Board-to-board interconnect apparatus including a microstrip circuit connected by a waveguide, where a bandwidth of a frequency band is adjustable

What is claimed is: 1. A board-to-board interconnect apparatus comprising: a waveguide which transmits a signal from a board on the side of a transmitter to a board on the side of a receiver and has a metal cladding; and a microstrip circuit which is formed on each of the transmitter-side board and the receiver-side board, wherein the microstrip circuit is connected to the waveguide and has a microstrip-to-waveguide transition (MWT), wherein the microstrip circuit adjusts a bandwidth of a first predetermined frequency band of the signal to provide the signal to the receiver, and wherein the bandwidth of the first predetermined frequency band is adjusted by adjusting a slope of an upper cutoff frequency band of the signal. 2. The board-to-board interconnect apparatus of claim 1 , wherein the microstrip circuit comprises: a microstrip feeding line which supplies the signal in a first layer of the board on which the microstrip circuit is formed; a probe element which adjusts the bandwidth of the first predetermined frequency band; a slotted ground plane including a slot for minimizing a ratio of reverse-traveling waves to forward-traveling waves in a second layer of the board on which the microstrip circuit is formed, wherein the forward-traveling waves travel from the microstrip circuit to the waveguide, and the reverse-traveling waves travel from the waveguide to the microstrip circuit; a ground plane including vias for forming an electrical connection between the slotted ground plane and the ground plane in a third layer of the board on which the microstrip circuit is formed; and a patch which is disposed in the third layer and is electrically isolated from the ground plane and radiates the signal at a resonance frequency. 3. The board-to-board interconnect apparatus of claim 2 , wherein the probe element has a characteristic impedance greater than a characteristic impedance of the microstrip feeding line. 4. The board-to-board interconnect apparatus of claim 2 , wherein the probe element is connected to an end of the microstrip feeding line, and has a predetermined width and length. 5. The board-to-board interconnect apparatus of claim 4 , wherein the length of the probe element is determined based on a wavelength of the resonance frequency. 6. The board-to-board interconnect apparatus of claim 4 , wherein the width of the probe element is 40 to 80% of a width of the microstrip feeding line. 7. A microstrip circuit comprising: a microstrip feeding line which supplies a signal in a first layer of a board on which the microstrip circuit is formed; a probe element which adjusts a bandwidth of a first predetermined frequency band of the signal; a slotted ground plane including a slot for minimizing a ratio of reverse-traveling waves to forward-traveling waves in a second layer of the board on which the microstrip circuit is formed, wherein the forward-traveling waves travel from the microstrip circuit to a waveguide connected to the microstrip circuit, and the reverse-traveling waves travel from the waveguide to the microstrip circuit; a ground plane including vias for forming an electrical connection between the slotted ground plane and the ground plane in a third layer of the board on which the microstrip circuit is formed; and a patch which is disposed in the third layer and is electrically isolated from the ground plane and radiates the signal at a resonance frequency, wherein the bandwidth of the first predetermined frequency band is adjusted by adjusting a slope of an upper cutoff frequency band of the signal. 8. The microstrip circuit of claim 7 , wherein the probe element has a characteristic impedance greater than a characteristic impedance of the microstrip feeding line. 9. The microstrip circuit of claim 7 , wherein the probe element is connected to an end of the microstrip feeding line, and has a predetermined width and length. 10. The microstrip circuit of claim 9 , wherein the length of the probe element is determined based on a wavelength of the resonance frequency. 11. The microstrip circuit of claim 9 , wherein the width of the probe element is 40 to 80% of a width of the microstrip feeding line.