GR20170100300A - Method for recharging smart devices by related devices connected via a communication data circuit to a central controller - Google Patents

Abstract

There is proposed a method for the recharging of smart devices by related devices which are connected via a communication data circuit to a central controller; the invented recharging device has a circuit feeding the smart device with power via supply of adequate electric currents and voltages while recording the progress of these electrical quantities in time.

Description

Method for charging smart devices from charging devices connected via a data communication circuit to a central controller

Description

The present invention belongs to the field of information security (Information Security) and in particular to that of access control (Access Control) and concerns a method for charging smart devices from charging devices connected via a data communication circuit to a central controller. The method allows smart devices to be identified in order to allow them to be charged in areas with increased security needs.

The use of smart devices (smartphones, tablets, ultra-portables and laptops) is an integral part of the daily life of billions of people. More than 2 billion people use smart phones (smartphones) today, while their number is expected to exceed 6 billion by the year 2020. Tablet users are defined as 1 billion, while hundreds of millions of laptop users are added to these numbers.

The vast majority of these devices use rechargeable electrochemical accumulators (batteries) in order to temporarily store and then release electrical energy that will power microcomputers and their peripherals (monitors, networking subsystems, etc.).

If we consider an average capacity for smartphone batteries (only) in the region of 2.5Ah, and taking into account that basically every one of them is charged at least once every day, it is easy to see the extent of the phenomenon charging process and its energy needs - approximately, on a daily basis, about 16 million kWh or the equivalent annual consumption of 1.6 million households.

All this super-intensive and energy-demanding process currently utilizes conventional low-voltage sockets (sockets) (110-220V) and devices for transforming this low (alternating) voltage into ultra-low direct voltages (low voltage) in the 5V range for charging needs of the devices.

It is a technology, that of conventional sockets, with more than a century of history, that was designed to meet very different needs from those of charging batteries with very low rated currents and voltages (in the region of 1A/5V). Conventional sockets can generate dangerous - even fatal - currents during their use, while they passively and indiscriminately connect any electrical load to the network up to the nominal size of the fuse with which they are connected (usually in the order of 3-5A/220V or 110V).

If the explosive development of the internet was what characterized the previous decade, surely mobile computing will be the one that will characterize the one we are going through. Portable 'devices' carrying computing power, smart phones, watches, clothes, cars, as well as the Internet of Things (Internet of Things), will re-transform our societies and profoundly change the way we live (learn, work , we communicate, we move, etc.).

This significant trend for 'ubiquitous' computing power creates a secondary (trend) for 'ubiquitous' charging infrastructure for all those devices that provide it. After the home, the office and the car, the public space is also called upon to adapt to the new need. It is something that is already happening, and we see it every day around us.

Anywhere we are/stay for more than about 30 minutes an hour, we identify a potential 'charge point'. As battery and charging technologies reduce device charging times, so will the number of places where charging can take place. Where we will stay for 20, 10, 5 or future and even less minutes. Charging mobile devices in public is an upcoming/new service.

The solutions proposed today for this service are essentially two:

1. Conventional (domestic) power sockets offered in public places (shopping malls, airports, etc.) to serve the public - with the disadvantages mentioned in paragraph 3.

2. Shared chargers for portable/mobile devices, which although remove one of the problems of the 'solution of sockets' mentioned above (that of security from free access to the low-voltage network), create another one concerning the security of the smart devices themselves devices.

In both cases no care can be taken for the security of the spaces where the specific solutions are installed, making them unsuitable for spaces with increased security needs.

There is a third 'solution', that of using portable chargers (Power Banks) - essentially independent batteries that charge the built-in batteries of our mobile devices - but it has such a large energy and environmental footprint that it should be treated more as an indication of the existence of the problem rather than as a possible solution to it.

Maintaining security in a public space is of paramount importance, and the solutions of the existing level degrade it, introducing new risks, instead of promoting it.

In addition, every energy process such as charging a battery, when it involves billions of uses on a daily basis, must also be designed based on its performance and ecological footprint.

