The present invention generally relates to the field of medical electronic device and secure communication and storage technology. The invention, particularly relates to a lightweight cyber security enabled smart health monitoring system for monitoring, treatment, tracking and recording health anomalies and prediction and path analysis of individual based Medi-care system.

(1) BACKGROUND OF THE INVENTION
Social distancing and contact/exposure tracing are accepted to be critical strategies in the fight against the COVID-19 epidemic and with upcoming CORONA variation. They are both closely connected to the ability to reliably establish the degree of proximity between people in real-world environments. The spread of COVID-19 threatens global public health. Besides the effort to explore an efficient vaccine, measures, like lock-down, mask-wearing, and social distancing, are being taken to slow the spread and prevent severe consequences of the pandemic. Even in conventional medical inquires contact/exposure to crowded patient area/ward are liable to infected with different viral and other pathogenic disease.
With the advancement of the technology in digitalization of medical instruments, implementation of artificial intelligences, storage of medical data of patient in server (both in cloud and offline) facilitates medical stuff to cares patients and store their data smoothly. However various potential cyber threats and attacks i.e., replay of information, man-in-the-middle, impersonation, illegal session key computation, unauthorized data updating/ deletion/ disclosure, denial of service may destroy, use, alter the medical data of patient which results may be lethal.
A number of different type of the tools and methods for replacing/changing the lightweight cyber security enabled smart health monitoring system for providing a health care unit are available in the prior art. For example, the following patents are provided for their supportive teachings and are all incorporated by reference: US9801542B2 discloses a heart monitoring system for a person includes one or more wireless nodes; and wearable appliance in communication with the one or more wireless nodes, the appliance monitoring vital signs. The wearable device for use in a wireless body area network which comprises one or more additional devices, wherein said network is configured as a mesh network and said wearable device and said one or more additional devices are placed on one or more parts of a user's body and each of said wearable device and said one or more additional devices each comprise a sensor for monitoring a vital parameter related to the health of the user, and wherein at least one of said sensors is woven into a garment worn by the user and coupled to the network using optical fibers. However, this prior art document is unable to monitor the plurality of health parameters using a plurality of sensors.
Another prior art document, US8945009B2 discloses a remote health monitoring system, as applied to the field of public health surveillance. In particular, it relates to a multi-user remote health monitoring system that is capable of reliably identifying and collecting data from frontline healthcare providers, laboratory and hospital information systems, patients and healthy individuals in a number of ways, with a view to aid in the field of public health. The system can also be used to query and collect additional information regarding specifics pertaining to the health of the individuals, and for patient tracking, monitoring, and the collection of individual data.
Yet another prior art document, CN111125468A discloses a structural health monitoring system and a method based on a block chain technology and an intelligent contract, wherein the system comprises a data acquisition module, a data temporary storage and transmission module, a data analysis module and an intelligent monitoring module; the data acquisition module comprises a sensor and a digital camera which are arranged on the building structure, and the sensor and the digital camera are used for acquiring original data; the data temporary storage and transmission module comprises a local gateway which is respectively in wireless connection with the data acquisition module and the data analysis module; the data analysis module includes a blockchain network system and a health monitoring intelligence contract deployed in the blockchain network system. The structural health monitoring system is effectively prevented from being broken down under the condition of server failure or network failure.
Still another prior art document, CN112104692A discloses a health monitoring method of a medical Internet of things, which is implemented by two subsystems respectively, wherein the two subsystems comprise a community monitoring subsystem for implementing the health monitoring method of the community medical Internet of things and an intelligent medical subsystem depending on a block chain, and the community monitoring subsystem takes daily monitoring of chronic diseases and chronic disease service management of a community medical center as starting points. The community monitoring subsystem comprises a micro multi-parameter health monitoring terminal and a health collection and health monitoring service platform, collects relevant physiological parameter indexes of a user, sends the indexes to a mobile phone through Bluetooth, a health monitoring management system on the mobile phone performs preliminary analysis processing on received data, accesses the Internet in a Wi-Fi or cellular mobile communication mode, and uploads the data to the health monitoring service platform for further processing; an intelligent medical subsystem relying on a blockchain.
