According to Moore`s observation, one of the main attractions of embedded electronics is its low cost. This advantage increases as technology advances. A single semiconductor substrate can produce more complex circuit functions. The cost per component in simple circuits is almost inversely proportional to the number of components. However, the cost per component tends to increase as more components are added, and lower efficiencies offset the increase in complexity. As a result, costs are minimal at any point in technological development. For example, manufacturing cost forecasts per component in 1970 were only one-tenth of what they were in 1965. The fact that Moore`s Law is approaching its natural death is perhaps most painfully present among chipmakers themselves; As these companies face the task of building ever more powerful chips against the reality of physical opportunities. Even Intel is competing with itself and its industry to create what might ultimately not be possible. The amount of computing power we can now fit into smaller devices is somewhat remarkable compared to what was achievable ten years ago. In 2016, the International Technology Roadmap for Semiconductors, after using Moore`s Law to move the industry forward since 1998, created its final roadmap. He no longer focused his research and development plan on Moore`s Law.
Instead, he described what might be called the More than Moore strategy, where application requirements drive chip development rather than focusing on scaling semiconductors. App drivers range from smartphones to AI to data centers.  Moore did not find an equation for his prediction, but it is easy to create one. One of the simplest is: “This simple rule has driven all the advances in the technological revolution for more than half a century and continues to define the growing frontiers of technology today, allowing us to make concepts like artificial intelligence and autonomous vehicles a reality.” This means that even though they might be physically smaller, they will theoretically reach what ITRS calls “their economic minimum,” meaning it only makes the cost prohibitive. Although Moore revised the forecasts in 1975 and doubled the time frame to two years, his prediction turned out to be correct and has since been used as the current definition of Moore`s Law. In 1965, the co-founder of chip giant Intel, Gordon Moore, made an observation based on this chip-sized compression after noticing that transistors had doubled every year since their invention. So he decided to build a theory on it. This theory is what we know today as Moore`s Law. Our editors will review what you have submitted and decide if the article needs to be revised. The number of transistors per chip cannot fully explain quality-adjusted microprocessor prices.    Moore`s 1995 paper does not limit Moore`s law to strict linearity or transistor counting: “The definition of `Moore`s Law` refers to almost everything related to the semiconductor industry that corresponds to a straight line on a semi-logarithmic diagram. I hesitate to check its origins and therefore to refine its definition.
 It has been more than 50 years since Moore published his work detailing simple theory, and since then it has revolutionized computing, enabling all the technology we consider fundamental to life today. In 1974, Robert H. Dennard of IBM recognized the rapid scaling technology of MOSFETs and formulated the so-called Dennard scaling, which describes their power density remaining constant as MOS transistors become smaller, so that power consumption remains proportional to the area.   The scaling and miniaturization of MOSFETs were the main driving forces behind Moore`s Law.  Semiconductor industry data show that this inverse relationship between power density and surface density broke in the mid-2000s.  A few days later, Bush replied, “We will enforce the law in Florida.” First of all, there are two rabbits on an island. The next day, there are four, then eight, then 16, 32, 64, 128, 256 and so on. Soon, the island is completely invaded by rabbits as they multiply exponentially. Similarly, according to Moore`s Law, the number of components in a computer chip increases exponentially: it doubles every two years. “Moore`s Law is a law of economics — not physics,” Intel`s Markus Weingartner told WIRED. “This tells us that each new chip will have twice as many transistors and therefore the computing capacity of the previous generation for the same production costs.