WO2023057809A1 - System and method for achieving an uninterrupted exchange of data - Google Patents

Abstract

A system for achieving an uninterrupted exchange of data is disclosed. The system includes a processing subsystem which includes a linking module (40) which creates an integrated platform when a linkage-type of the link corresponds to a broader-level linkage type. The processing subsystem also includes a mapping module (50) which updates standard rule(s) and protocol(s), maps first unique credential(s) with an Internet Protocol address, generates a first unique identifier, and assigns to the first device. The processing subsystem also includes a communication module (60) which receives a first request from the first device upon registration, validates and verifies an authenticity of the first device on the integrated platform by exchanging user information between the cellular network infrastructure and the internet service provider platform, provides the first service(s) to the first device, and updates the first register dynamically with the first unique identifier upon detection of a connection switching, thereby achieving the uninterrupted exchange of the data.

Description

SYSTEM AND METHOD FOR ACHIEVING AN UNINTERRUPTED EXCHANGE OF DATA EARLIEST PRIORITY DATE: This Application claims priority from a Complete patent application filed in India having Patent Application No. 202121045726, filed on October 07, 2021 and titled “SYSTEM AND METHOD FOR ACHIEVING ANUNINTERRUPTED EXCHANGE OF DATA”. FIELD OF INVENTION Embodiments of a present disclosure relate to communication technology, and more particularly to a system and method for achieving an uninterrupted exchange of data. BACKGROUND Exchange of data refers to a mutual transfer of information between people and devices. The data includes voiceover data, an audio file, a video, a video file, a document, an image, a text message, or the like. Conventionally, people use services provided by multiple mobile network operators for communicating with each other via the cellular network. Also, people use services of internet service providers (ISPs)for receiving email services, domain registration, web hosting, browser services, and the like. Moreover, the multiple mobile network operators and the ISPs work independently for providing respective services to people. However, in the case of remote areas where the cellular network may not reach, people might face problems contacting other people and opt for other means of communication. Further, in the case of using the internet for communication, the IP address keeps on changing and may cause secured connectivity-related issues as people may not be able to track back the device with whom they were connected sometime earlier because of a change in the IP address. Hence, there is a need for an improved system and method for achieving an uninterrupted exchange of data between one or more users which addresses the aforementioned issues. BRIEF DESCRIPTION In accordance with one embodiment of the disclosure, a system for achieving an uninterrupted exchange of data is provided. The system includes a processing subsystem hosted on a server. The processing subsystem is configured to execute on a network to control bidirectional communications among a plurality of modules. The processing subsystem includes a linking module. The linking module is configured to create an integrated platform upon establishing a link between cellular network infrastructure and an internet service provider platform based on one or more predefined conditions when a linkage-type of the link corresponds to a broader-level linkage type. The processing subsystem also includes a mapping module operatively coupled to the linking module. The mapping module is configured to update one or more standard rules and one or more protocols associated with at least one of the cellular network infrastructure and the internet service provider platform, upon creating the integrated platform. The mapping module is also configured to map one or more first unique credentials associated with a first device of one or more users with an Internet Protocol address by updating a first register allocated to the corresponding first device on the integrated platform, with the Internet Protocol address, based on the one or more standard rules and the one or more protocols updated, upon registration of the first device. The mapping module is also configured to generate a first unique identifier using a plurality of first details associated with the corresponding first device based on the mapping of the one or more first unique credentials with the Internet Protocol address. The first unique identifier corresponds to indicative of the one or more first unique credentials being mapped with the Internet Protocol address. Further, the mapping module is also configured to assign the first unique identifier to the corresponding first device by updating the first register with the corresponding first unique identifier on the integrated platform. Further, the processing subsystem also includes a communication module operatively coupled to the mapping module. The communication module is configured to receive a first request from the first device upon assigning the first unique identifier to the corresponding first device. The first request includes a request for receiving one or more first services from the corresponding integrated platform. The communication module is also configured to validate and verify an authenticity of the corresponding first device on the integrated platform by exchanging first device information of the corresponding first device between the cellular network infrastructure and the internet service provider platform upon receiving the corresponding first request. Further, the communication module is configured to provide the one or more first services to the corresponding first device upon validating and verifying the authenticity. Furthermore, the communication module is also configured to update the first register dynamically with the first unique identifier upon detection of a connection switching of the corresponding first device between the cellular network infrastructure and the internet service provider platform, thereby achieving the uninterrupted exchange of the data. In accordance with another embodiment, a method for achieving an uninterrupted exchange of data is provided. The method includes creating an integrated platform upon establishing a link between cellular network infrastructure and an internet service provider platform based on one or more predefined conditions when a linkage-type of the link corresponds to a broader-level linkage type. The method also includes updating one or more standard rules and one or more protocols associated with at least one of the cellular network infrastructure and the internet service provider platform, upon creating the integrated platform. Further, the method also includes mapping one or more first unique credentials associated with a first device of one or more users with an Internet Protocol address by updating a first register allocated to the corresponding first device on the integrated platform, with the Internet Protocol address, based on the one or more standard rules and the one or more protocols updated, upon registration of the first device. Furthermore, the method also includes generating a first unique identifier using a plurality of first details associated with the corresponding first device based on the mapping of the one or more first unique credentials with the Internet Protocol address, wherein the first unique identifier corresponds to indicative of the one or more first unique credentials being mapped with the Internet Protocol address. Furthermore, the method also includes assigning the first unique identifier to the corresponding first device by updating the first register with the corresponding first unique identifier on the integrated platform. Furthermore, the method also includes receiving a first request from the first device upon registration via the first device of the corresponding one or more users, wherein the first request includes a request for receiving one or more first services from the corresponding integrated platform. Furthermore, the method also includes validating and verifying an authenticity of the corresponding first device on the integrated platform by exchanging first device information of the corresponding first device between the cellular network infrastructure and the internet service provider platform upon receiving the corresponding first request. Furthermore, the method also includes providing the one or more first services to the corresponding first device upon validating and verifying the authenticity. Furthermore, the method also includes updating the first register dynamically with the first unique identifier upon detection of a connection switching of the corresponding first device between the cellular network infrastructure and the internet service provider platform, thereby achieving the uninterrupted exchange of the data. To further clarify the advantages and features of the present disclosure, a more particular description of the disclosure will follow by reference to specific embodiments thereof, which are