Yet another prior art document, US20150332283A1 discloses a Healthcare transaction validation systems and methods are presented. Healthcare transactions associated with a stakeholder are compiled into a chain of healthcare transaction blocks. The chain can be considered a chronicle of person's healthcare path through life. When a transaction is conducted, the corresponding healthcare parameters (e.g., inputs, outputs, clinical evidence, outcomes, etc.) are sent to one or more validation devices. The devices establish a validity of the transaction and generate a new block via a proof-of-work principle. Once the new block has been calculated it can be appended to the stakeholder's health care blockchain. However, this prior art document does not provide a sanitizing unit.
Another prior art document, US10297132B2 discloses a data collection system collects and stores physiological data from an ambulatory patient at a high resolution and/or a high data rate (“more detailed data”) and sends a low-resolution and/or down sampled version of the data (“less detailed data”) to a remote server via a wireless network. The server automatically analyzes the less detailed data to detect an anomaly, such as an arrhythmia. A two-tiered analysis scheme is used, where the first tier is more sensitive and less specific than the second tier. The server may also store the received data and make it available to a user, such as via a graphical or tabular display.
Still another prior art document, US10019552B2 discloses a method according to one aspect of the present invention includes receiving patient information, analyzing the patient information to identify a condition for the patient, formatting a report based on the patient information and the patient condition, and storing at least one of the patient information, the patient condition, and the formatted report as part of a medical record for the patient. The stored information can be processed and analyzed to perform a risk assessment for the patient, as well as compared to other data. Embodiments of the present invention may be used to monitor any appropriate medical device from essentially any location from which a communications signal can be sent and received. This enables patients to enjoy an active lifestyle by not being tied to medical device monitoring equipment that is difficult or impossible to transport or having to routinely visit health care facilities. The present invention can be used to monitor, process, and transport any amount and type of data from any medical device to any suitable user, such as a healthcare provider.
Yet another prior art document, CN108606784A discloses a remote health monitoring system based on Internet of Things, including user terminal, server and monitoring client, the output end of the user terminal and the receiving terminal of server are electrically connected, and the output end of the server and the receiving terminal of monitoring client are electrically connected; The user terminal includes embedded processor, the input terminal of the embedded processor is connect by data line with analog-digital converter, the input terminal of the analog-digital converter is connect by data line with monitoring sensor group, the storage port of the embedded processor is connect by data line with memory, this programmed is by way of remote real-time monitoring, the physical condition of old man can be monitored in real time, and by way of setting safety value, it can find the body problem of old man in time by way of contrast and make prompting, the deficiency for accompanying the time less at this stage can be made up
However, above mentioned references and many other similar references has one or more of the following shortcomings: (a) Data safety and security; (b) Complex installation; (c) Single anomalies monitoring and treatment system; (d) Unable to monitor the plurality of health parameters; (e) No or less tracking and prediction of disease and its effect; and (f) Real time and comprehensive medical surveillances.
The present application addresses the above-mentioned concerns and shortcomings (and other similar concerns/shortcomings) with regard to providing a lightweight cyber security enabled smart health monitoring system.
There remains a constant need in society for a continuous flow of new and innovative novelty of a lightweight cyber security enabled smart health monitoring system. It is in this context, that the subject invention is useful, not only to provide cost effective and easy to operate/use but to provide enhanced health monitoring system for providing a lightweight cyber security enabled smart health monitoring system.

(2) SUMMARY OF THE INVENTION:
In the view of the foregoing disadvantages inherent in the known types of technologies for providing a health monitoring system now present in the prior art, the present invention provides an improved device to enhance the safety, security and data acquisition of the patient and its maintenance efficiently. As such, the general purpose of the present invention, which will be described subsequently in greater detail, is to provide a new and improved lightweight cyber security enabled smart health monitoring system for providing a smart health monitoring system in a hospital, in a community center, in health sub-division office and/or in any preferred location by any medically learned person and/or authorized person to do which has all the advantages of the prior art and none of the disadvantages.
The main aspect of the present invention is to provide a lightweight cyber security enabled smart health monitoring system. The lightweight cyber security enabled smart health monitoring system for collecting, processing, analyzing and storing patient data in real time, comprised of a patient data acquisition unit for collecting patient data having a housing for placing an oxygen level monitoring unit, a pulse rate monitoring unit, a biometric sensor, an infrared based temperature sensor, a memory unit, a display unit; a processing unit, a communication unit and an electric power unit, any number of user unit authorized to deploy patient data acquisition unit in hospital, community center and/or preferred location to collect plurality set of patient data and any one of the user unit can be access to the plurality set of patient data and at least one health server configures to stores plurality set of patient data, instruction generated by the processing unit based on the plurality set of patient data and execution to collecting, processing, analyzing and storing plurality set of patient data and generate notification.
