A method for obtaining the deformation of a tire casing subjected to a load, rotating at a rotational speed W, comprises the following steps: acquiring a signal comprising the amplitude of the acceleration in the direction normal to the crown when running at the rotational speed W; delimiting the signal over a number of wheel revolutions, so as to construct a wheel revolution signal; determining a reference acceleration; defining a first energy density S which is a function of the wheel revolution signal, and of the reference acceleration, and which is denoted S.sup.+ when the wheel revolution signal is above a threshold value A, or is denoted S.sup.− when the wheel revolution signal is below or equal to said threshold value A; and identifying the deformation generated by the load as a function of the reference acceleration and of the first energy density S.

A method for obtaining the deformation of a tire casing subjected to a load, rotating at a rotational speed W, comprising: Phase 1—Delimiting the first signal over a whole number of wheel revolutions to construct a first wheel revolution signal; and Determining a reference acceleration; and Phase 2—Delimiting the signal over a whole number of wheel revolutions to construct a second wheel revolution signal; Defining at least a first energy density S which is a function of the second wheel revolution signal, and of the reference acceleration, and which is denoted S+ when the wheel revolution signal is above a threshold value A, or is denoted S− when the wheel revolution signal is below or equal to said threshold value A; and Identifying the deformation as a function of the reference acceleration and of the first energy density S.

The invention concerns a tire damage detection method that includes a tire damage detection step comprising: providing an acquisition device (11), which is installed onboard a motor vehicle (2) equipped with two or more wheels fitted with tires, and which is coupled to a vehicle bus (20) of the motor vehicle (2), and a processing device/system (12, 12A, 12B) storing a predefined tire damage model; acquiring, by the acquisition device (11) from the vehicle bus (20), a signal indicative of a speed of a wheel of the motor vehicle (2); outputting, by the acquisition device (11), quantities indicative of the wheel speed; receiving, by the processing device/system (12, 12A, 12B) from the acquisition device (11), the quantities indicative of the wheel speed; computing, by the processing device/system (12, 12A, 12B) based on the quantities indicative of the wheel speed, a normalized wheel speed indicative of a ratio of the wheel speed to an average wheel speed indicative of motor vehicle speed; and detecting, by the processing device/system (12, 12A, 12B), a potential damage to a tire of the wheel of the motor vehicle (2) based on the predefined tire damage model and on the normalized wheel speed. In particular, the tire damage detection method according to the present invention includes also a preliminary step that comprises: performing tests involving test tire impacts against/on different obstacles at different motor vehicle speeds; measuring/acquiring test-related wheel speeds during the performed tests; computing test-related normalized wheel speeds based on the test-related wheel speeds; and determining the predefined tire damage model to be used by the processing device/system (12, 12A, 12B) in the tire damage detection step on the basis of the test-related normalized wheel speeds corresponding to the test tire impacts and of associated test-related average wheel speeds.

The invention concerns a tire damage detection method that includes a tire damage detection step comprising: providing an acquisition device (11), which is installed on board a motor vehicle (2) equipped with two or more wheels fitted with tires, and which is coupled to a vehicle bus (20) of the motor vehicle (2), and a processing device/system (12,12A,12B) storing a predefined tire damage model; acquiring, by the acquisition device (11) from the vehicle bus (20), signals indicative of speeds of the motor vehicle (2) and of a wheel of said motor vehicle (2); outputting, by the acquisition device (11), quantities indicative of the speeds of the motor vehicle (2) and of the wheel thereof; receiving, by the processing device/system (12,12A,12B) from the acquisition device (11), the quantities indicative of the speeds of the motor vehicle (2) and of the wheel of said motor vehicle (2); computing, by the processing device/system (12,12A,12B), based on the quantities indicative of the speeds of the motor vehicle (2) and of the wheel of said motor vehicle (2), a normalized wheel speed indicative of a ratio of the wheel speed to the motor vehicle speed; and detecting, by the processing device/system (12,12A,12B), a potential damage to a tire of the wheel of the motor vehicle (2) based on the predefined tire damage model and on the normalized wheel speed. In particular, the tire damage detection method according to the present invention includes also a preliminary step that comprises: performing tests involving test tire impacts against/on different obstacles at different motor vehicle speeds; measuring/acquiring test-related wheel and motor vehicle speeds during the performed tests; computing test-related normalized wheel speeds based on the test-related wheel and motor vehicle speeds; and determining the predefined tire damage model to be used by the processing device/system (12,12A,12B) in the tire damage detection step on the basis of the test-related normalized wheel speeds and the test-related motor vehicle speeds that correspond to the test tire impacts.