illustrated in the appended figures. It is to be appreciated that these figures depict only typical embodiments of the disclosure and are therefore not to be considered limiting in scope. The disclosure will be described and explained with additional specificity and detail with the appended figures. BRIEF DESCRIPTION OF THE DRAWINGS The disclosure will be described and explained with additional specificity and detail with the accompanying figures in which: FIG. 1 is a block diagram representation of a system for achieving an uninterrupted exchange of data in accordance with an embodiment of the present disclosure; FIG.2 is a block diagram representation of an exemplary embodiment of the system for achieving an uninterrupted exchange of data of FIG. 1 in accordance with an embodiment of the present disclosure; FIG. 3 is a block diagram of a communication controlling computer or a communication controlling server in accordance with an embodiment of the present disclosure; and FIG.4 (a) and FIG.4 (b) are flow charts representing steps involved in a method for achieving an uninterrupted exchange of data in accordance with an embodiment of the present disclosure. Further, those skilled in the art will appreciate that elements in the figures are illustrated for simplicity and may not have necessarily been drawn to scale. Furthermore, in terms of the construction of the device, one or more components of the device may have been represented in the figures by conventional symbols, and the figures may show only those specific details that are pertinent to understanding the embodiments of the present disclosure so as not to obscure the figures with details that will be readily apparent to those skilled in the art having the benefit of the description herein. DETAILED DESCRIPTION For the purpose of promoting an understanding of the principles of the disclosure, reference will now be made to the embodiment illustrated in the figures and specific language will be used to describe them. It will nevertheless be understood that no limitation of the scope of the disclosure is thereby intended. Such alterations and further modifications in the illustrated system, and such further applications of the principles of the disclosure as would normally occur to those skilled in the art are to be construed as being within the scope of the present disclosure. The terms "comprises", "comprising", or any other variations thereof, are intended to cover a non-exclusive inclusion, such that a process or method that comprises a list of steps does not include only those steps but may include other steps not expressly listed or inherent to such a process or method. Similarly, one or more devices or sub-systems or elements or structures or components preceded by "comprises... a" does not, without more constraints, preclude the existence of other devices, sub-systems, elements, structures, components, additional devices, additional sub-systems, additional elements, additional structures or additional components. Appearances of the phrase "in an embodiment", "in another embodiment" and similar language throughout this specification may, but not necessarily do, all refer to the same embodiment. Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by those skilled in the art to which this disclosure belongs. The system, methods, and examples provided herein are only illustrative and not intended to be limiting. In the following specification and the claims, reference will be made to a number of terms, which shall be defined to have the following meanings. The singular forms “a”, “an”, and “the” include plural references unless the context clearly dictates otherwise. Embodiments of the present disclosure relate to a system for achieving an uninterrupted exchange of data. As used herein, the term “exchange of data” refers to a mutual transfer of information between people and devices. In one embodiment, the data may include voiceover data, an audio file, a video, a video file, a document, an image, a text message, or the like. The system described hereafter in FIG. 1 is the system for achieving the uninterrupted exchange of the data. FIG. 1 is a block diagram representation of a system (10) for achieving an uninterrupted exchange of data in accordance with an embodiment of the present disclosure. The system (10) includes a processing subsystem (20) hosted on a server (30). In one embodiment, the server (30) may include a cloud server. In another embodiment, the server (30) may include a local server. The processing subsystem (20) is configured to execute on a network (not shown in FIG. 1) to control bidirectional communications among a plurality of modules. In one embodiment, the network may include a wired network such as a local area network (LAN). In another embodiment, the network may include a wireless network such as wireless fidelity (Wi-Fi), Bluetooth, Zigbee, near field communication (NFC), infra-red communication (RFID), or the like. The processing subsystem (20) includes a linking module (40). The linking module (40) is configured to create an integrated platform upon establishing a link between cellular network infrastructure and an internet service provider platform (ISP platform) based on one or more predefined conditions when a linkage-type of the link corresponds to a broader-level linkage type. As used herein, the term “cellular network infrastructure” refers to an infrastructure that includes a network of cells each with a base station through which mobile phones and other mobile devices transmit data and voice. Also, as used herein, the term “internet service provider platform” refers to a platform controlled by an internet service provider (ISP) which is a company that provides web access to both businesses and consumers. ISPs may also provide other services such as email services, domain registration, web hosting, browser services, and the like. Thus, upon establishing the link between the cellular network infrastructure and the ISP platform, the integrated platform may be obtained, wherein the integrated platform may be adapted to facilitate at least one of communication, an exchange of information, a switching service, and the like between the cellular network infrastructure and the ISP platform. Further, in one embodiment, the one or more predefined conditions may include at least one of an agreement between the cellular network infrastructure and the ISP platform, a permission to exchange information of one or more users with each other, one or more government-based rules, and the like. Also, as used herein, the term “broader-level linkage-type” refers to a type of linkage which is established between one or more entities without any intervention of an end-user of the one or more entities. In one embodiment, the one or more entities may include at least one of the cellular network infrastructure, the ISP platform, and the like. Upon integrating or linking the cellular network infrastructure and the ISP platform with each other on the integrated platform, one or more standard rules and one or more protocols followed by the cellular network infrastructure and the ISP platform independently may need a modification to provide the uninterrupted exchange of the data. In one embodiment, the exchange of the data may occur between at least one of the one or more users and one or more devices. In one embodiment, the one or more users and the one or more devices may be using one or more facilities provided by at least one of the cellular network infrastructure and the ISP platform. In one exemplary embodiment, the one or more facilities provided by the cellular network infrastructure may include at least one of transferring voice, transferring data, a messaging facility, a calling facility, and the like. Similarly, in one exemplary embodiment, the one or more facilities provided by the ISP platform may include at least one of surfing web, shop online, conduct business, connect with family and friends, an email service, a domain registration facility, a web hosting facility, one or more browser packages, and the like. Thus, the processing subsystem (20) also includes a mapping module (50) operatively coupled to the linking module (40). The mapping module (50) is configured to update the one or more standard rules and the one or more protocols associated with at least one of the cellular network infrastructure and the ISP platform, upon creating the integrated platform. Basically, in an embodiment, the one or more standard rules and the one or more protocols may be established to determine how the data is transmitted between different devices in the same network, essentially, connected devices to communicate with each other, regardless of any differences in one or more internal processes, structure or design. In one embodiment, the one or more standard rules and the one or more protocols associated with the cellular network infrastructure may depend on one or more cellular technologies used for communication. In one embodiment, the one or more cellular technologies may include at least one of one or more multiplexing techniques, Global System for Mobile communications (GSM), Code Division Multiple Access (CDMA), Wireless in Local Loop (WLL), General Packet Radio Services (GPRS), and the like. Similarly, in