The use of portable chargers (power banks) for example, could well be an example of anti-ecological design. Specifically:

1. Dramatically increases (doubles) battery production and recycling needs, since for every device battery, almost another one is added for the charger. Although portable chargers can theoretically charge more than one device, this doesn't happen very often in practice. The usual practice is 1:1 and it mainly concerns smart phones. Also, the batteries of the chargers are usually much smaller than those of the devices they charge. This means more raw materials in production and more materials in recycling.

It is worth noting here that to date there is no mature and widely applicable solution for recycling lithium technology batteries (Lithium Ion, Lithium Polymer) - used by the vast majority of smart mobile devices.

This happens for technical reasons (the way they are manufactured is not strictly standardized with the result that there are different materials in different accumulators depending on the manufacturer), but also for economic reasons (technically possible solutions do not give economically viable operation models)

2. It introduces measurable energy losses in the proposed use cycle from the extra charge-discharge of the charger's battery - and which are multiplied for the 3.5+ billion devices.

3. It creates extra load, which in travel has a measurable footprint in carbon dioxide (CO2) emissions: 3.57 billion people traveled by plane in 2015 burdening the atmosphere with 781 million tons of CO2. The average weight of each passenger is determined at 100kg, and of their luggage at 50kg.

If an average portable charger (Power Bank) adds 0.25kg of extra load to each traveller's luggage, this is equivalent to the luggage of 15.5 million people or (very roughly) releasing an extra 680 thousand tonnes of CO2 into the atmosphere.

Of the remaining solutions offered, the use of conventional (domestic) sockets in public places to charge mobile devices poses risks for the safety of the public as well as the space.

Low voltage can become dangerous - even fatal - for users of socket outlets if they are not properly used, designed and all the necessary precautions are not taken in the installation and maintenance of their electrical network. However, the proper study, installation and maintenance of such a network, which is offered free of charge to serve the public, usually ends up being unprofitable in the long run for the one who offers it.

In addition, free access to low voltage sockets degrades the safety of the space in which they are installed. It's not just the uncontrolled access to electricity (which can ultimately be used for malicious actions) that's problematic, it's the more general access provided (via the outlet) to the site's wiring/electrical installation.

It is a solution that, in its current form, in the environment of the ever-increasing needs to safeguard security in public spaces, will not be able (and should not) continue.

Observing, for example, that during the check of hand luggage at the airport it is possible that a small gadget that happens to be in his possession may be taken from a passenger for security reasons, while he is immediately given free access to the airport's low-voltage network, little doubt can be continue to have for the embalming nature of the method.

Finally, in recent years it is customary to install shared chargers in public places to serve the public. The ends of these chargers lead to popular mobile device charging connectors that directly offer ultra-low DC voltages and currents, eliminating the problem of accessing the low voltage of the AC network (power-grid). However, these solutions introduce new problems, this time concerning the security of the smart device, without curing those concerning the security of the space in which they are installed.

In particular, modern smart phones, for reasons of saving space inside the device, combine their charging terminal with the terminal for wired communication with the device. Thus, by connecting a smart phone to a charger, we also indirectly give access to a communication channel with it, and in fact to a channel that does not currently have the same security infrastructure as the device's wireless channels (mobile networks, wireless local networks such as WiFi, etc.) ), since it is basically designed to connect to homes/secure devices.

The risks of data interception, installation of viruses, malware or even the challenges of material damage to smartphones from connecting them to unsafe chargers has been extensively documented since 2011 until today.

In addition, as in the case of the use of household sockets, with regard to the space where shared chargers are installed, security problems remain, since the identity of the devices and their use remains unknown. Thus, security e.g. of a subway station cannot know whether a smartphone or other device is actually connected to the shared charger of its premises and/or whether a connected smartphone is simply charging or acting as a camera that relays images from inside the station in violation the safety regulations of .

