Due to technological advancement, modern
electronic computers are exponentially more capable than those of preceding
generations (a phenomenon partially described by Moore's Law).
A key difference between physics and mathematics is that because physics is ultimately concerned with descriptions of the material world, it tests its theories by observations (called experiments), whereas mathematics is concerned with abstract logical patterns not limited by those observed in the real world (because the real world is limited in the number of dimensions and in many other ways it does not have to correspond to richer mathematical structures).
A key difference between physics and mathematics is that because physics is ultimately concerned with descriptions of the material world, it tests its theories by observations (called experiments), whereas mathematics is concerned with abstract logical patterns not limited by those observed in the real world (because the real world is limited in the number of dimensions and in many other ways it does not have to correspond to richer mathematical structures).
Due to technological
advancement, modern electronic computers are exponentially more capable than
those of preceding generations (a phenomenon partially described by Moore's
Law).
A key difference between physics and mathematics is that because physics is ultimately concerned with descriptions of the material world, it tests its theories by observations (called experiments), whereas mathematics is concerned with abstract logical patterns not limited by those observed in the real world (because the real world is limited in the number of dimensions and in many other ways it does not have to correspond to richer mathematical structures).
A key difference between physics and mathematics is that because physics is ultimately concerned with descriptions of the material world, it tests its theories by observations (called experiments), whereas mathematics is concerned with abstract logical patterns not limited by those observed in the real world (because the real world is limited in the number of dimensions and in many other ways it does not have to correspond to richer mathematical structures).
A key difference
between physics and mathematics is that because physics is ultimately concerned
with descriptions of the material world, it tests its theories by observations
(called experiments), whereas mathematics is concerned with abstract logical
patterns not limited by those observed in the real world (because the real
world is limited in the number of dimensions and in many other ways it does not
have to correspond to richer mathematical structures). Statics, a subfield of
mechanics, is responsible for the building of bridges. The distinction,
however, is not always clear-cut. The distinction, however, is not always
clear-cut.
Due to technological
advancement, modern electronic computers are exponentially more capable than
those of preceding generations (a phenomenon partially described by Moore's
Law).
A key difference between physics and mathematics is that because physics is ultimately concerned with descriptions of the material world, it tests its theories by observations (called experiments), whereas mathematics is concerned with abstract logical patterns not limited by those observed in the real world (because the real world is limited in the number of dimensions and in many other ways it does not have to correspond to richer mathematical structures).
A key difference between physics and mathematics is that because physics is ultimately concerned with descriptions of the material world, it tests its theories by observations (called experiments), whereas mathematics is concerned with abstract logical patterns not limited by those observed in the real world (because the real world is limited in the number of dimensions and in many other ways it does not have to correspond to richer mathematical structures).