one embodiment, the one or more standard rules and the one or more protocols associated with the ISP platform may include at least one of Transmission Control Protocol (TCP), Internet Protocol (IP), User Datagram Protocol (UDP), File Transfer Protocol (FTP), and the like. However, when the cellular network infrastructure and the ISP platform may be integrated or linked, the one or more standard rules and the one or more protocols may vary. Upon updating the one or more standard rules and the one or more protocols, each of the one or more user devices of the one or more users, and the one or more devices may have to be allocated with a unique identifier, upon registration of the one or more devices and the one or more user devices on the integrated platform. In one exemplary embodiment, the one or more devices and the one or more user devices may include at least one of a mobile phone, a tablet, a laptop, an Internet of Things (IoT) device, a broadband router, a camera, a digital speaker, or the like. Also, in one exemplary embodiment, the one or more devices and the one or user devices may include a first device, a second device, and the like. Thus, the mapping module (50) is also configured to map one or more first unique credentials associated with the first device of the one or more users with an Internet Protocol (IP) address by updating a first register allocated to the corresponding first device on the integrated platform, with the IP address, based on the one or more standard rules and the one or more protocols updated, upon registration of the first device. In one embodiment, the one or more first unique credentials may include at least one of a mobile number, an Aadhar card number, a passport number, a social security number, an International Mobile Equipment Identity (IMEI) number, a serial number, a model number, a device identification number, and the like. As used herein, the term “Internet Protocol address” refers to a unique string of characters that identifies each computer using the Internet Protocol to communicate over a network. In one embodiment, the IP address may be private, public, or static. Also, in one embodiment, the IP address may be Internet Protocol version 4 (IPv4) or Internet Protocol version 6 (IPv6). However, the IP address generated may be generated based on the one or more standard rules and the one or more protocols updated by the mapping module (50). The mapping module (50) may also be configured to generate a first unique identifier using a plurality of first details associated with the corresponding first device based on the mapping of the one or more first unique credentials with the IP address. In one embodiment, the first unique identifier may be the unique identifier described above. The first unique identifier may correspond to indicative of the one or more first unique credentials being mapped with the IP address. In one exemplary embodiment, as used herein, the term “first unique identifier” refers to an IP provided with at least one of a plurality of prefix bits, a plurality of suffix bits, a plurality of reserved bits, and the like, to give an indication that the corresponding one or more first unique credentials are mapped with certain IP. In an alternative exemplary embodiment, as used herein, the term “first unique identifier” refers to a string of at least one of numbers, characters, symbols, keywords, alphanumeric characters, and the like, giving an indication that the corresponding one or more first unique credentials are mapped with certain IP. Moreover, in one embodiment, the first unique identifier may be similar to or resemble the one or more first unique credentials, an IP address, a name, or the like. For example, a mobile number associated with a mobile phone of a person can be mapped with an IP address and the IMEI number may be updated to give an indication that the corresponding mobile number is mapped with the IP address, and hence the corresponding IMEI number can be used as the first unique identifier. Later, the mapping module (50) may also be configured to assign the first unique identifier to the corresponding first device by updating the first register with the corresponding first unique identifier on the integrated platform. Basically, for generating and assigning the first unique identifier to the first device, the first device may have to be registered on the integrated platform. Thus, in one embodiment, the processing subsystem (20) may also include a registration module (as shown in FIG. 2) operatively coupled to the linking module (40). The registration module may also be operatively coupled to the mapping module (50). The registration module may be configured to register the one or more users on the integrated platform upon receiving the plurality of first details associated with the first device. Ultimately, the first device may get registered on the integrated platform along with the registration of the corresponding one or more users. In one embodiment, the plurality of first details may be stored in a database (as shown in FIG.2) of the system (10), wherein the database may be a local database or a cloud database. In one exemplary embodiment, the plurality of first details may include a username, a geo-location of the first device, one or more contact details, and the like. Mostly, in an embodiment, whenever the one or more users own the first device, the one or more first unique credentials may be associated with the first device, wherein the one or more first unique credentials may be used to identify the first device when the first device may be connected to the cellular network infrastructure. However, when the first device may get connected to the ISP platform, a conventional IP address may be allocated which may vary with change in the ISP platform. Therefore, the first unique identifier generated may be mapped with the one or more first unique credentials. Thus, whenever, the one or more users or the first device may be contacted via the one or more first unique credentials, the corresponding first unique identifier may also be fetched from the first register allocated to the corresponding first device, which indicates that the corresponding one or more first unique credentials are mapped with the IP address. Suppose the one or more users or the first device may be willing to receive one or more first services from the integrated platform. Then, the corresponding first device may send a request for the same by initiating a connection using the one or more first unique credentials. Thus, the processing subsystem (20) also includes a communication module (60) operatively coupled to the mapping module (50). The communication module (60) is configured to receive a first request from the first device upon assigning the first unique identifier to the corresponding first device. The first request includes a request for receiving the one or more first services from the corresponding integrated platform. In one embodiment, the one or more first services may include a voice call service, a messaging service, a video call service, a voice over Internet Protocol service, a video over Internet Protocol service, a messaging service over Internet Protocol, exchange of the data over the cellular network infrastructure, exchange of the data over the ISP platform, or the like. The communication module (60) is also configured to validate and verify an authenticity of the corresponding first device on the integrated platform by exchanging first device information of the corresponding first device between the cellular network infrastructure and the ISP platform upon receiving the corresponding first request. In one embodiment, the first device information may also be available on the database. The first device information may correspond to at least one of the plurality of first details associated with the first device, the first unique identifier mapped with the one or more first unique credentials associated with the first device, a call history, a message history, a type of the first device, and the like. The authenticity of the first device may be validated and verified based on the first device information that may have been exchanged between the cellular network infrastructure and the ISP platform via the integrated platform. Later, the communication module (60) is also configured to provide the one or more first services to the corresponding first device upon validating and verifying the authenticity. Suppose the one or more users may be traveling or the first device is in movement and move out of a network coverage area of at least one of the cellular network infrastructure and the ISP platform. Now, the cellular network infrastructure and the ISP platform may be established at a plurality of geographical locations with a respective predefined coverage area allocated to each. As the one or more users may be traveling, the first device may switch a connection between one or more cells of the cellular network infrastructure. Similarly, the first device may also switch the connection between the cellular network infrastructure and the ISP platform. During this process, if the first device may be registered on the integrated platform, then the first device information may be updated in a way