The invention concerns a tire damage detection system (1,1A) that includes an acquisition device (11), a processing system (12,12A) and a notification device (13,13A). The acquisition device (11) is installed on board a motor vehicle (2) equipped with two or more wheels fitted with tires, is coupled to a vehicle bus (20) of the motor vehicle (2), and is configured to acquire, from the vehicle bus (20), a signal indicative of a speed of a wheel of the motor vehicle (2) and output quantities indicative of the wheel speed. The processing system (12,12A) is configured to store a predefined tire damage model and to receive, from the acquisition device (11), the quantities indicative of the wheel speed, and is programmed to compute, based on the quantities indicative of the wheel speed, a normalized wheel speed indicative of a ratio of the wheel speed to an average wheel speed indicative of motor vehicle speed, and detect a potential damage to a tire of the wheel of the motor vehicle (2) based on the predefined tire damage model and on the normalized wheel speed. The notification device (13,13A) is configured to, if a potential damage to the tire of the wheel of the motor vehicle (2) is detected by the processing system (12,12A), signal the detected potential damage to a user (3) associated with the motor vehicle (2). In particular, according to the present invention, the processing system (12) is a cloud computing system (12A) that is wirelessly and remotely connected to the acquisition device (11), while the notification device (13) is an electronic communication device (13A) associated with the user (3) and remotely connected to the cloud computing system (12A) via one or more wired and/or wireless networks.

The present invention relates to an apparatus for monitoring a tire pressure using a mass of a vehicle. Provided is a tire pressure monitoring apparatus using a mass of a vehicle including: a radius analyzing unit; a frequency analyzing unit; a mass estimating unit; a calibration unit; and a low pressure determining unit.

Determining tread depth using data from a tire mounted sensor (TMS), including: determining, based on data collected by the tire mounted sensor, a tire deformation for a tire; determining, based on the tire deformation, an effective rolling radius of the tire; and determining, based at least on the effective rolling radius of the tire, an estimated tread depth for the tire.

The invention concerns a system and a method for detecting potential damages to tires of motor vehicles due to impacts against/on obstacles.

Thread depth ascertainment for vehicle tires involves a plurality of vehicles transmitting respective adaptation data to a central data processor. The data processing device forming optimization data on the basis thereof and transmitting the optimization data to the vehicles. The adaptation data are formed by the vehicles based on tire type, mileage and rotation speed of the tire and a velocity of the vehicle and at least one operating parameter of the tire, and the optimization data are used by each of the vehicles for ascertaining the tread depth of a relevant tire based on model of the ascertained tire type, wherein the model supplies the tread depth based on the rotation speed of the tire, the velocity of the vehicle and at least one operating parameter of the tire using at least one model parameter, which is determined based on the optimization data received from the central data processor.

Disclosed is a method for remotely loading digital data to an electronics unit for measuring operating parameters of a wheel of a motor vehicle, the remote loading being carried out by a remote loading tool external to the wheel. The method includes the positioning of the external remote loading tool in the proximity of the wheel at least, emission of at least one frame of mechanical waves by the external remote loading tool toward the electronics unit, the waves being representative of the data to be remotely loaded, reception of at least the frame of mechanical waves by the electronics unit via the mechanical parameter measurement sensor, and the conversion of the mechanical waves into electrical signals and then into digital signals containing the remotely loaded data in digital form, and the storage of the remotely loaded data in the electronics unit.