Another aspect of the present invention is to provide a method for providing lightweight cyber security enabled smart health monitoring system. The method can be initiated with Registering at least any one of a user unit and at least one patient data acquisition unit by a trusted registration authority and stored secrete credential and identities of user unit and patient data acquisition unit respectively in a health server. After successful registration when user unit want to access data from the health server and/or want to deploy patient data acquisition unit in preferred location undergoes Mutual Authenticating either between the patient data acquisition unit and the health server or between the health server and user unit or among patient data acquisition unit user unit and health server simultaneously after successful matching of secrete credential and identities entered by user unit to the stored secrete credential and identities in the health server. Session are initiated either between the patient data acquisition unit and the health server or between the health server and user unit or among patient data acquisition unit user unit and health server simultaneously. During the session user can access plurality set of patient data by the user unit previously stored by the patient data acquisition unit. The user unit also collects plurality set of patient data by using patient data acquisition unit. The plurality set of patient data comprises heartbeat, body temperature, oxygen level, glucose level in blood, hypertension and hypotension, or the like. The collected data of plurality set of patient data are stored in the health server. The processing unit analyzed and path predict to detect increase and/or decrease of value in each set of patient data and notifying at least one of user unit when at least one of the plurality set of patient data is above a predefined value. The predefined value for each of the plurality set of patient data is pre-stored. After successful collection of plurality set of patient data or successful access of plurality set of patient data the session is terminated and re-initiating mutual authentication, for next patient by any one of the user units.
Yet another aspect of the present invention is to provide the method of registration of at least any one of a user unit which involves selecting desired identities and password by any one of user unit and password are interpreted to crate pseudo password and the identity and pseudo password are provided to the trusted registration authority. The trusted registration authority registers each user unit and provides user credential after successful registration with generation of biometrics keys by biometric data (i.e., Fingerprints, retina scanning, face scanning, or the like). The trusted registration authority generates a pseudo biometric variable by putting the biometrics key inside user credential and generating a pseudo variable by putting the user credential inside the biometrics key. Storing pseudo biometric variable and pseudo variable in user unit and health server for future uses.
Still another aspect of the present invention is to provide method of registration of at least any one of patient data acquisition unit. The method introduced with generating secrete key for the trusted registration authority and for each patient data acquisition unit and also generating pseudo identities of the patient data acquisition unit. The secrete key and pseudo identities of the patient data acquisition unit are stored in health server and the patient data acquisition unit are deployed in any preferred location.
Yet another aspect of the present invention is method of mutual authentication between the patient data acquisition unit and the health server. The method of mutual authentication established with generating a random secret nonce and a fresh timestamp value by patient data acquisition unit and generating an authentication request message with the help of the random secret nonce, the timestamp value, the pseudo identities and the secret keys. The authentication request message is transmitted to the health server through the communication unit. The health server validates the fresh timestamp value and authentication request message. After successful validation the health server generates new random secret nonce and second fresh timestamp value and computing session key by making the use of new random secret nonce values, second fresh timestamp values the secret keys and the pseudo identities. The health server also generates an authentication response message and puts the session key inside in it and transmitting authentication response message to the patient data acquisition unit. The patient data acquisition unit receives authentication response message and verifies it and after successful verification both patient data acquisition unit and health server establishes session.
Still another aspect of the present invention is to provide the method of mutual authentication between the health server and user unit. The method begins with entering secret credential and/or swapping smart card and imprinting corresponding biometrics data by the user unit and generating an authentication request message with the help of secrete credential and biometric data. The user unit transmits the authentication request message to the health server. The health servers validate the secret credential and biometric data and authentication request message and subsequently generation of new random secret nonce and second fresh timestamp value by the health server and computing session key by making the use of new random secret nonce values, second fresh timestamp values, the secret credential and biometric data. The health server generates an authentication response message and puts the session key inside that and transmits to authentication response message to the user unit through communication unit. The user unit receives authentication response message and verifies it and Allows establishment of session after successful verification and mutual authentication.