similar to a handover process that occurs during a cell switching process. Thus, the communication module (60) is also configured to update the first register dynamically with the first unique identifier upon detection of a connection switching of the corresponding first device between the cellular network infrastructure and the ISP platform, thereby achieving the uninterrupted exchange of the data. In one exemplary embodiment, the IP address varies dynamically upon detection of the connection switching of the first device between the cellular network infrastructure and the ISP platform with the first unique identifier remaining constant, when the IP address corresponds to IPv4. Similarly, in another exemplary embodiment, the IP address remains constant upon detection of the connection switching of the first device between the cellular network infrastructure and the ISP platform, when the IP address corresponds to IPv6. Suppose upon registering the first device, the one or more users may be willing to register one or more second devices. Then, in one embodiment, the registration module may be configured to register the one or more second devices on the integrated platform upon receiving a plurality of second details from the corresponding one or more users. In one embodiment, the plurality of second details may include a second device name, a count of the one or more second devices to be registered, a type of the second device, one or more properties of the one or more second devices, or the like. In one exemplary embodiment, the plurality of second details may also be stored in the database. Upon registration, for the one or more second devices to be able to receive the one or more first services and the one or more second services, the one or more second devices may also be provided with a respective unique identifier. Thus, in one embodiment, the processing subsystem (20) may also include an extension providing module (as shown in FIG. 2) operatively coupled to the mapping module (50). The extension providing module may be configured to receive a second request of obtaining an authority for providing one or more second services to one or more second devices of the one or more users, from the first device upon assigning the first unique identifier to the first device. In one embodiment, the one or more second services may include at least one of to provide internet service to the one or more second devices, controlling an operation of the one or more second devices, enabling the one or more second devices to communicate with each other and with the first device, and the like. The extension providing module may also be configured to generate one or more IP addresses by associating one or more extension bits with the IP address mapped to the one or more first unique credentials associated with the first device by the mapping module (50) upon receiving the second request. The extension providing module may also be configured to map one or more second unique credentials associated with the one or more second devices with one or more extended IP addresses by updating a second register allocated to the corresponding one or more second devices with the one or more extended IP addresses on the integrated platform. In one embodiment, the one or more second unique credentials may include at least one of a mobile number, an Aadhar card number, a passport number, a social security number, an International Mobile Equipment Identity (IMEI) number, a serial number, a model number, a device identification number, and the like. Further, the extension providing module may also be configured to generate one or more second unique identifiers using a plurality of second details associated with the corresponding one or more second devices based on the mapping. The one or more second unique identifiers may correspond to indicative of the one or more second unique credentials being mapped with the corresponding one or more extended IP addresses. In one exemplary embodiment, a definition of the one or more second unique identifiers may be the same as that of the first unique identifier with the only difference being an indication that the corresponding one or more second unique credentials are mapped with certain IP. Moreover, in one embodiment, the one or more second unique identifiers may be similar to or resemble the one or more second unique credentials, an IP address, a name, or the like. In one embodiment, the extension providing module may be configured to assign the one or more second unique identifiers to the corresponding one or more second devices by updating the second register with the corresponding one or more second unique identifiers on the integrated platform. In one exemplary embodiment, the communication module (60) may also be configured to receive the first request from the one or more second devices upon assigning the or more second unique identifiers to the corresponding one or more second devices. The communication module (60) may also be configured to validate and verify an authenticity of the corresponding one or more second devices on the integrated platform by exchanging second device information of the corresponding one or more second devices between the cellular network infrastructure and the ISP platform upon receiving the corresponding first request. In one embodiment, the second device information may also be stored in the database. The second device information may correspond to at least one of the plurality of second details, the one or more second unique identifiers mapped with the one or more second unique credentials, a call history, a message history, a type of the one or more second devices, and the like. Further, the communication module (60) may also be configured to provide the one or more first services to the corresponding one or more second devices upon validating and verifying the authenticity. Furthermore, the communication module (60) may also be configured to update the second register dynamically with the one or more second unique identifiers upon detection of a connection switching of the corresponding one or more second devices between the cellular network infrastructure and the ISP platform, thereby achieving the uninterrupted exchange of the data Subsequently, in one embodiment, the processing subsystem (20) may also include a protection module (as shown in FIG. 2) operatively coupled to the communication module (60). The protection module may be configured to verify one or more permissions allocated to the first device and the one or more second devices requesting to receive the one or more first services and the one or more second services respectively upon validating and verifying the authenticity of the corresponding first device and the corresponding one or more second devices. The protection module may also be configured to prevent the corresponding first device or the corresponding one or more second devices from receiving the one or more first services and the one or more second services when the one or more permissions correspond to the corresponding first device or the corresponding one or more second devices belonging to a fraudulent category. Further, the protection module may also be configured to add the corresponding first device or the corresponding one or more second devices in a block-list upon preventing from receiving the one or more first services and the one or more second services. Additionally, in one exemplary embodiment, the linking module (40) may be configured to establish a link between the first device of the one or more users and a device naming platform upon receiving the plurality of first details associated with the corresponding first device, when the linkage type of the link corresponds to a user- level linkage type. In one embodiment, the device naming platform may be a third- party platform, a cellular network infrastructure, an ISP platform, the corresponding one or more users, or the like. As used herein, the term “user-level linkage-type” refers to a type of linkage which is established between one or more entities and needs an intervention of an end-user of the one or more entities. Further, in such embodiment, the mapping module (50) may be configured to generate a first unique identifier based on the plurality of first details of the first device and one or more device naming rules, upon linking the corresponding first device with the device naming platform. In one exemplary embodiment, the device naming platform may be adapted to search for an IP address mapped with the first unique identifier, wherein the IP address is mapped with the first unique public identifier during the generation of the corresponding first unique identifier. In one embodiment, the first unique identifier may include a unique device name. As used herein, the term “unique device name” refers to a name allocated to one or more devices registered on the integrated platform which is unique for each of the one or more devices, and each name could be traced back to a unique IP address. Also, in one embodiment, the unique device name may include a first unique device name, a second unique device name, and the like. In one exemplary embodiment, the first unique device name may be directly allocated to the first device. However, in one