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list for critical care is as follows:

      1 Pulse

      2 Temperature

      3 Blood Pressure

      4 Respiratory Rate

      5 Oxygen Saturation

      Pulse sensor was chosen as it measured the most important parameters from the human body and thus ideal to be used in a wearable. The system is now modularized to incorporate new sensors [5].

      Hardware Components:

      The main hardware components used are:

       Pulse Sensor—Pulse Sensor heart rate sensor for Arduino and Arduino compatible boards. It adds amplification and noise cancellation circuitry to the hardware. It’s noticeably faster and easier to get reliable pulse readings. Pulse Sensor works with either a 3 V or 5 V Arduino. A Color-Coded Cable, with a standard male header connector. As we know that the ear lobe and the thumb are the most sensitive areas in the human body, we attach the sensor using the ear clip to the ear lope or using the Velcro we attach it to the thumb of the user. There is a small camera placed in the sensor along with an infrared sensor. Infrared sensors work on the principle of reflected light waves. Infrared light reflected from objects. The reflected light is detected and then the BPM (Beats per Minute) is calculated [6].

Schematic illustration of hardware components.

      Figure 2.1 Hardware components.

Schematic illustration of pulse sensor connection.

       LinkIt One—It is a high performance-development board. It provides similar pin-out features to Arduino boards, making it easy to connect various sensors, peripherals, and Arduino shields. LinkIt One is an all-in-one prototyping board for IoT/wearable devices. The advantage of using this board is that it has inbuilt GSM, GPRS, Wi-Fi, GPS, Bluetooth features. It also has a Lithium ION battery which will ensure the board can be used without being connected to a socket always. This is a very important feature for us as this will not restrict the user’s movement. The users are free to move around with this board unlike other boards (Figure 2.3).

      Proposed System: The proposed automatic, IoT system is used to monitor the patient’s heart rate. It is also used to display the same in the form of an ECG (electrocardiogram). The system has the parts:

      1 Sensing Sub-System

      2 Data Transfer Sub-System

      3 Data Display Sub-System

      1. Sensing Sub-System

Photo depicts the pulse sensor kit.

      2. Data Transfer Sub-System

      3. Data Display Sub-System

      This sub-system consists of a cross platform app (Android and iOS) which is used to present the data to the doctor. The data is stored on the database which is retrieved onto the app and the data is plotted onto a dynamic plot and is represented as a graph in the doctor phone. If the patient’s parameters go below or beyond the medical parameters then an immediate message is transferred to the doctor, ambulance and patients relatives. We wanted this to be user friendly and hence we designed a cross platform app. Here to secure the data of a particular patient we use MQTT protocol. MQTT is a connectivity protocol. It is an extremely lightweight publish/subscribe messaging transport. It is useful for connections with remote locations where a small code footprint is required and/or network bandwidth is at a premium. Here, it has been used in sensors communicating to a server, request connections with healthcare providers. It is also ideal for mobile applications because of its small size, low power usage, minimized data packets, and efficient distribution of information to one or many receivers.

Schematic illustration of sign-up flowchart. Snapshot depicts the basic flow. Скачать книгу