Yet another aspect of the present invention is to provide the communication unit which is comprises at least one of Bluetooth, Wi-Fi, NFC, RF, Zigbee, wired connection, internet connectivity, or the like.
In this respect, before explaining at least one embodiment of the invention in detail, it is to be understood that the invention is not limited in its application to the details of construction and to the arrangements of the components set forth in the following description or illustrated in the drawings. The invention is capable of other embodiments and of being practiced and carried out in various ways. Also, it is to be understood that the phraseology and terminology employed herein are for the purpose of description and should not be regarded as limiting.
These together with other objects of the invention, along with the various features of novelty which characterize the invention, are pointed out with particularity in the disclosure. For a better understanding of the invention, its operating advantages and the specific objects attained by its uses, reference should be had to the accompanying drawings and descriptive matter in which there are illustrated preferred embodiments of the invention.
(3) BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be better understood and objects other than those set forth above will become apparent when consideration is given to the following detailed description thereof. Such description makes reference to the annexed drawings wherein:
Fig. 1 illustrates a block diagram of lightweight cyber security enabled smart health monitoring system.
Fig. 2 depicts a block diagram among patient data acquisition unit, user unit and the health server through communication unit according to an embodiment herein.
Fig. 3 depicts exemplary results set of plurality of patient data according to an embodiment herein.
Fig. 4 depicts a flow chart of the method for providing lightweight cyber security enabled smart health monitoring system, according to an embodiment herein.
Fig. 5 depicts a flow chart of the method for registration of at least any one of a user unit, according to an embodiment herein.
Fig. 6 depicts a flow chart of the method for registration of at least any one of patient data acquisition unit according to an embodiment herein.
Fig. 7 depicts a flow chart of the method of mutual authentication between the patient data acquisition unit and the health serve according to an embodiment herein.
Fig. 8 depicts a flow chart of the method for mutual authentication between the health server and user unit according to an embodiment herein.

(4) DETAILED DESCRIPTION OF THE INVENTION
In the following detailed description, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention, and it is to be understood that the embodiments may be combined, or that other embodiments may be utilized and that structural and logical changes may be made without departing from the spirit and scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined by the appended claims and their equivalents.
References will now be made in detail to the exemplary embodiment of the present disclosure. Before describing the detailed embodiments that are in accordance with the present disclosure, it should be observed that the embodiments reside primarily in combinations arrangement of the system according to an embodiment herein and as exemplified in FIG. 1 – FIG. 8.
In the following description, for the purpose of explanation, numerous specific details are set forth in order to provide a thorough understanding of the arrangement of the system according to an embodiment herein. It will be apparent, however, to one skilled in the art, that the present embodiment can be practiced without these specific details. In other instances, structures are shown in block diagram form only in order to avoid obscuring the present invention.
The main embodiment of the present invention is to provide a lightweight cyber security enabled smart health monitoring system. Fig. 1 shows the block diagram of lightweight cyber security enabled smart health monitoring system. The lightweight cyber security enabled smart health monitoring system for collecting, processing, analyzing and storing patient data in real time, comprised of a patient data acquisition unit 101 for collecting patient data having a housing for placing an oxygen level monitoring unit 105, a pulse rate monitoring unit 110, a biometric sensor 106, an infrared based temperature sensor 107, a memory unit 111, a display unit 113; a processing unit 108, a communication unit 112 and an electric power unit 109, any number of user unit 104 authorized to deploy patient data acquisition unit 101 in hospital, community center and/or preferred location to collect plurality set of patient data and any one of the user unit can be access to the plurality set of patient data and at least one health server 103 configures to stores plurality set of patient data, instruction generated by the processing unit 108 based on the plurality set of patient data and execution to collecting, processing, analyzing and storing plurality set of patient data and generate notification.