exemplary embodiment, the second unique device name may be allocated to the second device as an extension to the first unique device name. Moreover, in one embodiment, the first unique device name may be similar to a domain name assigned by a domain name system (DNS) to each of the one or more devices connected to a network. However, the first unique device name generated may be generated by the device naming platform based on the plurality of first details of the first device and the one or more device naming rules. The mapping module (50) may also be configured to map the one or more first unique credentials associated with the first device with the first unique identifier by updating a database associated with the device naming platform with the corresponding one or more first unique credentials, thereby assigning the first unique identifier to the first device. The first unique identifier corresponds to indicative of the one or more first unique credentials being mapped with the one or more first unique credentials. Moreover, in one embodiment, the communication module (60) may be configured to receive the first request from the first device upon assigning the first unique identifier to the corresponding first device. The first request includes a request for receiving the one or more first services from the corresponding device naming platform. The communication module (60) may also be configured to validate and verify the authenticity of the corresponding first device based on a pair of login credentials used by the first device for accessing the device naming platform, upon receiving the corresponding first request. As used herein, the term “login credentials” refers to credentials the enable users to log in and verify their identities to online accounts on the internet. In one embodiment, the pair of login credentials may include a username and password combination used for logging in to the device naming platform. Further, the communication module (60) may also be configured to provide the one or more first services to the corresponding first device upon validating and verifying the authenticity. Furthermore, the communication module (60) may also be configured to update the database dynamically with the first unique identifier upon detection of the connection switching of the corresponding first device between the cellular network infrastructure and the ISP platform, thereby achieving the uninterrupted exchange of the data. FIG.2 is a block diagram representation of an exemplary embodiment of the system (10) for achieving the uninterrupted exchange of the data between the one or more users of FIG. 1 in accordance with an embodiment of the present disclosure. The system (10) includes the processing subsystem (20) hosted on the server (30). Suppose a person ‘A’ (70) has registered on the integrated platform (80) via the registration module (90) using a first mobile phone (100) of the person ‘A’ (70). Here, the integrated platform (80) is generated upon linking the cellular network infrastructure (110) with the ISP platform (120) via the linking module (40), when a linkage-type of the link corresponds to the broader-level linkage type. The first mobile phone (100) of the person ‘A’ (70) also gets registered on the integrated platform (80) along with the person ‘A’ (70). Suppose the integrated platform (80) uses IPv6 for allocating IP addresses to one or more devices that use the internet via the integrated platform (80). However, the IPv6 possesses certain standard rules and protocols which are followed while allocating the IP addresses. But those standard rules and the protocols are updated by the mapping module (50) upon linking the cellular network infrastructure (110) with the ISP platform (120). Further, a mobile number of the person ‘A’ (70) is mapped with an IP address in IPv6 form by updating the first register allocated to the first mobile phone (100) on the integrated platform (80) with the corresponding IP address via the mapping module (50). Then, the first unique identifier is generated via the mapping module (50), which have a plurality of bits in the IPv6 form with initial few of the plurality of bits are filled with a country code, then a mobile number of the person ‘A’ (70), followed by a few standard bits. The first register may be associated with the database (130), wherein the database (130) stores a plurality of details associated with the first mobile phone (100) and the person ‘A’ (70). Now, suppose a person ‘B’ (140) is willing to contact the person ‘A’ (70) through the mobile number of the person ‘A’ (70). Suppose the person ‘B’ (140) is also registered on the integrated platform (80) using a second mobile phone (145). Then, when the person ‘B’ (140) tries to contact the person ‘A’ (70), the communication module (60) receives the first request from the person ‘B’ (140) to receive the service of having a conversation over a voice call with the person ‘A’ (70). the first request is validated and verified by the communication module (60) and then the corresponding service is provided to the person ‘B’ (140) by connecting the voice call with the person ‘A’ (70). Then, suppose during the voice call, the person ‘A’ (70) switches its connection from the cellular network infrastructure (110) to the ISP platform (120). Therefore, the first register gets updated with the first unique identifier allocated to the first mobile phone (100) of the person ‘A’ (70) by the communication module (60) so that even after switching to the ISP platform (120), the person ‘A’ (70) and the person ‘B’ (140) should be able to communicate with each other. Moreover, when the person ‘B’ (140) requests for the voice call with the person ‘A’ (70), the one or more permissions allocated to the person ‘B’ (140) in regard to contacting the person ‘A’ (70) are also checked by the protection module (150). Since the one or more permissions indicate that the person ‘B’ (140) is genuine and is allowed to contact the person ‘A’ (70), the call gets connected. Further, suppose during the registration of the first mobile phone (100), the person ‘A’ (70) was also willing to register one or more mobile devices (160) such as an IoT speaker, a heater controller, and a television remote controller of the person ‘A’ (70). Then, the person ‘A’ (70) registers them via the registration module (90). Also, the second request of receiving the authority to provide the one or more second services to the one or more mobile devices (160) is received by the extension providing module (170) from the person ‘A’ (70) upon registration. Now, the one or more extended IP addresses are generated, mapped to the one or more second unique credentials of the one or more mobile devices (160), the one or more second unique identifiers are generated, and the one or more second unique identifiers are allocated to the corresponding one or more mobile devices (160) by the extension providing module (170). Therefore, now the first mobile phone (100) can act as a server to the one or more mobile devices (160) and hence will be able to provide the one or more second services to the corresponding one or more mobile devices (160). FIG. 3 is a block diagram of a communication controlling computer or a communication controlling server (180) in accordance with an embodiment of the present disclosure. The communication controlling server (180) includes processor(s) (190), and memory (200) operatively coupled to a bus (210). The processor(s) (190), as used herein, means any type of computational circuit, such as, but not limited to, a microprocessor, a microcontroller, a complex instruction set computing microprocessor, a reduced instruction set computing microprocessor, a very long instruction word microprocessor, an explicitly parallel instruction computing microprocessor, a digital signal processor, or any other type of processing circuit, or a combination thereof. Computer memory elements may include any suitable memory device(s) for storing data and executable program, such as read only memory, random access memory, erasable programmable read only memory, electrically erasable programmable read only memory, hard drive, removable media drive for handling memory cards and the like. Embodiments of the present subject matter may be implemented in conjunction with program modules, including functions, procedures, data structures, and application programs, for performing tasks, or defining abstract data types or low-level hardware contexts. Executable program stored on any of the above-mentioned storage media may be executable by the processor(s) (190). The memory (200) includes a plurality of subsystems stored in the form of executable program which instructs the processor(s) (190) to perform method steps illustrated in FIG.4 (a) and FIG.4 (b). The memory (200) includes a processing subsystem (20) of FIG 1. The processing subsystem (20) further has following modules: a linking module (40), a mapping module (50), and a communication module (60). The linking module (40) is configured to create an integrated platform (80) upon establishing a link between cellular network infrastructure (110) and an internet service provider platform (120) based on one or more predefined conditions when a linkage-type of the link corresponds to a