twenty
On a digital clock, the number 8 is formed using all seven segments of a seven-segment display. Each segment lights up to create the complete shape of the number. Therefore, the number 8 consists of 7 segments.
A line segment is divided into congruent segments by a point that lies at its midpoint. This midpoint is equidistant from both endpoints of the segment, ensuring that the two resulting segments are of equal length. Alternatively, if a line segment is divided into a specific number of equal parts, each division point will also create congruent segments.
In a 7 segment display, the symbols can be created using a selected number of segments where each segment is treated as a different element.When 1 segment is used, the possible positions are 7because it can be any of the 7 segments (7C1=7).When 2 segments are used, the number of possible combinations are 7C2=21.When 3 segments are used, the number of possible combinations are 7C3=35When 4 segments are used, the number of possible combinations are 7C4=35When 5 segments are used, the number of possible combinations are 7C5=21When 6 segments are used, the number of possible combinations are 7C6=7When 7 segments are used, the number of possible combinations are 7C7=1Adding the combinations, 7+21+35+21+7+1=127Therefore, 127 symbols can be made using a 7 segment display!
A line segment defined by ( n ) points is divided into ( n + 1 ) segments. Each point creates a division between two segments, so with ( n ) points, there are ( n ) divisions. Therefore, the total number of segments formed is equal to the number of divisions plus one, resulting in ( n + 1 ) segments.
Any line segment, no matter how short it is, has an infinite number of points.
You can divide a segment into an infinite number of smaller segments.
On a digital clock, the number 8 is formed using all seven segments of a seven-segment display. Each segment lights up to create the complete shape of the number. Therefore, the number 8 consists of 7 segments.
A line segment is divided into congruent segments by a point that lies at its midpoint. This midpoint is equidistant from both endpoints of the segment, ensuring that the two resulting segments are of equal length. Alternatively, if a line segment is divided into a specific number of equal parts, each division point will also create congruent segments.
The answer depends on whether the n points are on a line and you are interested in linear segments or whether they are on the circumference of a circle and you are interested in the number of segments that the circle is partitioned into. Or, of course, any other shape.
In a 7 segment display, the symbols can be created using a selected number of segments where each segment is treated as a different element.When 1 segment is used, the possible positions are 7because it can be any of the 7 segments (7C1=7).When 2 segments are used, the number of possible combinations are 7C2=21.When 3 segments are used, the number of possible combinations are 7C3=35When 4 segments are used, the number of possible combinations are 7C4=35When 5 segments are used, the number of possible combinations are 7C5=21When 6 segments are used, the number of possible combinations are 7C6=7When 7 segments are used, the number of possible combinations are 7C7=1Adding the combinations, 7+21+35+21+7+1=127Therefore, 127 symbols can be made using a 7 segment display!
A line segment defined by ( n ) points is divided into ( n + 1 ) segments. Each point creates a division between two segments, so with ( n ) points, there are ( n ) divisions. Therefore, the total number of segments formed is equal to the number of divisions plus one, resulting in ( n + 1 ) segments.
the rest of the question : N= Total number of individuals divided by Number of segments Total number of segments is 31
Any line segment, no matter how short it is, has an infinite number of points.
A seven segment[E1]consist of seven light -emitting diode segments and one segment for the decimal point.The LEDs are physically arranged.To display a number, the necesssary segments are lit by sending an appropriate signals for current flow to the diodes
Except for the first and last segments, which have no setae, there are eight tiny bristle-like structures that can not be seen with the naked eye called setae on each segment of an earthworm. The arrangement of the setae is one factor that helps in the identification of earthworms, as they can be closely or widely paired in four pairs or separate. Setae grip the soil to help the earthworm move about and sense the enviroment.
That depends on the millipede. Each segment has a pair of legs. As they get older, they have more segments. The number of legs usually ranges from 80 to 400, although there are a few that have as many as 750
A millipede has two legs per body segment. Therefore, to find the number of segments in a millipede with 752 legs, you would divide the total number of legs by two. Thus, a millipede with 752 legs would have 376 segments.