Deck 5: Moores Law and More: Fast, Cheap Computing, Disruptive Innovation, and What This Means for the Manager

A) Insulators
B) Semiconductors
C) Resistors
D) Inductors
E) Rheostats

A) are driven by precise sets of software instructions.
B) have the capability to both enable and inhibit the flow of electricity.
C) have no moving parts.
D) are composed of germanium instead of silicon.
E) contain storage that retains data even when powered down.

A) they require less energy.
B) their value appreciates over time.
C) the presence of a high number of moving parts results in higher storage capacities.
D) they can retain data even if power is switched off, when used as hard disks.
E) they can be used to store large amounts of data at extremely low costs.

A) magnetic disk areal storage density doubles annually.
B) the cost per unit of useful light emitted by an LED falls by a factor of 10 every decade.
C) the value of a telecommunications network is proportional to the square of the number of connected users of the system.
D) chip performance per dollar doubles every eighteen months.
E) the cost of a semiconductor chip fabrication plant doubles every four years.

A) software
B) central processing unit
C) arithmetic and logic unit
D) random-access memory
E) microprocessor

A) Random-access memory
B) Cache memory
C) Optical storage memory
D) Holographic memory
E) Flash memory

A) the cost of a semiconductor chip fabrication plant doubles every four years.
B) the magnetic disk areal storage density doubles annually.
C) customers buy more products as they become cheaper.
D) the value of chips in semiconductor-based devices appreciates every six months.
E) firms stock up on tech products and sell them once their prices increase.

A) personal computers
B) mainframe computers
C) minicomputers
D) Internet computing
E) laptops

A) flash memory
B) read-only memory
C) holographic memory
D) volatile memory
E) racetrack memory

A) The amount of data that can be transmitted over an optical fiber line doubles every twelve months.
B) In eighteen months, chips as fast as today's models should be available for half the price.
C) The data storage capabilities of nonvolatile memory devices double every nine months.
D) Today's semiconductor fabrication plants will depreciate in value by more than 50 percent in four years.
E) If the magnetic disk areal storage density of a memory device increases by a factor of 2, the corresponding price decreases by a factor of 2.

A) Random-access memory
B) Flash memory
C) Optical disk drive
D) Nanodrive
E) Read-only memory

A) million
B) billion
C) trillion
D) quadrillion
E) sextillion

A) terabyte
B) gigabyte
C) megabyte
D) petabyte
E) zettabyte

A) Grids
B) Platforms
C) Lecterns
D) Fabs
E) Kilns

A) Multicore processors usually run older software by using only one core at a time.
B) Multicore processors draw more power than single-brain processors to solve the same problem.
C) Multicore processors require greater cooling to run the same software as single-brain processors.
D) Individual cores in multicore processors have smaller memories than single-brain chips and are consequently slower.
E) Multicore processors still have some fair distance to go before going mainstream.

A) Rising transportation costs greatly increase the costs of manufacturing and make moving inventory between locations highly expensive.
B) Chip manufacturers maintain low inventories to hedge the move of semiconductor technology away from silicon-based chips.
C) The potential physical and electronic damage to silicon chips if left unused for extended periods of time deters manufacturers from maintaining higher inventories.
D) Chip manufacturers leverage the higher costs of chip-based products to their advantage by keeping supply low compared to demand.
E) Products with a significant chip-based component rapidly fall in value and can cause huge losses when overproduced.

A) it did not offer an online music store model to rival Apple's iTunes effort.
B) its technology offerings were too futuristic and out of sync with the waves of computing to appeal to customers.
C) it failed to adapt to the changes in the electronics industry as predicted by Moore's Law.
D) its music players contradicted the price / performance phenomenon predicted by Moore's Law.
E) it attempted to straddle the twin markets of online music retail and electronic music players, and could not capitalize on either.