broader-level linkage-type. The mapping module (50) is configured to update one or more standard rules and one or more protocols associated with at least one of the cellular network infrastructure (110) and the internet service provider platform (120), upon creating the integrated platform (80). The mapping module (50) is also configured to map one or more first unique credentials associated with a first device of one or more users with an Internet Protocol address by updating a first register allocated to the corresponding first device on the integrated platform (80), with the Internet Protocol address, based on the one or more standard rules and the one or more protocols updated, upon registration of the first device. The mapping module (50) is also configured to generate a first unique identifier using a plurality of first details associated with the corresponding first device based on the mapping of the one or more first unique credentials with the Internet Protocol address, wherein the first unique identifier corresponds to indicative of the one or more first unique credentials being mapped with the Internet Protocol address. The mapping module (50) is also configured to assign the first unique identifier to the corresponding first device by updating the first register with the corresponding first unique identifier on the integrated platform (80). The communication module (60) is configured to receive a first request from the first device upon assigning the first unique identifier to the corresponding first device, wherein the first request comprises a request for receiving one or more first services from the corresponding integrated platform (80). The communication module (60) is also configured to validate and verify an authenticity of the corresponding first device on the integrated platform (80) by exchanging first device information of the corresponding first device between the cellular network infrastructure (110) and the internet service provider platform (120) upon receiving the corresponding first request. The communication module (60) is also configured to provide the one or more first services to the corresponding first device upon validating and verifying the authenticity. The communication module (60) is also configured to update the first register dynamically with the first unique identifier upon detection of a connection switching of the corresponding first device between the cellular network infrastructure (110) and the internet service provider platform (120), thereby achieving the uninterrupted exchange of the data. FIG.4 (a) and FIG.4 (b) are flow charts representing steps involved in a method (220) for achieving an uninterrupted exchange of data in accordance with an embodiment of the present disclosure. The method (220) includes an integrated platform upon establishing a link between cellular network infrastructure and an internet service provider platform based on one or more predefined conditions, when a linkage-type of the link corresponds to a broader-level linkage-type in step 230. In one embodiment, creating the integrated platform may include creating the integrated platform by a linking module (40). The method (220) also includes updating one or more standard rules and one or more protocols associated with at least one of the cellular network infrastructure and the internet service provider platform, upon creating the integrated platform in step 240. In one embodiment, updating the one or more standard rules and the one or more protocols may include updating the one or more standard rules and the one or more protocols by a mapping module (50). Furthermore, the method (220) includes mapping one or more first unique credentials associated with a first device of one or more users with an Internet Protocol address by updating a first register allocated to the corresponding first device on the integrated platform, with the Internet Protocol address, based on the one or more standard rules and the one or more protocols updated, upon registration of the first device in step 250. In one embodiment, mapping the one or more first unique credentials associated with the first device with the Internet Protocol address may include mapping the one or more first unique credentials associated with the first device with the Internet Protocol address by the mapping module (50). Furthermore, the method (220) also includes generating a first unique identifier using a plurality of first details associated with the corresponding first device based on the mapping of the one or more first unique credentials with the Internet Protocol address, wherein the first unique identifier corresponds to indicative of the one or more first unique credentials being mapped with the Internet Protocol address in step 260. In one embodiment, generating the first unique identifier may include generating the first unique identifier by the mapping module (50). Furthermore, the method (220) also includes assigning the first unique identifier to the corresponding first device by updating the first register with the corresponding first unique identifier on the integrated platform in step 270. In one embodiment, assigning the first unique identifier may include assigning the first unique identifier by the mapping module (50). Furthermore, the method (220) also includes receiving a first request from the first device upon assigning the first unique identifier to the corresponding first device, wherein the first request comprises a request for receiving one or more first services from the corresponding integrated platform in step 280. In one embodiment, receiving the first request may include receiving the first request by a communication module (60). Furthermore, the method (220) also includes validating and verifying an authenticity of the corresponding first device on the integrated platform by exchanging first device information of the corresponding first device between the cellular network infrastructure and the internet service provider platform upon receiving the corresponding first requestin step 290. In one embodiment, validating and verifying the authenticity of the corresponding first device may validating and verifying the authenticity of the corresponding first device by the communication module (60). Furthermore, the method (220) also includes providing the one or more first services to the corresponding first device upon validating and verifying the authenticity in step 300. In one embodiment, providing the one or more first services may include providing the one or more first services by the communication module (60). Furthermore, the method (220) also includes updating the first register dynamically with the first unique identifier upon detection of a connection switching of the corresponding first device between the cellular network infrastructure and the internet service provider platform, thereby achieving the uninterrupted exchange of the data in step 310. In one embodiment, updating the first register dynamically with the first unique identifier may include updating the first register dynamically with the first unique identifier by the communication module (60). Further, from a technical effect point of view, the implementation time required to perform the method steps included in the present disclosure by the one or more processors of the system is very minimal, thereby the system maintains very minimal operational latency and requires very minimal processing requirements. Various embodiments of the present disclosure enable achieving the uninterrupted exchange of the data as both the cellular network infrastructure and the ISP platform are linked on the integrated platform, and the first unique identifier allocated to a device of the one or more users remains constant. Also, the system is more reliable and more efficient because the one or more devices registered on the integrated platform remain always connected and reachable to the one or more users without any private third-party provider. Further, the system provides a more secured exchange of data because the first unique identifier allocated to the one or more devices of the one or more users remains constant and hence easy to track. While specific language has been used to describe the disclosure, any limitations arising on account of the same are not intended. As would be apparent to a person skilled in the art, various working modifications may be made to the method in order to implement the inventive concept as taught herein. The figures and the foregoing description give examples of embodiments. Those skilled in the art will appreciate that one or more of the described elements may well be combined into a single functional element. Alternatively, certain elements may be split into multiple functional elements. Elements from one embodiment may be added to another embodiment. For example, order of processes described herein may be changed and are not limited to the manner described herein. Moreover, the actions of any flow diagram need not be implemented in the order shown; nor do all of the acts need to be necessarily performed. Also, those acts that are not dependent on other acts may be performed in parallel with the other acts. The scope of embodiments is by no means limited by these specific examples.

