Yes. This is what commonly occurs in systems with three or more stars. Two stars orbit close to one one another while the third one farther out orbits the other two.
The smaller objects which are built to represent the larger objects are called Model
The smaller objects which are built to represent the larger objects are called Model
Larger objects have greater mass, which means they have more inertia. Inertia is the tendency of an object to resist changes in its motion, so more force is needed to overcome this resistance and accelerate larger objects.
Larger objects have more gravity than smaller objects because they have more mass. Gravity is directly proportional to an object's mass - the more mass an object has, the stronger its gravitational pull. This is described by Newton's law of universal gravitation.
The size of an object does not impact gravity directly. Gravity is determined by the mass of an object and the distance between objects. The larger the mass of an object, the stronger its gravitational pull will be on other objects.
Smaller objects tend to have more density than larger objects because their mass is concentrated in a smaller volume, making their particles more tightly packed together. In contrast, larger objects have their mass distributed over a larger volume, leading to lower density.
An object's size does not directly affect its gravity. Gravity depends on an object's mass and distance from other objects. However, larger objects with more mass tend to have stronger gravitational pulls.
I assume that the smaller objects must not overlap, for otherwise, infiniely many of them will fit. It would be incorrect to calculate the area of the larger object and divide that by the area of the small objects. This is because these objects may not fir end to end. For example, you can get only one 2mm*2mm object into a 3mmx3mm object even though the larger area is 9 mm2, more than twice as big. This question is, I think, called the knapsack problem which does not have a simple solution. You can start looking at how many of the smaller objects will fit in, using the two possible orientations: Thus 457/43 = 10.63 and 330/49 = 6.73 so in that orientation, you can get 10*6 = 60 smaller objects. Alternatively, 457/49 = 9.33 and 330/43 = 7.67 so in this orientation you can get 9*7 = 63 smaller objects. So far 63 is the largest number. In fact, it will be possible to increase the number from 63 by changing the orientation of some of the smaller objects.
The amount of gravity an object has is determined by its mass. The larger the mass of an object, the greater its gravitational pull. This means that objects with more mass will exert a stronger gravitational force on other objects.
No, an object with a larger density than water will sink in water. Objects float when they have a lower density than the liquid they are placed in.
The flat object has more drag (air resistance) than the large object.
Objects in space are always Floating and/or orbiting a larger object because of the lack of gravity in space.