A) connecting identical processors in a parallel combination and drawing power from the same source.
B) putting two or more lower power processor cores on a single chip.
C) connecting a series of high powered processors through a single power source.
D) slicing a flat chip into pieces and reconnecting the pieces vertically.
E) connecting a combination of parallel and series-connected processors to a single larger processor to supplement its functioning.

A) third
B) first
C) fifth
D) fourth
E) second

A) Dovetailing
B) Helicity
C) Oblique correction
D) Jet quenching
E) Quantum tunneling

A) Weight, speed, and capacity
B) Density, temperature, and wafer thickness
C) Size, heat, and power
D) Silicon availability, efficiency, and energy
E) Memory, cache size, and speed

A) The distance between pathways inside silicon chips gets smaller with each successive generation.
B) Silicon is commonly available in the form of sand or silicon dioxide, which helps keep the costs of chip production low.
C) Constant interaction among three forces-size, heat, and power-makes Moore's Law practical.
D) The availability of better cooling technologies ensures chips can continue growing smaller and more power efficient.
E) With the exponential growth in information technology-enabled businesses, the demand for computers makes Moore's Law possible.

A) Nanocomputing
B) Quantum computing
C) Grid computing
D) Massively parallel processing
E) Cloud computing

A) Transistors
B) Multicore processors
C) Single-core processors
D) Conductors
E) Inductors

A) special software is installed on several computers enabling them to work together on a common problem.
B) computers are designed with many microprocessors that work together, simultaneously, to solve problems.
C) quantum properties, such as superposition and entanglement, are used to represent data and perform operations on these data.
D) microprocessors with two or more (typically lower power) calculating processor cores are fabricated on the same piece of silicon to solve multiple problems.
E) computer software seeks to reproduce or mimic human thought, decision making, or brain functions.

A) mainframes
B) quantum computers
C) supermini computers
D) minisuper computers
E) supercomputers

A) Financial risk modeling
B) Gene analysis
C) Linear problems
D) Parallel problems
E) Manufacturing simulation

A) The tech industry is the least fertile ground for disruptive technologies.
B) Over time their performance attributes improve to the point where they invade established markets.
C) They come to market with a set of performance attributes that existing customers need.
D) Disruptive technologies and disruptive innovations are independent concepts.
E) The term disruptive technologies is a simple one because few technologies are able to create market shocks and catalyze growth.

A) Pay attention to slow-expensive advancements in technology.
B) Remove shortsightedness regarding the future.
C) Become more consumer-focused.
D) Indulge in bottom-line obsession.
E) Increase conversation within same product groups.

A) multiple international agencies like the Fair Factories Clearinghouse.
B) morals and ethics that dictate firms to put principles above profits.
C) environmental advocates being appointed to influential positions on company boards.
D) the complexity of the modern value chain.
E) the increased longevity of electronic products.

A) dealing with e-waste at home can be ten times cheaper than sending it abroad.
B) disposal and recycling partners must be audited with the same vigor as suppliers and other partners.
C) environmentalists target only the big firms as they can afford to compensate for any environmental damage wrought by their practices.
D) it is simple enough for firms to monitor and track e-waste management through international agencies such as Fair Factories Clearinghouse.
E) appointing environmentalists like Al Gore to the firm's board of directors helps avoid legal action and brand tarnishing due to bad e-waste management practices.

A) Electronic waste increases with the rise of living standards worldwide.
B) The content of gold in a pound of electronic waste is lesser than that in a pound of mined ore.
C) The process of separating densely packed materials inside tech products to effectively harvest the value in e-waste is skill intensive.
D) Sending e-waste abroad can be much more expensive than dealing with it at home.
E) E-waste trade is mostly transparent, and stringent guidelines ensure that all e-waste is accounted for.

A) they primarily focus on the bottom line.
B) they fail to listen to customer needs.
C) they overestimate the impact of these innovations.
D) they don't indulge in playing catch-up.
E) they concentrate only on future financial performance.