Claims

I/WE CLAIM: 1. A system (10) for achieving an uninterrupted exchange of data, wherein the system (10) comprises: a processing subsystem (20) hosted on a server (30), and configured to execute on a network to control bidirectional communications among a plurality of modules comprising: a linking module (40) configured to create an integrated platform (80) upon establishing a link between cellular network infrastructure (110) and an internet service provider platform (120) based on one or more predefined conditions when a linkage-type of the link corresponds to a broader-level linkage-type; a mapping module (50) operatively coupled to the linking module (40), wherein the mapping module (50) is configured to: update one or more standard rules and one or more protocols associated with at least one of the cellular network infrastructure (110) and the internet service provider platform (120), upon creating the integrated platform (80); map one or more first unique credentials associated with a first device of one or more users with an Internet Protocol address by updating a first register allocated to the corresponding first device on the integrated platform (80), with the Internet Protocol address, based on the one or more standard rules and the one or more protocols updated, upon registration of the first device; generate a first unique identifier using a plurality of first details associated with the corresponding first device based on the mapping of the one or more first unique credentials with the Internet Protocol address, wherein the first unique identifier corresponds to indicative of the one or more first unique credentials being mapped with the Internet Protocol address; and assign the first unique identifier to the corresponding first device by updating the first register with the corresponding first unique identifier on the integrated platform (80); and a communication module (60) operatively coupled to the mapping module (50), wherein the communication module (60) is configured to: receive a first request from the first device upon assigning the first unique identifier to the corresponding first device, wherein the first request comprises a request for receiving one or more first services from the corresponding integrated platform (80); validate and verify an authenticity of the corresponding first device on the integrated platform (80) by exchanging first device information of the corresponding first device between the cellular network infrastructure (110) and the internet service provider platform (120) upon receiving the corresponding first request; provide the one or more first services to the corresponding first device upon validating and verifying the authenticity; and update the first register dynamically with the first unique identifier upon detection of a connection switching of the corresponding first device between the cellular network infrastructure (110) and the internet service provider platform (120), thereby achieving the uninterrupted exchange of the data.

2. The system (10) as claimed in claim 1, wherein the Internet Protocol address varies dynamically upon detection of the connection switching of the first device between the cellular network infrastructure (110) and the internet service provider platform (120) with the first unique identifier remaining constant when the Internet Protocol address corresponds to Internet Protocol version 4.

3. The system (10) as claimed in claim 1, wherein the Internet Protocol address remains constant upon detection of the switching of the connection of the first device between the cellular network infrastructure (110) and the internet service provider platform (120) when the Internet Protocol address corresponds to Internet Protocol version 6.