The housing in the present invention is of carbon polymer with water and fire resistive and long-lasting material. The housing may be of any desired shape and size. The display unit 113 are placed in top surface of the housing. The display unit 113 can be LCD, LED screen or the like where value of plurality set of patient data are displayed. The display unit 113 powered with electric power unit 109. The electric power unit 109 are inbuilt rechargeable single and/or multiple battery set. The battery set can be optionally replaced with external electric source. The electric power unit 109 supplies power to oxygen level monitoring unit 105, a pulse rate monitoring unit 110, a biometric sensor 106, an infrared based temperature sensor 107, and a processing unit 108. The oxygen level monitoring unit 105 monitors the oxygen level in the blood of the patient. The pulse rate monitoring unit 110 monitors the pulse of the patient. The biometric sensor 106 collects the biometric data such as Fingerprints, retina scanning, face scanning, or the like. The infrared based temperature sensor 107 measures the temperature of the patient. The communication unit 112 in the present invention may comprises at least one of Bluetooth, Wi-Fi, NFC, RF, Zigbee, wired connection, internet connectivity, or the like. The communication unit 112 are secure, fast and efficient in exchange of plurality set of patient data among patient data acquisition unit 101, user unit 104 and health server 103.
The user unit 104 are the legitimate users which are doctors 114, nursing staff 116, relatives of patients/patient authorized person 115, patient 102, any stack holder 117 and any other interested and authorized by the patient. The doctors and nursing staff can remotely monitor the patients through the patient data acquisition unit 101. The doctors 114 provide consultation based on the data collected by the patient data acquisition unit 101. The relatives of patients, patient, any stack holder and any other interested and authorized by the patient 102 can be access the plurality set of patient data from the health server 103 through the graphical interface of the computer implemented medium in the mobile objects. The mobile objects can be mobile, cell phone, desktop, laptop and device with display and network connection capability.
Fig. 2 shows a block diagram among patient data acquisition unit, user unit and the health server through communication unit according to an embodiment herein. The patient data acquisition unit, user unit and the health server exchange data through the communication unit in insecure medium and/or vulnerable channel to multiple threads. However the communication unit protects the healthcare data against the various potential cyber threats and attacks such as replay of information, man-in-the-middle, impersonation, illegal session key computation, unauthorized data updating/ deletion/ disclosure, denial of service, etc.
Fig. 3 shows exemplary results set of plurality of patient data according to an embodiment herein. Here the oxygen level in blood of the and the pulse rate of the patient are displayed in the table format which can be displayed in the graphical user interface of the computer readable medium.
Another embodiment of the present invention provides a method for providing lightweight cyber security enabled smart health monitoring system 100. Fig. 4 shows a flow chart of the method for providing lightweight cyber security enabled smart health monitoring system, according to an embodiment herein. The method can be initiated with Registering at least any one of a user unit 104 and at least one patient data acquisition unit 101 by a trusted registration authority and stored secrete credential and identities of user unit 104 and patient data acquisition unit 101 respectively in a health server 103. After successful registration when user unit want to access data from the health server 103 and/or want to deploy patient data acquisition unit 101 in preferred location undergoes Mutual Authenticating either between the patient data acquisition unit 101 and the health server 103 or between the health server and user unit or among patient data acquisition unit 101 user unit and health server simultaneously after successful matching of secrete credential and identities entered by user unit 104 to the stored secrete credential and identities in the health server. Session are initiated either between the patient data acquisition unit 101 and the health server or between the health server and user unit or among patient data acquisition unit 101 user unit and health server simultaneously. During the session user can access plurality set of patient data by the user unit previously stored by the patient data acquisition unit 101. The user unit 104 also collects plurality set of patient data by using patient data acquisition unit 101. The plurality set of patient data comprises heartbeat, body temperature, oxygen level, glucose level in blood, hypertension and hypotension, or the like. The collected data of plurality set of patient data are stored in the health server. The processing unit 108 analyzed and path predict to detect increase and/or decrease of value in each set of patient data and notifying at least one of user unit when at least one of the pluralities set of patient data is above a predefined value. The predefined value for each of the plurality set of patient data is pre-stored. After successful collection of plurality set of patient data or successful access of plurality set of patient data the session is terminated and re-initiating mutual authentication, for next patient by any one of the user units.
Fig. 5 shows a flow chart of the method for registration of at least any one of a user unit, according to an embodiment herein. The method of registration of at least any one of a user unit in the present invention involves selecting desired identities and password by any one of user unit 104 and password are interpreted to crate pseudo password and the identity and pseudo password are provided to the trusted registration authority. The trusted registration authority registers each user unit and provides user credential after successful registration with generation of biometrics keys by biometric data (i.e., Fingerprints, retina scanning, face scanning, or the like). The trusted registration authority generates a pseudo biometric variable by putting the biometrics key inside user credential and generating a pseudo variable by putting the user credential inside the biometrics key. Storing pseudo biometric variable and pseudo variable in user unit and health server 103 for future uses.
