Badminton, like many other sports, involves a large amount of nuance, where varied and tenacious game plans as well as fluid skills are crucial for the triumph of the match. Badminton is very physically demanding, depending not only on intense movements of various parts of the body, but also requiring active responses from the nervous system. Throughout a match, a player's nervous system must be at peak capacity, sending commands to their body to perform physical movements while processing environmental stimuli. With the help of neurons and the resulting chemical response, players push their limits to the maximum in a game that appeals to themselves and the audience. Say no to plagiarism. Get a tailor-made essay on “Why Violent Video Games Should Not Be Banned”? Get an original essay Every part of a badminton match begins and ends with the work of the peripheral nervous system. To give an example, consider a player who positions his body on the right side of the backcourt and the opponent hits briefly on the left side, near the net. When the player focuses on the shuttlecock, their eyes receive the electromagnetic waves, or lights, which reflect off the shuttlecock which bounces off the opponent's racket and clears the net. Electromagnetic waves enter the player's eyes through the pupil where the lens focuses these waves on the retina (Gade, 2018c). Then the process continues with the functions of rods and cones, specialized cells that absorb light. The rods respond to the movement of the shuttlecock, and at the same time, the cones fulfill their role of receiving details from the environment (Kalat, 2017). After that, the optic nerves carry signals from the rods and cones to the back of the brain, where the nerves will continue to process visual information, analyze the situation, and form responses. In the case of badminton, the response is to run across the court to hit the falling shuttlecock (Gade, 2018b, 2018c). This response is transmitted along the spinal cord as a sequence of signals, passing through countless nerves of the peripheral nervous system which are connected to a vast array of muscles in various parts of the player's body, where the signals are stimulated by the neurotransmitter acetylcholine and cause the necessary rapid movement (Kalat, 2017). A variety of sensory cues come into play before the player's reactions to their opponent's dropshots. The player's eyes pick up visual details about the position of the ball, the opponent, as well as their own position, sending neural signals to the occipital lobe at the back of the brain. The brain then decodes the tangled signals to form a coherent visual image, realigning the inverted visual information and filling in the retinal blind spots (Gade, 2018c). Additionally, its ears listen to the sound of the opponent's racket when it comes into contact with the shuttlecock, and specialized cells receive the resulting vibrations and carry the signals to the temporal lobe of the brain (Gade, 2018b). . Throughout a badminton player's body, nerves transmit signals about sensations of touch, such as grip on the racket, or temperature, such as the high heat of the court, to the parietal lobe (Gade, 2018b). Once each lobe transforms signals into accessible information, the frontal lobe begins to process this information, thereby forming responses to the incoming situation (Kalat, 2017). In the case of badminton, the left hemisphere of the player's brain is responsible for analyzing the situation, for understanding that the opponent has just hit the shuttlecock which is going..