Shape Construction Worksheet 25 - Advanced Level (geometric logic) | 20 Questions

Question 1

How many visible faces can be seen from the front view of this 3D arrangement (assuming each small cube has 6 faces, and cubes are placed on a ground plane, looking from a corner angle)? Cube arrangement (top view, 1=cube present): ⬜ ⬜ ⬜

Each cube has 6 faces, but faces are hidden where cubes touch or touch the ground.
- Count visible faces: Top faces (1 per visible cube) + Front faces + Side faces.
- For this configuration, the total is 17 visible faces.

counting, faces, 3d, cubes

Question 2

If you assemble these 2D shapes in 3D space by joining matching edges, which 3D shape do you get? Parts: 6 × ⬜

The cube can be constructed from:
square, square, square, square, square, square arranged appropriately.
This is a standard net/assembly pattern for a cube.

assembly, 2d-to-3d, construction

Question 3

Which of the following nets can be folded into a cube (without overlapping)?

A valid cube net must have exactly 6 squares connected edge-to-edge, with each square adjacent to at most 4 others, and when folded, all squares meet at edges without overlap.
This net is one of the 11 known cube nets.

cube, net, folding, 3d

Question 4

How many visible faces can be seen from the front view of this 3D arrangement (assuming each small cube has 6 faces, and cubes are placed on a ground plane, looking from a corner angle)? Cube arrangement (top view, 1=cube present): ⬜ ⬜ ⬜ ⬛

Each cube has 6 faces, but faces are hidden where cubes touch or touch the ground.
- Count visible faces: Top faces (1 per visible cube) + Front faces + Side faces.
- For this configuration, the total is 18 visible faces.

counting, faces, 3d, cubes

Question 5

Which of the following nets can be folded into a cube (without overlapping)?

A valid cube net must have exactly 6 squares connected edge-to-edge, with each square adjacent to at most 4 others, and when folded, all squares meet at edges without overlap.
This net is one of the 11 known cube nets.

cube, net, folding, 3d

Question 6

How many visible faces can be seen from the front view of this 3D arrangement (assuming each small cube has 6 faces, and cubes are placed on a ground plane, looking from a corner angle)? Cube arrangement (top view, 1=cube present): ⬜ ⬜ ⬜ ⬜

Each cube has 6 faces, but faces are hidden where cubes touch or touch the ground.
- Count visible faces: Top faces (1 per visible cube) + Front faces + Side faces.
- For this configuration, the total is 24 visible faces.

counting, faces, 3d, cubes

Question 7

How many visible faces can be seen from the front view of this 3D arrangement (assuming each small cube has 6 faces, and cubes are placed on a ground plane, looking from a corner angle)? Cube arrangement (top view, 1=cube present): ⬜ ⬜ ⬜

Each cube has 6 faces, but faces are hidden where cubes touch or touch the ground.
- Count visible faces: Top faces (1 per visible cube) + Front faces + Side faces.
- For this configuration, the total is 17 visible faces.

counting, faces, 3d, cubes

Question 8

How many visible faces can be seen from the front view of this 3D arrangement (assuming each small cube has 6 faces, and cubes are placed on a ground plane, looking from a corner angle)? Cube arrangement (top view, 1=cube present): ⬜ ⬜ ⬜

Each cube has 6 faces, but faces are hidden where cubes touch or touch the ground.
- Count visible faces: Top faces (1 per visible cube) + Front faces + Side faces.
- For this configuration, the total is 17 visible faces.

counting, faces, 3d, cubes

Question 9

A standard die (opposite faces sum to 7) is shown from different angles: View 1: Top: 2 Front: 3 Right: 5 Which face is opposite to face 3?

Using the standard dice rule (opposite faces sum to 7):
- From the views, we can determine adjacency relationships
- Face 3 appears in multiple views
- Tracking orientations shows it is opposite to 4 (since 3 + 4 = 7)

dice, opposite, 3d, orientation

Question 10

A standard die (opposite faces sum to 7) is shown from different angles: View 1: Top: 1 Front: 2 Right: 3 Which face is opposite to face 1?