So we see that while in existing solutions we can limit the risks arising for users of the charging service (proper design, installation and maintenance of a network of household sockets - continuous surveillance/certification of shared chargers), absolutely no care can be taken for the providers of the service. For the latter, who are charged with the most demanding task, that of safeguarding general/common security, the identity of the device connected in order to be charged, and any of its functions during its charging, remain unknown.

The present invention proposes a method for charging smart devices from charging devices connected via a data communication circuit to a central controller, which can identify smart devices in order to allow their charging in areas with increased security needs.

In addition to the electrical connection (wired or wireless, e.g. inductive charging) of the charging device to the smart device, through which the charging voltages/currents of its integrated battery (charging circuit) are provided, the Secure Pairing where provided by the method further assumes the existence of a wired or wireless data communication channel (data circuit) between the smart device and the charging device. Smart devices can combine in one connector their wired charging terminal with the wired data communication terminal (USB, Micro USB), or the data communication channel (data circuit) between the smart device and the charging device can be implemented wirelessly via Bluetooth, WiFi, NFC, etc.

Connecting the smart device to the charging circuit causes a characteristic current to flow from the charging device to the smart device, while an equally characteristic voltage can be measured at the ends of the charging circuit. The charging currents and voltages are indicative of the state in which a specific battery is at any given time (fully/partially charged, new or old), but they also determine with great precision the current energy needs (consumption) of the device, offering a useful energy footprint (Energy Fingerprint).

Through the data circuit, the charger can also gain access to an extensive set of digital fingerprints of the device.

Static digital fingerprints characterize a series of technical characteristics of the microcomputer system carried by legitimate smart devices, based on the official specifications of their manufacturer. These can be: the type of their central processor (CPU), graphics processor (GPU) and/or other specialized processors (eg sound) that they may have. It can also be the size of the main memory (RAM) and auxiliary memories, the resolutions of the screen and the camera/cameras, the specifications of the communication systems (mobile telephony, local network, Bluetooth, GPS, NFC, USB, etc.). ), as well as any sensors that are integrated (fingerprint readers, acceleration sensors, gyroscopes, compasses, barometers, etc.), microphones, speakers and/or other peripherals. Static digital footprints are also e.g. the stock code (SKU) or description of the specific model of the smart device, as well as its unique identification numbers such as: International Mobile Equipment Identity (IMEI), International Mobile Subscriber Identity (IMSI), Mobile Equipment Identifier (MEID), Media Access Control Address (MAC Address) etc.

As dynamic digital fingerprints we also characterize the states of the hardware (hardware) of the smart device (e.g. camera on/off, WiFi on/off, device under charge yes/no, percentage of CPU usage, percentage of charge of the built-in battery, etc. .a.), the measurements of its sensors/receivers (e.g. temperature of the device, GPS position, etc.) and the performances of the microcomputer system of the smart devices under load in the execution of specific actions (tasks). Indicatively such performance-action can be the time needed by the central processor to calculate a series of sums or to copy a volume of data from one area of memory to another.

More generally, any task that determines states of the hardware of the smart device and/or uses hardware of the microcomputer system of the smart device under load, the use of which can be quantified/measured and/or ultimately determine performance (performance), potentially creates a dynamic digital footprint.

A special case of action (task) is the action of turning on/off the charging circuit. This action is performed on the charging device and not on the smart device. As part of this action, the charging device interrupts the power supply to the smart device permanently/permanently or temporarily. Temporarily, to determine if this outage is traceable through a dynamic device fingerprint collected through the charger-device data circuit. For example, the charging device interrupts the power supply to the smart device at random intervals during charging, for a period of time (e.g. 1 sec) each time, and collects (each time) its corresponding dynamic digital fingerprint device. If the power failure is not detectable via the device's dynamic fingerprint, then it is assumed that the data circuit is not connected to the device being charged and charging is stopped.

A dynamic energy footprint is defined as the minimum/maximum deviation of the monitored electrical quantities caused by the execution of an action that uses hardware of the microcomputer system of the smart device under charge, as well as the minimum/maximum start and end time of the observation of these deviations .

