Directional coupler

What is claimed is: 1. A directional coupler comprising: a first electrically conductive member having a first electrically conductive surface; a second electrically conductive member having a second electrically conductive surface opposing the first electrically conductive surface; a plurality of ridges protruding from the second electrically conductive surface, each having an electrically-conductive waveguide face which extends in opposition to the first electrically conductive surface; and a plurality of electrically-conductive rods protruding from the second electrically conductive surface and being located around the plurality of ridges, each having a leading end opposing the first electrically conductive surface, wherein, the plurality of ridges include a first main ridge, a second main ridge, a third main ridge, a fourth main ridge, a first connection ridge connecting one end of the first main ridge and one end of the third main ridge, a second connection ridge connecting one end of the second main ridge and one end of the fourth main ridge, a first bypass ridge connecting the one end of the first main ridge and the one end of the second main ridge, and a second bypass ridge connecting the one end of the third main ridge and the one end of the fourth main ridge; a first waffle-iron ridge waveguide is created between the waveguide faces of the first main ridge, the first connection ridge, and the third main ridge and the first electrically conductive surface; a second waffle-iron ridge waveguide is created between the waveguide faces of the second main ridge, the second connection ridge, and the fourth main ridge and the first electrically conductive surface; a first bypass waveguide is created between the waveguide face of the first bypass ridge and the first electrically conductive surface; a second bypass waveguide is created between the waveguide face of the second bypass ridge and the first electrically conductive surface; a portion of an electromagnetic wave which propagates in the first waffle-iron ridge waveguide from another end of the first main ridge toward another end of the third main ridge is propagated, via the first bypass waveguide, in the second waffle-iron ridge waveguide toward another end of the fourth main ridge; a portion of an electromagnetic wave which propagates in the first waffle-iron ridge waveguide from the other end of the third main ridge toward the other end of the first main ridge is propagated, via the second bypass waveguide, in the second waffle-iron ridge waveguide toward another end of the second main ridge; spacings da 1 , da 2 , da 3 and da 4 respectively exist between the first electrically conductive surface and the waveguide faces of the first, second, third, and fourth main ridges; spacings db 1 and db 2 respectively exist between the first electrically conductive surface and the waveguide faces of the first and second connection ridges; spacings dc 1 and dc 2 respectively exist between the first electrically conductive surface and the waveguide faces of the first and second bypass ridges; and the relationship db 1 , db 2 <da 1 , da 2 , da 3 , da 4 , dc 1 , dc 2 is satisfied. 2. The directional coupler of claim 1 , wherein the first and second connection ridges are greater in height than the first to fourth main ridges, and greater in height than the first and second bypass ridges. 3. The directional coupler of claim 1 , wherein the first electrically conductive surface has two protrusions respectively opposed to the waveguide faces of the first and second connection ridges. 4. The directional coupler of claim 1 , wherein, the first and second connection ridges are greater in height than the first to fourth main ridges, and greater in height than the first and second bypass ridges; the first electrically conductive surface is flat; and the first electrically conductive surface has two protrusions respectively opposed to the waveguide faces of the first and second connection ridges. 5. The directional coupler of claim 1 , wherein, the plurality of ridges further include a third bypass ridge connecting a central portion of the first connection ridge and a central portion of the second connection ridge; and a third bypass waveguide is created between the waveguide face of the third bypass ridge and the first electrically conductive surface. 6. The directional coupler of claim 1 , wherein, the first and second connection ridges are greater in height than the first to fourth main ridges, and greater in height than the first and second bypass ridges; the plurality of ridges further include a third bypass ridge connecting a central portion of the first connection ridge and a central portion of the second connection ridge; and a third bypass waveguide is created between the waveguide face of the third bypass ridge and the first electrically conductive surface. 7. The directional coupler of claim 3 , wherein, the first electrically conductive surface is flat; the plurality of ridges further include a third bypass ridge connecting a central portion of the first connection ridge and a central portion of the second connection ridge; and a third bypass waveguide is created between the waveguide face of the third bypass ridge and the first electrically conductive surface. 8. The directional coupler of claim 5 , wherein, the first and second connection ridges are greater in height than the first to fourth main ridges, and greater in height than the first and second bypass ridges; an electromagnetic wave which propagates along the first main ridge has a central wavelength λ; a length of each of the first and second connection ridges as taken along the waveguide face is equal to or greater than λ and less than 2λ; and a length of each of the first to third bypass ridges as taken along the waveguide face is equal to or greater than λ/2 and less than λ. 9. The directional coupler of claim 1 , wherein, the plurality of ridges further include a third bypass ridge connecting a central portion of the first connection ridge and a central portion of the second connection ridge; a third bypass waveguide is created between the waveguide face of the third bypass ridge and the first electrically conductive surface; a spacing dc 3 exists between the waveguide face of the third bypass ridge and the first electrically conductive surface; and the following relationship is satisfied: db 1, db 2< da 1, da 2, da 3, da 4< dc 1, dc 2, and db 1, db 2< dc 3< dc 1, dc 2. 10. The directional coupler of claim 1 , wherein, the first and second connection ridges are greater in height than the first to fourth main ridges, and greater in height than the first and second bypass ridges; a spacing dc 3 exists between the waveguide face of the third bypass ridge and the first electrically conductive surface; and the following relationship is satisfied: db 1, db 2< da 1, da 2, da 3, da 4< dc 1, dc 2, and db 1, db 2< dc 3< dc 1, dc 2. 11. The directional coupler of claim 2 , wherein, the plurality of ridges further include a third bypass ridge connecting a central portion of the first connection ridge and a central portion of the second connection ridge; a third bypass waveguide is created between the waveguide face of the third bypass ridge and the first electrically conductive surface; an electromagnetic wave which propagates along the first main ridge has a central wavelength λ; a length of each of the first and second connection ridges as taken along the waveguide face is equal to or greater than λ and less than 2λ; a length of each of the first to third bypass ridges as taken along the