4. The system (10) as claimed in claim 1, wherein the linking module (40) is configured to establish a link between a first device of one or more users and a device naming platform upon receiving a plurality of first details associated with the corresponding first device when the linkage type of the link corresponds to a user-level linkage type.

5. The system (10) as claimed in claim 4, wherein the mapping module is configured to: generate a first unique identifier based on the plurality of first details of the first device and one or more device naming rules, upon linking the corresponding first device with the device naming platform, wherein the first unique identifier corresponds to indicative of the one or more first unique credentials being mapped with the one or more first unique credentials; map one or more first unique credentials associated with the first device with the first unique identifier by updating a database (130) associated with the device naming platform with the corresponding one or more first unique credentials, thereby assigning the first unique identifier to the first device.

6. The system (10) as claimed in claim 5, wherein the communication module (60) is configured to: receive a first request from the first device upon assigning the first unique identifier to the corresponding first device, wherein the first request comprises a request for receiving one or more first services from the corresponding device naming platform; validate and verify an authenticity of the corresponding first device based on a pair of login credentials used by the first device for accessing the device naming platform, upon receiving the corresponding first request; provide the one or more first services to the corresponding first device upon validating and verifying the authenticity; and update the database (130) dynamically with the first unique identifier upon detection of a connection switching of the corresponding first device between a cellular network infrastructure (110) and an internet service provider platform (120), thereby achieving the uninterrupted exchange of the data, wherein the device naming platform is adapted to search for an Internet Protocol address mapped with the first unique identifier, wherein the Internet Protocol address is mapped with the first unique public identifier during the generation of the corresponding first unique identifier.

7. The system (10) as claimed in claim 1, wherein the processing subsystem (20) comprises an extension providing module (170) operatively coupled to the mapping module (50), wherein the extension providing module (170) is configured to: receive a second request of obtaining an authority for providing one or more second services to one or more second devices of the one or more users, from the first device upon assigning the first unique identifier to the first device; generate one or more extended Internet Protocol addresses by associating one or more extension bits with the Internet Protocol address mapped to the one or more first unique credentials associated with the first device by the mapping module (50) upon receiving the second request; and map one or more second unique credentials associated with the one or more second devices with the one or more extended Internet Protocol addresses by updating a second register allocated to the corresponding one or more second devices with the one or more extended Internet Protocol addresses on the integrated platform (80); generate one or more second unique identifiers using a plurality of second details associated with the corresponding one or more second devices based on the mapping, wherein the one or more second unique identifiers correspond to indicative of the one or more second unique credentials being mapped with the corresponding one or more extended Internet Protocol addresses; and assign the one or more second unique identifiers to the corresponding one or more second devices by updating the second register with the corresponding one or more second unique identifiers on the integrated platform (80).

8. The system (10) as claimed in claim 7, wherein the communication module (60) is configured to: receive the first request from the one or more second devices upon assigning the or more second unique identifiers to the corresponding one or more second devices; validate and verify an authenticity of the corresponding one or more second devices on the integrated platform (80) by exchanging second device information of the corresponding one or more second devices between the cellular network infrastructure (110) and the internet service provider platform (120) upon receiving the corresponding first request; provide the one or more first services to the corresponding one or more second devices upon validating and verifying the authenticity; and update the second register dynamically with the one or more second unique identifiers upon detection of a connection switching of the corresponding one or more second devices between the cellular network infrastructure (110) and the internet service provider platform (120), thereby achieving the uninterrupted exchange of the data.

9. The system (10) as claimed in claim 8, wherein the processing subsystem (20) comprises a protection module (150) operatively coupled to the communication module (60), wherein the protection module (150) is configured to: verify one or more permissions allocated to the first device and the one or more second devices requesting to receive the one or more first services and the one or more second services respectively upon validating and verifying the authenticity of the corresponding first device and the corresponding one or more second devices; prevent the corresponding first device or the one or more second devices from receiving the one or more first services and the one or more second services when the one or more permissions correspond to the corresponding first device or the corresponding one or more second devices belonging to a fraudulent category; and add the corresponding first device or the corresponding one or more second devices in a block-list upon preventing from receiving the one or more first services and the one or more second services.

10. A method (220) for achieving an uninterrupted exchange of data, wherein the method (220) comprises: creating, by a linking module (40), an integrated platform upon establishing a link between cellular network infrastructure and an internet service provider platform based on one or more predefined conditions, when a linkage-type of the link corresponds to a broader-level linkage-type; (230) updating, by a mapping module (50), one or more standard rules and one or more protocols associated with at least one of the cellular network infrastructure and the internet service provider platform, upon creating the integrated platform; (240) mapping, by the mapping module (50), one or more first unique credentials associated with a first device of one or more users with an Internet Protocol address by updating a first register allocated to the corresponding first device on the integrated platform, with the Internet Protocol address, based on the one or more standard rules and the one or more protocols updated, upon registration of the first device; (250) generating, by the mapping module (50), a first unique identifier using a plurality of first details associated with the corresponding first device based on the mapping of the one or more first unique credentials with the Internet Protocol address, wherein the first unique identifier corresponds to indicative of the one or more first unique credentials being mapped with the Internet Protocol address; (260) assigning, by the mapping module (50), the first unique identifier to the corresponding first device by updating the first register with the corresponding first unique identifier on the integrated platform; (270) receiving, by a communication module (60), a first request from the first device upon assigning the first unique identifier to the corresponding first device, wherein the first request comprises a request for receiving one or more first services from the corresponding integrated platform; (280) validating and verifying, by the communication module (60), an authenticity of the corresponding first device on the integrated platform by exchanging first device information of the corresponding first device between the cellular network infrastructure and the internet service provider platform upon receiving the corresponding first request; (290) providing, by the communication module (60), the one or more first services to the corresponding first device upon validating and verifying the authenticity; and (300) updating, by the communication module (60), the first register dynamically with the first unique identifier upon detection of a connection switching of the corresponding first device between the cellular network infrastructure and the internet service provider platform, thereby achieving the uninterrupted exchange of the data (310).