According to the invention, through the data circuit between the smart device and the charging device, the charging device can obtain knowledge of the technical characteristics of a smart device, and based on them then trigger actions (tasks) which in turn will affect characteristics in the dynamic energy footprint of the device under load - thereby developing an 'out-of-band' feedback and control loop.

Thus, the data circuit between the smart device and the charging device is used in order for the charging device to:

1. To determine the technical characteristics of a smart device (by comparing them with those of its official manufacturer) but also

2. To cause actions (tasks) in it (while comparing the performance of each device under charge with the performance of valid -legitimate devices).

By leveraging static fingerprints, triggering tasks, and analyzing dynamic digital and energy fingerprints, the charger can easily identify counterfeit devices and exclude them from the charging process, while also detecting more sophisticated attempts of his manipulation/deception.

The charging interfaces, wired and wireless, are physically/electrically separated. The figure shows a conventional smart device (A) and a malicious device (B), which share a USB connector, where OL power pins (1 & 4) are connected to the malicious device (B) and data pins (2 & 3) are connected to the conventional smart device (A). So someone could connect a malicious device (B) to the charging circuit, and a conventional one (A) to the data circuit in an attempt to bypass the control. The charging device, through the central controller, would check the static fingerprints of the conventional device (A) and find them valid, while essentially charging a different device, (B).

Applying the proposed method, the charging device collects static digital fingerprints of the conventional smart device (A) that identify the type of the smart device (A), which it communicates to the central controller and receives test patterns (Test Patterns) corresponding to the type of the smart device (A) according to her static fingerprints. Based on these (the control patterns) the charging device triggers actions (tasks) on the smart device (A), indirectly/parallelly affecting, in a pre-planned and controlled way, the dynamic energy footprint and/or the dynamic digital footprints of the device (A) which he compares with the prescribed allowable prints contained in the control samples.

Due to the smart device (A) being tested, the dynamic energy footprint of the device (B) (under load) will not change within the limits prescribed by the test models (for the type of device (A) ) causing charging to stop.

The proposed method, in addition to being able to identify a smart device, can also safely confirm that it (the identified device) is being charged and not another.

In this way, the problem of determining the identity of smart devices connected to a charger (in order to be charged), as well as their use during charging, is completely removed, offering a critical security tool to relevant service providers.

The proposed method also gives the possibility of enforcing specific rules and operating conditions of a smart device during its charging process. In particular, the respective provider/operator of the charging service (e.g. the security service of an airport, a railway station or a hospital) may request the deactivation of certain functions (e.g. the function of connecting to mobile networks, the function of the microphone or camera) ) or even completely turning off the device while charging.

Through the data circuit, and optionally with the authorization of the owner (owner) of the smart device, the charging device can disable the functions that are not allowed each time, as well as confirm their deactivation through the fingerprint of the currents and voltages in the charging circuit (potential energy footprint) and/or corresponding potential digital footprints.

It is also important to mention that the cost of developing charging devices that implement the method remains particularly low.

The main costs in the manufacture of a charger will still come (as in the common/conventional ones) from the cost of its transformer, the cost of the electronic rectifiers, the mechanical shell, the required certifications, the cables, etc.

The addition of a small microcontroller that will be able to sample the current and voltage of the charging circuit through two analog-to-digital converters (ADC), and will have digital communication subsystems to implement the data circuit and remote management of the charger ( central controller), will add little to his final bill of materials (Bill of Materials).

For example, Microchip's ATSAML21 series, or Texas Instruments' MSP430 series microcontrollers suitable for the application cost less than US$2/piece for very small quantities (under 1000 pieces), while ending up costing less than 1 USD/piece for large.

According to the invention there is proposed a method for charging smart devices by charging devices connected via a data communication circuit to a central controller, where the charging device has a charging circuit to the smart device, through which it supplies the smart device with electricity through the providing appropriate currents and voltages, while recording the evolution of these two electrical quantities over time. Smart devices can combine their wired charging terminal with a wired data communication terminal (USB, Micro USB) in one connector. The charging circuit to the smart device and/or the data communication circuit between the smart device and the charging device can alternatively be implemented wirelessly.

