Thursday , July 7 2022

Advanced digital networks look very similar to the human nervous system


Parents have tested how neonatal catches their finger and is still tight. This immediate response is one of the most sweetest indirect movements that babies display. Newborn nerves feel emotionally touch, process information and respond without having to send a signal to the brain. Although people enable this ability to be very early in life, the system that enables it is a useful example for digital networks that connect sensors, processors and machines to translate information in place.

My research on the human nervous system and advanced telecommunications networks has found some striking touches between the two, including the similarities between the baby's nervous systems and the rapid response networks are now being developed to handle sensor networks at all times, Always connected to connections, cameras and microphones across homes, communities and people's workplaces.

These insights can suggest new ways of thinking about the design of telecommunication systems in the future, as well as providing new ideas for diagnosing and treating neurological disorders such as multiple sclerosis, autistic spectrum disorder and Alzheimer's disease.

A view of human neurology

In general, the nervous system has three main elements: the brain, the spinal cord and the nervous system of the marginal.

The human nervous system can be understood as a network of interconnected sensors and processors.
Siyavula Education / Flickr, CC BYW

The peripheral nervous system is distributed through the whole body, sensing input such as pressure, heat and cold, and communicating that information through the spinal cord to & # 39; the brain. This system also deals with the responses from the brain, managing voluntary movements, and whether some local indirect body regulation such as breathing, digestion and retention is beaten.

The spinal cord treats large numbers of sensory inputs and action responses that go back and forth between the brain and the body. It also deals with involuntary muscle movements of the name of reflex arcs, such as the knee reaction when the doctor is performing an examination or quickly "pull-off" hand when touching something hot.

The brain, the middle of the majority of the power processing of the nervous system, has several specialized regions in its right and left hemisphere. These areas take input from sensors such as eyes, ears and skin, and return outputs in the form of thoughts, emotions, memories and movement. In many cases, these outputs are also used by other parts of the brain as inputs that allow refining and learning.

In healthy people, these elements work together in uncommon harmony by combining cell networks that respond to specific chemicals, mechanical changes, mild features, temperature changes and pain through a process known as sensory conveyancing. This complexity makes even one of the least components of the nervous system, the nerve fiber, or axon, a challenge to study.

Some of the nervous system connections, which are believed to be physically only, may also be able to be wire efficiently. The brain produces a very specialized electrical field in some nerve fiber sites during the normal course. Measuring the features of this area can offer signs that a brain is healthy, or that it may have some neurological disorders.

Inside telecommunications networks

The current generation of advanced telecommunications networks, known as 5G, is wireless, and has three similar categories of components.

The digital equivalent to the marginal nervous system is the "internet of things." There is an extensive and increasing network of household devices, vehicles and appliances that contain electronics, software and connectivity that allow them to connect, interact and exchange data.

The technological equivalent of the brain is the "cloud", an internet-connected group of computers and powerful processors that store, control and process data. They often work with each other to handle complex tasks that involve large amounts of input and processing, before delivering output back over the internet.

These two types of components include the spinal cord, a new type of network called "mist" – a drama because it has been a thin cloud to distribute it – have set up to reduce network connections and the delayed processing resulting from cloud and remote devices. The processors and storage devices in the fog can handle tasks that require special reactions quickly.

Amazing similarity

When building up modern-world technical networks, people are likely – and are likely to be unconscious – reflect human neutrology.

This offers opportunities to identify technological solutions to networking problems that could be adapted to medical treatments for neurological disorders that do not have any known cure.

Autism spectrum disorder, for example, is a serious developmental condition that disrupts people's ability to communicate and interact. It is believed that it happens due to an imbalance between two types of neutral communication: People with autism spectrum disorder have too much activity in neurons that excite other neurons and very little activity in neurons which can reduce calorie neurons others. This is what happens when some contacts in telecommunications networks are overloaded while others are not busy at all. Software tools that control cloud networks and large fog even the demand and reduce telecommunications delays. These programs can also simulate – and suggest ways of reducing – the imbalance of the network in autism-related faults.

Salvatore Domenic Morgera explains the nervous system network.

Multiple sclerosis is often an incapacitated disease where the body's immune system disappears in fiber and nerve protection covers. This impedes the flow of information within the brain, and between the brain and the body. Technically, this is similar to the costs of specific network networks, which are routinely treated by sending messages from other pathways with work connections. Medical research may identify ways to recreate nervous messages through adjoining connections when some nerves do not work properly.

Using software and medicine with each other

Nuclear communication breaks down when Alzheimer's disease affects them.
BruceBlaus / Wikimedia Commons, CC BYW

Alzheimer's disease is a type of dementia that causes problems with memory, mind and behavior. In 2015, I introduced work from my research laboratory on discovering new brain networks whose behavior indicates that Alzheimer's disease could be an automatic disease, such as MS. This suggests that a brain with Alzheimer's might be like a telecommunications network being attacked by an attacker that not only changes data within the network, but also the structure of the network itself.

Then, my research group used the human immune system as an inspiration for software development to protect computer networks against malicious attacks. This software can, in turn, be used to simulate Alzheimer's disease progress in a patient, highlighting ways to reduce its effects.

The involvement of the nervous system in other autoimmune diseases, such as Type 1 diabetes and rheumatoid arthritis, can have additional insights into digital networks, or sensors and software solutions may help patients. In my view, software models, made more realistic by clinical research, will help researchers understand the structure and function of the human nervous system and, along the way, make telecommunications networks and services faster and more reliable and secure .

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