Fig. 6 shows a flow chart of the method for registration of at least any one of patient data acquisition unit according to an embodiment herein. The method of registration of at least any one of patient data acquisition unit 101 introduced with generating secrete key for the trusted registration authority and for each patient data acquisition unit 101 and also generating pseudo identities of the patient data acquisition unit 101. The secrete key and pseudo identities of the patient data acquisition unit 101 are stored in health server 103 and the patient data acquisition unit 101 are deployed in any preferred location.
Fig. 7 shows a flow chart of the method of mutual authentication between the patient data acquisition unit and the health serve according to an embodiment herein. The method of mutual authentication between the patient data acquisition unit 101 and the health server 103 established with generating a random secret nonce and a fresh timestamp value by patient data acquisition unit 101 and generating an authentication request message with the help of the random secret nonce, the timestamp value, the pseudo identities and the secret keys. The authentication request message is transmitted to the health server 103 through the communication unit 112. The health server 103 validates the fresh timestamp value and authentication request message. After successful validation the health server 103 generates new random secret nonce and second fresh timestamp value and computing session key by making the use of new random secret nonce values, second fresh timestamp values the secret keys and the pseudo identities. The health server also generates an authentication response message and puts the session key inside in it and transmitting authentication response message to the patient data acquisition unit 101. The patient data acquisition unit 101 receives authentication response message and verifies it and after successful verification both patient data acquisition unit 101 and health server establishes session.
Fig. 8 depicts a flow chart of the method for mutual authentication between the health server and user unit according to an embodiment herein. The method of mutual authentication between the health server and user unit 104 begins with entering secret credential and/or swapping smart card and imprinting corresponding biometrics data by the user unit and generating an authentication request message with the help of secrete credential and biometric data. The user unit transmits the authentication request message to the health server. The health servers validate the secret credential and biometric data and authentication request message and subsequently generation of new random secret nonce and second fresh timestamp value by the health server 103 and computing session key by making the use of new random secret nonce values, second fresh timestamp values, the secret credential and biometric data. The health server generates an authentication response message and puts the session key inside that and transmits to authentication response message to the user unit 104 through communication unit 112. The user unit receives authentication response message and verifies it and Allows establishment of session after successful verification and mutual authentication.
It is to be understood that the above description is intended to be illustrative, and not restrictive. For example, the above-discussed embodiments may be used in combination with each other. Many other embodiments will be apparent to those of skill in the art upon reviewing the above description.
The benefits and advantages which may be provided by the present invention have been described above with regard to specific embodiments. These benefits and advantages, and any elements or limitations that may cause them to occur or to become more pronounced are not to be construed as critical, required, or essential features of any or all of the embodiments.
While the present invention has been described with reference to particular embodiments, it should be understood that the embodiments are illustrative and that the scope of the invention is not limited to these embodiments. Many variations, modifications, additions and improvements to the embodiments described above are possible. It is contemplated that these variations, modifications, additions and improvements fall within the scope of the invention.

We / I Claimed:

1. A lightweight cyber security enabled smart health monitoring system 100 for collecting, processing, analyzing and storing patient data in real time, said lightweight cyber security enabled smart health monitoring system 100 comprising:
a patient data acquisition unit 101 for collecting patient data having a housing for placing an oxygen level monitoring unit 105, a pulse rate monitoring unit 110, a biometric sensor 106, an infrared based temperature sensor 107, a memory unit 111, a display unit 113; a processing unit 108, a communication unit 112 and an electric power unit 109;
Any one of a user unit authorized to deploy patient data acquisition unit 101 in hospital, community center and/or preferred location to collect plurality set of patient data and any one of said user unit can be access to said plurality set of patient data; and
At least one health server 103 configures to stores plurality set of patient data, instruction generated by said processing unit 108 based on the plurality set of patient data and execution to collecting, processing, analyzing and storing plurality set of patient data and generate notification.