According to the invention, a data communication circuit is created between the smart device and the charging device, through which the charging device collects the static digital fingerprints of the smart device under charge that identify the type of the smart device, which it communicates to the central controller and receives samples control (Test Patterns) corresponding to the type of smart device according to its static digital fingerprints, based on which (control patterns) the charging device causes actions (Tasks) to the smart device, influencing indirectly/in parallel, in a pre-planned and controlled way , its dynamic energy fingerprints monitored by the charging circuit and/or its dynamic digital fingerprints, which are collected through the data communication circuit.

The charging device determines states of the hardware (hardware) of the smart device and/or performances of the smart device under charge as a result of the execution of these actions as dynamic digital and/or energy footprints, which it compares with the prescribed allowable footprints contained in the models control, while informing the central controller of the result (successful or not) of the submission of the smart device to them (the control patterns), where as long as the dynamic digital/energy fingerprints remain within the limits prescribed by the control patterns, the process of charging continues normally, otherwise the central controller is asked to send new control samples or charging is interrupted.

The collection of the static digital fingerprints of the smart device occurs once each time it is connected to the charging device, while the submission of the smart device to control samples may be repeated at predetermined or undefined time intervals, and in any case if the current in the charging circuit reset, if this does not occur as foreseen in the context of the execution of a specific action, in the context of which the control model requests the interruption of the power supply to the device, in order to see if this interruption is detectable through the dynamic digital footprint of the device through the charger-device data circuit. In this way, the charging device can at any time confirm to the central controller that the device under charge (connected to the charging circuit) and the identified device to which the data circuit of the charging device is connected are identical.

Repeating the collection of static digital fingerprints of the smart device and subjecting the smart device to test samples if the current in the charging circuit goes to zero, if this does not occur as predicted in the context of performing a particular action is central: zero current means possible disconnection of the smart device, so the device identification must be repeated.

Control patterns are defined as pairs of actions (Tasks) - dynamic fingerprints or actions (Tasks) - dynamic energy fingerprints, where the control patterns of dynamic digital fingerprints describe an action on the smart device under charge and determine states of the hardware (hardware) of the smart device and/or give the minimum and maximum time allowed for its completion and where the dynamic energy footprint control samples describe an action on the smart device under charge and give the minimum/maximum deviation of the monitored electrical quantities that the execution of this action is allowed to cause, as well as the minimum/maximum start and end time of observing these deviations. Static fingerprints are defined as technical characteristics of the microcomputer system carrying OL smart devices, through which the smart device is identified, through comparison with corresponding digital fingerprints of its official manufacturer or authorized body.

According to the method, during the charging process of a smart device, specific operating rules of the smart device can be imposed through the data communication circuit between the smart device and the charging device.

According to the invention, through the data communication circuit between the smart device and the charging device, specific functions of the smart device can be deactivated, such as the function of connecting to mobile networks or the function of other communication systems, the function of the microphone or the camera, while the complete deactivation of the device may even be imposed.

Through the central controller, all charging devices connected to that particular controller are monitored/supervised and the control patterns are designed/stored (and then communicated).

Through the control models, the security protocols of the charging device network manager are essentially implemented. So, if for example the manager of the network of chargers (e.g. an airport security service), wants the smart device's WiFi disabled while charging (while the Device's fingerprint shows it enabled), they can send the device charging a control model that requests e.g. the deactivation of WiFi and prescribes the impact of this deactivation on the charging circuit (reduction of power supply to the device).