Using the standard dice rule (opposite faces sum to 7):
- From the views, we can determine adjacency relationships
- Face 1 appears in multiple views
- Tracking orientations shows it is opposite to 6 (since 1 + 6 = 7)

dice, opposite, 3d, orientation

Question 11

If you assemble these 2D shapes in 3D space by joining matching edges, which 3D shape do you get? Parts: 6 × ⬜

The cube can be constructed from:
square, square, square, square, square, square arranged appropriately.
This is a standard net/assembly pattern for a cube.

assembly, 2d-to-3d, construction

Question 12

If you assemble these 2D shapes in 3D space by joining matching edges, which 3D shape do you get? Parts: ⚪ + ▭ + ⚪

The cylinder can be constructed from:
circle, rectangle, circle arranged appropriately.
This is a standard net/assembly pattern for a cylinder.

assembly, 2d-to-3d, construction

Question 13

This is the net of a cube with letters on each face: [A][B][C] [D] [E] [F] What is opposite to face A after folding?

By mentally folding the net:
- Identify which edges join when folded
- Track the 3D adjacency relationships
- F ends up opposite to the asked face based on the folding pattern.

cube, folding, pattern, 3d

Question 14

How many visible faces can be seen from the front view of this 3D arrangement (assuming each small cube has 6 faces, and cubes are placed on a ground plane, looking from a corner angle)? Cube arrangement (top view, 1=cube present): ⬜ ⬜ ⬜

Each cube has 6 faces, but faces are hidden where cubes touch or touch the ground.
- Count visible faces: Top faces (1 per visible cube) + Front faces + Side faces.
- For this configuration, the total is 17 visible faces.

counting, faces, 3d, cubes

Question 15

A standard die (opposite faces sum to 7) is shown from different angles: View 1: Top: 1 Front: 2 Right: 3 Which face is opposite to face 1?

Using the standard dice rule (opposite faces sum to 7):
- From the views, we can determine adjacency relationships
- Face 1 appears in multiple views
- Tracking orientations shows it is opposite to 6 (since 1 + 6 = 7)

dice, opposite, 3d, orientation

Question 16

Which of the following nets can be folded into a cube (without overlapping)?

A valid cube net must have exactly 6 squares connected edge-to-edge, with each square adjacent to at most 4 others, and when folded, all squares meet at edges without overlap.
This net is one of the 11 known cube nets.

cube, net, folding, 3d

Question 17

If you assemble these 2D shapes in 3D space by joining matching edges, which 3D shape do you get? Parts: ⚪ + ▭ + ⚪

The cylinder can be constructed from:
circle, rectangle, circle arranged appropriately.
This is a standard net/assembly pattern for a cylinder.

assembly, 2d-to-3d, construction

Question 18

A standard die (opposite faces sum to 7) is shown from different angles: View 1: Top: 1 Front: 2 Right: 3 Which face is opposite to face 1?

Using the standard dice rule (opposite faces sum to 7):
- From the views, we can determine adjacency relationships
- Face 1 appears in multiple views
- Tracking orientations shows it is opposite to 6 (since 1 + 6 = 7)

dice, opposite, 3d, orientation

Question 19

This is the net of a cube with letters on each face: [A] [B][C][D] [E] [F] If face C is on top, which face is on the bottom?

By mentally folding the net:
- Identify which edges join when folded
- Track the 3D adjacency relationships
- A ends up opposite to the asked face based on the folding pattern.

cube, folding, pattern, 3d

Question 20

How many visible faces can be seen from the front view of this 3D arrangement (assuming each small cube has 6 faces, and cubes are placed on a ground plane, looking from a corner angle)? Cube arrangement (top view, 1=cube present): ⬜ ⬜ ⬜

Each cube has 6 faces, but faces are hidden where cubes touch or touch the ground.
- Count visible faces: Top faces (1 per visible cube) + Front faces + Side faces.
- For this configuration, the total is 17 visible faces.

counting, faces, 3d, cubes

Shape Construction - Advanced Level: geometric logic ADVANCED

What you'll learn in this worksheet:

Question 1

Question 2

Question 3

Question 4

Question 5

Question 6

Question 7

Question 8

Question 9

Question 10

Question 11

Question 12

Question 13

Question 14

Question 15

Question 16

Question 17

Question 18

Question 19

Question 20