2. A method for providing lightweight cyber security enabled smart health monitoring system 100 comprising:
Registration, of at least any one of a user unit 104 and at least one patient data acquisition unit 101 by a trusted registration authority and stored secrete credential and identities of user unit and patient data acquisition unit 101 respectively in a health server 103;
Mutual Authenticating either between said patient data acquisition unit 1015 and said health server 103 or between said health server and user unit or among patient data acquisition unit 101 user unit and health server simultaneously after successful matching of secrete credential and identities entered by user unit to the stored secrete credential and identities in said health server;
Initiating session, either between said patient data acquisition unit 101 and said health server 103 or between said health server and user unit 104 or among patient data acquisition unit 101 user unit and health server simultaneously;
Accessing, plurality set of patient data by said user unit previously stored by said patient data acquisition unit 101;
Collecting, plurality set of patient data by said patient data acquisition unit 101 wherein said plurality set of patient data comprises heartbeat, body temperature, oxygen level, glucose level in blood, hypertension and hypotension, or the like;
Storing, said plurality set of patient data in said health server during session;
Analyzing and path prediction of increase and decrease of value in each set of patient data;
Notifying at least one of user unit 104 when at least one of said plurality set of patient data is above a predefined value, wherein said predefined value for each of said plurality set of patient data is pre-stored;
Terminating session after either successful collection of plurality set of patient data or successful access of plurality set of patient data; and
Re-initiating mutual authentication, for next patient 102 by any one of said user unit 104.
3. The method for providing lightweight cyber security enabled smart health monitoring system 100 as claimed in clamed 2, whereon said registration, of at least any one of a user unit 104 comprising:
Selecting desired identities and password by any one of user unit and password are interpreted to crate pseudo password;
Providing identity and pseudo password to said trusted registration authority;
Registration of each user unit by said trusted registration authority and providing user credential after successful registration;
Generation of biometrics keys by biometric data (i.e., Fingerprints, retina scanning, face scanning, or the like);
Generating a pseudo biometric variable by putting the biometrics key inside user credential;
Generating a pseudo variable by putting the user credential inside said biometrics key;
Storing; and
Storing pseudo biometric variable and pseudo variable in user unit and health server 103 for future uses.

4. The method for providing lightweight cyber security enabled smart health monitoring system 100 as claimed in clamed 2, whereon said registration, of at least any one of patient data acquisition unit comprising
Generating secrete key by said trusted registration authority for itself each patient data acquisition unit 101;
Generating pseudo identities of the patient data acquisition unit;
Storing secrete key and pseudo identities of the patient data acquisition unit 101 in health server; and
Deploying patient data acquisition unit 101 in any preferred location.

5. The method for providing lightweight cyber security enabled smart health monitoring system 100 as claimed in clamed 2 and 4, wherein said method of mutual authentication between said patient data acquisition unit 101 and said health server further comprising;
Generating a random secret nonce and a fresh timestamp value by patient data acquisition unit 101;
Generating an authentication request message with the help of said random secret nonce, said timestamp value, said pseudo identities and said secret keys;
Transmitting said authentication request message to said health server through said communication unit 112;
Validation of fresh timestamp value at health server and authentication request message;
Generation of new random secret nonce and second fresh timestamp value by said health server and computing session key by making the use of new random secret nonce values, second fresh timestamp values, said secret keys and said pseudo identities;
Generation of an authentication response message and puts said session key inside that;
Transmitting authentication response message to said patient data acquisition unit;
Receiving of authentication response message and verification by said patient data acquisition unit 101; and
Allowing establishment of session after successful verification and mutual authentication.

6. The method for providing lightweight cyber security enabled smart health monitoring system 100 as claimed in clamed 2 and 3, wherein said method of mutual authentication between said health server 103 and user unit further comprising;
Entering secret credential and/or swapping smart card and imprinting corresponding biometrics data;
Generating an authentication request message with the help of secrete credential and biometric data;
Transmitting said authentication request message to said health server;
Validation of secret credential and biometric data at health server and authentication request message;
Generation of new random secret nonce and second fresh timestamp value by said health server and computing session key by making the use of new random secret nonce values, second fresh timestamp values, said secret credential and biometric data;
Generation of an authentication response message and puts said session key inside that;
Transmitting authentication response message to said user unit 104 through communication unit 112;
Receiving of authentication response message and verification by said user unit;
Allowing establishment of session after successful verification and mutual authentication.
7. The lightweight cyber security enabled smart health monitoring system 100 as claimed in claim 1, wherein said communication unit 112 comprises at least one of Bluetooth, Wi-Fi, NFC, RF, Zigbee, wired connection, internet connectivity, or the like.