Claims (10)

A X I O S E I S 1. A method for charging smart devices by charging devices connected via a data communication circuit to a central controller, wherein the charging device has a charging circuit to the smart device, through which it supplies the smart device with electricity by providing suitable currents and voltages, while recording the evolution of these two electrical quantities over time, characterized by the fact that a data communication circuit is created between the smart device and the charging device, through which the charging device collects static digital fingerprints of the smart device that identify the type of smart device device, which it communicates to the central controller and receives test patterns (Test Patterns) that correspond to the type of smart device under charge according to the static digital fingerprints of the smart device, based on which (test patterns) the charging device causes actions (tasks ) on the smart device, ff by indirectly/paralleling, in a pre-planned and controlled manner, its dynamic energy fingerprints monitored by the charging circuit and/or its dynamic digital fingerprints, which are collected through the data communication circuit, where the charging device determines hardware states (hardware) of the smart device and/or performances of the smart device under load as a result of the execution of these actions as dynamic digital and/or energy footprints, which it compares with the prescribed allowable footprints contained in the control samples, while informing the central controller for the result (successful or not) of submitting the smart device to them (the control samples), where as long as the dynamic digital/energy footprints remain within the limits prescribed by the control samples, the charging process continues normally, otherwise the central controller is requested to send a new subsample controls or charging is interrupted. 2. A method for charging smart devices according to claim 1, characterized in that the collection of the static digital fingerprints of the smart device occurs once every time it is connected to the charging device, while its submission to control samples can be repeated at predetermined or non-time intervals, and in any case if the current in the charging circuit goes to zero, if this does not occur as foreseen in the execution of a specific action, in the context of which the control model requests the interruption of the supply of current to the device, in order to establish if this interruption is detectable through its dynamic fingerprint through the charger-device data circuit. 3. Method for charging smart devices according to claim 1 or 2, characterized in that pairs of actions (Tasks) - dynamic digital footprints or actions (Tasks) - dynamic energy footprints are defined as control patterns, where the control patterns of the dynamic digital footprints describe an action on the smart device under charge and identify states of the hardware (hardware) of the smart device and/or give the minimum and maximum allowable time to complete it and where the dynamic energy footprint control exemplars describe an action on the smart device under charge and they give the minimum/maximum deviation of the monitored electrical quantities that the execution of this action is allowed to cause, as well as the minimum/maximum start and end time of the observation of these deviations. 4. Method for charging smart devices according to claim 1, 2 or 3, characterized in that the static fingerprints are defined as technical characteristics of the microcomputer system carried by the smart devices, through which the smart device is identified by comparison with respective digital fingerprints of its official manufacturer or authorized body. 5. Method for charging smart devices according to claim 4, characterized by the static fingerprint can be the type of central processing unit (CPU), graphics processing unit (GPU) and/or other specialized processors, the size of the central memory (RAM) and auxiliary memories, the resolutions of the screen and the camera(s), the specifications of the communication systems such as mobile telephony, local network, Bluetooth, GPS, NFC, USB, any sensors of the smart device, the name of the device manufacturer and the inventory code/description of the specific model as well as unique identifying numbers such as International Mobile Equipment Identity (IMEI), International Mobile Subscriber Identity (IMSI), Mobile Equipment Identifier (MEID), Media Access Control Address (MAC Address). 6. A method for charging smart devices according to claim 1, 2, 3, 4 or 5, characterized in that during the charging process of a smart device through the data communication circuit between the smart device and the charging device, and optionally with the authorization of its owner, specific operating rules of the smart device are imposed. 7. A method for charging smart devices according to claim 6, characterized in that through the data communication circuit between the smart device and the charging device, and optionally with the authorization of its owner, specific functions of the smart device are disabled , such as the operation of connecting to mobile networks or the operation of other communication systems, the operation of the microphone or camera, or even the complete deactivation of the device. 8. Method for charging smart devices according to claim 7, characterized in that the deactivation of the functions is confirmed through the imprint of the currents and voltages in the Charging Circuit (dynamic energy fingerprint) and/or the collection of corresponding digital digital fingerprints. A method for charging smart devices according to claim 1, 2, 3, 4, 5, 6, 7 or 8, characterized in that the smart devices combine their wired charging terminal with a wired data communication terminal in one connector (connector). 10. Method for charging smart devices according to claim 1, 2, 3, 4, 5, 6, 7 or 8, characterized in that the charging circuit to the smart device and/or the data communication circuit between the smart device and of the charging device is implemented wired or wirelessly.