects the setting information or the control information. . The vehicle air conditioner according to claim 16 , wherein the threshold value setting unit (70) lowers the first threshold value or the second threshold value as the reliability of the current state information is higher. The vehicle air conditioner according to claim 16 , wherein the threshold setting unit (70) lowers the first threshold or the second threshold as the number of state information included in the learning data group is smaller. The threshold setting unit (70) increases the difference between the setting information or control information corrected to be the predetermined setting operation and the setting information or control information before the correction as the first threshold or The vehicle air conditioner according to claim 16 , wherein the second threshold value is lowered. The vehicle air conditioner according to claim 16 , wherein the threshold value setting unit (70) lowers the first threshold value or the second threshold value as the frequency of setting operations performed on the vehicle air conditioner increases. . The threshold setting unit (70) decreases the first threshold or the second threshold as the frequency of setting operations performed on the vehicle air conditioner when the current state information has a predetermined value is increased. The vehicle air conditioner according to claim 16 . The storage unit (61) stores a reaction time from the presentation by the confirmation operation unit (59) to an operation for determining whether or not the predetermined setting operation is performed by a passenger.
The vehicle air conditioner according to claim 16 , wherein the threshold value setting unit (70) lowers the first threshold value or the second threshold value as the average value of the reaction time is shorter. The storage unit (61) performs the predetermined setting operation by the passenger through the confirmation operation unit (59) and the number of times of presentation that the predetermined operation is performed by the confirmation operation unit (59). Storing the number of positive operations that have been performed to determine that in association with the probability model,
The vehicle air conditioner according to claim 16 , wherein the threshold setting unit (70) lowers the first threshold or the second threshold as the ratio of the number of positive operations to the number of presentations is higher.

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