When driving long distances, drivers who do not take frequent rests are more likely to get sleepy, a condition that experts say they often fail to identify early enough. Based on eye condition, this research proposes a system for detecting driver sleepiness in real time. A camera is often used to take a sequence of images by the system. In our system, these capture images may be saved as individual frames. The resulting frame is sent into facial recognition software as an input. The image's needed feature (eye) is then extracted. The method creates a condition for each eye and suggests a certain number of frames with the same condition that can be registered.

In this study, we will use Wi-Fi (100 metres) to link the mobile application to the tags. The team will produce the tags and make the smartphone application available worldwide. The tags will be placed on items that are likely to be misplaced. To locate the object, we must first locate the tag, which is located at a distance from the cell phone and emits Wi-Fi signals. The programme will begin monitoring the tag as soon as the user touches on the name of the thing he needs to find. The tag is linked to the mobile application. The tag may be tracked by the phone via Wi-Fi signals. As a result, this smartphone app will effectively assist those who have a hectic schedule and are prone to misplacing their items. This covers people of all ages, from teenagers to the elderly. Redetect will come in handy for folks who have a habit of forgetting where they keep their precious stuff. Basically, this software will protect you from losing objects by allowing you to register their position and, when necessary, redetect it, it will offer you the directions to get there. It uses the ESP8266 to determine the item's current location, which can be readily monitored even if the item's position changes from its starting position. That's for Redetect it — always on the lookout for your misplaced belongings.

The majority of the total populace today lives in urban communities. Because of absence of asset requirements, it appears as though there will be an issue in the future to offer every one of the types of assistance offices to the occupants. To keep on keeping up with, serve and work on the quality and way of life of the developing populace of country, important to foster specific computerized applications can be utilized in a shrewd city which will give us administrations as per our need. The various utilizations of Smart City try to make ideal and practical utilization of all assets, at its best with keeping a fitting harmony between our social, natural, and all sort of financial expenses. The principle order that characterizes utilizations of shrewd urban communities incorporates the nature of the climate, energy that is drunk, water and wastewater that is been depleted, and all sort of transportation and traffic, correspondence frameworks, personal satisfaction, information framework government, financial matters, HR, lodging and land use, country security.. There are many benefits in advancing shrewd urban areas as far as public advantages: making seriousness among various classes, advancing the business area, improvement of expectations for everyday comforts, legitimate use of re-sources. There are instances of savvy urban areas on the planet, and an IoT can be gained from their experience and accomplishments. Remembering for the need of IoT innovation in our group of people yet to come, in our undertaking we are creating two unique IoT based brilliant frameworks i.e., wellbeing checking framework and Home computerization framework that can be utilized in shrewd city model and further according to future necessity we can add all the more such applications to our task

This paper represents design of a simple, small, microstrip rectangular patch antenna for 5G application. Today, the requirement of antenna for such application should have higher bandwidth, low cost, low profile and smaller in size. The dimension of antenna are length and width of 2.59 mm and 3.65 mm respectively and height of this antenna is 0.4 mm. This antenna is designed by using thin and easily available substrate is used i.e., FR4 epoxy (εr= 4.4) to achieve compactness and high gain which will improve antenna performance. This antenna is wideband antenna means it covers a large bandwidth which includes 23.9 GHz frequency and our VSWR is improved from the base paper i.e., from 1.7483 to 1.0759. The simulation results of return loss, VSWR, gain and radiation pattern of the proposed antenna have been presented and discussed. Measured results are also presented and they are in good match with simulated results. The simulation results are obtained through HFSS 14 software.