Deck 10: Digital System Projects Using HDL

A) is necessary at all system levels.
B) is unnecessary because most subsystems have already been built and tested.
C) would require too much time reproving known technology.
D) is necessary for important subsystems but can be avoided for small, easily developed subsystems.

A) synthesis and testing of each piece.
B) overall definition.
C) strategic planning.
D) system integration and testing.

A) What components are available for implementation?
B) What sources of power will be utilized?
C) What are the project design limits?
D) Will inferred technology work or will RF be needed?

A) small projects are already divided into small pieces so further division is unnecessary.
B) small project definition is obvious.
C) size of project.
D) large project management requires professional planning.

A) be considered the blueprint for development.
B) include every need.
C) develop as the project begins to take shape.
D) be specific and include all known obstacles.

A) the original problem statement must be redesigned.
B) each system must be tested and or addressed form comparability.
C) all subsystems must be individually tested again.
D) No changes are required: continue to develop project on an as built basis.

A) the drive should be tested under actual conditions.
B) simulated testing should be continued until failure results. Then document failure and decide if it is acceptable or unacceptable.
C) unusual or extraordinary conditions should be developed and tested on the drive.
D) the drive is ready for quality testing and prototyping.

A) multiple output or inputs processed by the same clock pulse.
B) development of a signal through repeated division of original signal.
C) any clock signal.
D) a process in which 60 Hz clock signals are produced.

A) activates Hi- Z mode or tri- state buffer.
B) activates high output on tri- state buffer.
C) activates low output on tri- state buffer.
D) allows tri- state buffer to go either high or low as needed.

A) The output frequency would be equal to a MOD 4 counter.
B) The output frequency would be equal to a MOD 16 counter.
C) The output frequency would equal the input frequency.
D) None of the above

A) buffer data bus from output/input devices.
B) generate Hz clock pulses.
C) condition input signals.
D) require RC networks.

A) Schmitt- Trigger, and then a MOD 60 counter
B) MOD 60 counter
C) MOD 6 counter, and then a Schmitt- Trigger
D) Schmitt- Trigger, and then a MOD 2 counter

A) The 1 for tens of hours and 2 for ones of hours is detected and resets hours back to zero.
B) The 2 is detected and resets the new tens and ones of hours to zero.
C) A MOD 6 counter automatically resets hours to zero.
D) The 1 for tens of hours and 2 for ones of hours is detected and resets hours back to 1 o'clock.

A) project synthesis.
B) top- down hierarchical design.
C) strategic planning.
D) problem statement.

A) using thumbwheel style BCD preloading.
B) using a second, high speed clock pulse and enabling it only during time set mode.
C) designing a clock set circuit to preload counter.
D) routing the seconds counter to the hours and minutes clock as needed.

A) the negative going portion of the waveform would reverse bias input circuitry and cause circuit failure.
B) the negative going waveform would introduce unwanted noise.
C) sine waves have no defined on/off values.
D) off would not be at ground potential. It would have a negative potential.
E) C or D

A) would still be dependent on line frequency.
B) is generated by an oscillator powered from the line frequency.
C) would be conditioned and independent from line frequency.
D) Both B and C

A) one system in a group of systems.
B) unknown systems inside the box and unknown outputs outside the box.
C) a system of unknowns with a known output.
D) a system of known values cloaked because the details are unimportant.

A) Low power consumption
B) Low parts count
C) Everyone is familiar with clocks
D) Inexpensive parts

A) synchronously, beginning with strategic planning.
B) synchronously, beginning with synthesis and testing.
C) synchronously, beginning with definition.
D) asynchronously after definition is complete.

A) specifications should be stated.
B) synthesis and testing begin.
C) planning should begin.
D) problem statement should be made.

A) break problem down to as few sections as possible.
B) break problem down to two sections.
C) break problem down to manageable sections.
D) re- examine problem statement and check that all issues have been covered.

A) retentive counters.
B) BCD counters.
C) decade counters.
D) Both A and B

A) a 555 timer and Schmitt- trigger.
B) a crystal oscillator.
C) a Schmitt- trigger and MOD 60 counter.
D) Either A or B

A) strategic planing is always conceived as a whole.
B) integration and testing must be performed on all system prior to project definition.
C) each basic clock should be carefully built from the most insignificant to the most sophisticated.
D) each block must be built prior to system planning.

A) begin integration.
B) begin project synthesis.
C) check to see if product still meets original definition.
D) combine blocks and sections and make final product.

A) sampling interval is too long.
B) sampling interval is too short.
C) the input frequency is too low.
D) All of the above

A) produce poor precision.
B) help prevent counter overflow.
C) yield high precision.
D) Both A and B

A) Accuracy of the counter depends on the accuracy of the system clock.
B) An accurate frequency counter is needed.
C) The display must be updated periodically.
D) The counter will have four major blocks.

A) needs to be compatible with signal conditioning circuits.
B) will not be measured.
C) must be higher than 12 volts.
D) All of the above

A) determining next states.
B) establishing ring counter sequence.
C) determining unused bit sequence.
D) All of the above

A) has equal torque at all speeds but higher speeds achievable.
B) has more torque than full step sequences.
C) operates stepper motors much more smoothly but consumes up to three times the current.
D) has less torque but operates more smoothly than full step at moderate steps.