How CIOs Can Utilize Predictive Analytics For The Connected Car Industry

Predictive analytics is evolving into a strong mechanism for the automotive industry to solve a vibrant array of problems.

FREMONT, CA: Predictive maintenance in the automotive industry enables to evolve of the traditional market ecosystem through different technical data analytics and statistical methodologies into an intelligent manufacturing unit. The predictive maintenance analysis provides “correct data at the right moment.” It also lays the groundwork for various innovative processes to save costs.

Networked cars are the next sizeable digital project in the automotive industry that by introducing independent driverless cars is sure to generate a technological revolution. These self-driving cars require a complicated sensor circuit where the efficient devices connected to them make the machine-to-machine communications a reality.

Data and software have become essential fabrication components and stretch far beyond vital vehicle production. There is information from riders and travelers inside the vehicle, outside the car. Algorithms play the central part in influencing the next millennium of automobiles because of the significance of information collection, artificial intelligence (AI), data analysis, and then learning from it. As linked vehicles are progressively streaming information from telematics devices, infotainment systems, and the vast range of intelligent IoT devices into the cloud, each connected vehicle is capable of producing over 25 gigabytes per hour as more cloud-based facilities are available. The crucial element in wisely using this information deluge lies in car statistical analytics, and in specific predictive analytics.

Effective and Predictive Maintenance

The task for developers is how to gather, store, and process stunning quantities of information as the cars become faster. Automakers should use AI, information management, and electronic workflows to attain these innovative capacities while accelerating experimentation and simulation in the life cycle of product development. Predictive maintenance seeks to detect problems with car maintenance before they happen. By harnessing details from warranty maintenance using present car sensor information, predictive data analytics can find significant correlations that would be hard to discover for a person. An efficiency anomaly that may seem trivial when noted on a single vehicle could be a red flag when collated with dozens or hundreds of other cars having the same issue. Systems for predictive maintenance analytics can draw details from nearly every vehicle of a specified year and design and contrast that information with developments in-warranty repair.

This predictive maintenance performs a crucial part in preventing unplanned downtime, increasing income, and reducing the price of maintenance facilities. It offers a profound understanding of the health history of the automobile from when it had its first full service to the present situation of the car.

Geological Monitoring intelligence

Location intelligence in manufacturing allows automakers to manipulate place data from a portion of a fully produced item and then add intelligence to it. Various sub-assemblies produced by technologically advanced components help in manufacturing vehicles. Recognizing the physical place of these sub-assemblies and elements is essential at any time to educate the production chain and ensure that the correct sub-assemblies and components consistently reach the correct assembly line. Destination management allows employees to monitor event sites based on RFID and sensor technology information in real-time. Location intelligence also aims to ensure transparency and consistency in assessing and predicting issues before they become serious problems.

Predictive avoidance of collisions

 Technology provides drivers no function that is perhaps more valued than schemes for preventing imminent collisions. By using sophisticated detectors, large and rapid information, and car-to-car interconnection, predictive analytics technology can one day make car accidents outdated. By using sensors on the front of the automobile, the system is able to examine the distance and speed of the car traveling ahead of the vehicle, as well as the speed and direction of the next preceding vehicle typically outside the visual field of the rider. The mechanism notifies the driver with a verbal warning and clear message when either of the two following cars acts in a way that could cause the rider to brake unexpectedly. A signal is also sent in the event of contact to lock the safety belts momentarily. As designers generate apps that enhance communication between linked cars, more complicated and more efficient collision avoidance systems will arise depending on driver behavior prediction.

Connected automobile cybersecurity

With specialists predicting that there will be a half-billion linked cars on the highway by 2020, it is simple to see why they are worried. The reality is, connected vehicles are no less vulnerable to cyber assaults than any other internet-connected device, but the implications of a safety violation could be far more disastrous. One can only imagine the independent attraction cars posing for modern-day cybercriminals in particular.

To render their cars safe from cyber attacks, automakers must use technology that remains a step ahead of cybercriminals. Predictive analytics provides the ability to do that. Whether cybercriminals aim linked cars for the pure effort to profit or as a type of activism, their strategy is the same: discover deficiencies in channels and structures within the attached car environment and use them to obtain private data from passengers or to obtain command of automobile facilities. They always bring proof of their existence as cybercriminals "hack" into a scheme. Classical safety policies are relatively efficient in identifying an intruder's evidence when using the same methods as other intruders used to obtain access.

The potential to recognize metrics is what makes predictive analytics efficient in ensuring linked vehicles, where standard safety policies may fail. At some point, the behavior of each attacker will be different from the action of an authorized user. While being a very over-simplified explanation, the significant thing to understand is the ability of probabilistic data analytics to understand standard behavior models and spot divergences from such activities.

In a way, all linked apps in auto analytics constitute data management instances. Whether we are speaking about using predictive information to enhance servicing, advertising, safety, or other associated operations in the connected vehicle industry, the data must be handled in a manner that makes it helpful for the desired intent.