Cascaded radio frequency system

What is claimed is: 1. A cascaded radio frequency (RF) system, comprising a first monolithic microwave integrated circuit (MMIC) comprising: a first local oscillator (LO) generation circuit configured to generate a first LO signal based a system clock signal during a first mode of operation of the cascaded RF system; a first LO output terminal configured to output first the LO signal during the first mode of operation; a first LO input terminal configured to receive the first LO signal during the first mode of operation; and a second LO input terminal configured to receive a second LO signal during a second mode of operation of the cascaded RF system; and a second MMIC comprising: a second LO generation circuit configured to generate the second LO signal based on the system clock signal during the second mode of operation; a second LO output terminal configured to output the second LO signal during the second mode of operation; a third LO input terminal configured to receive the second LO signal during the second mode of operation; and a fourth LO input terminal configured to receive the first LO signal during the first mode of operation. 2. The cascaded RF system of claim 1 , wherein the first MMIC and the second MMIC are configured to operate respective transmitter and receiver circuitry based on the first LO signal during the first mode of operation and to operate respective transmitter and receiver circuitry based on the second LO signal during the second mode of operation. 3. The cascaded RF system of claim 1 , wherein the first MMIC comprises: an input configured to receive the system clock signal; a clock output terminal configured to relay the system clock signal; and a first clock input terminal coupled to the clock output terminal, and wherein the second MMIC comprises: a second clock input terminal coupled to the clock output terminal of the first MMIC. 4. The cascaded RF system of claim 1 , further comprising: a first signal path coupled between the first LO output terminal and the first LO input terminal of the first MMIC; and a second signal path coupled between the first LO output terminal of the first MMIC and the fourth LO input terminal of the second MMIC, wherein the first and the second signal paths are of a same length. 5. The cascaded RF system of claim 1 , further comprising a first signal path coupled between the second LO output terminal and the third LO input terminal of the second MMIC; and a second signal path coupled between the second LO output terminal of the second MMIC and the second LO input terminal of the first MMIC, wherein the first and the second signal paths are of a same length. 6. The cascaded RF system of claim 4 , wherein the first and the second LO input terminals; of the first MMIC are arranged on opposite sides of the first MMIC, and wherein the third and the fourth LO input terminals of the second MMIC are arranged on opposite sides of the second MMIC. 7. The cascaded RF system of claim 1 , wherein the first MMIC and the second MMIC are arranged on a printed circuit board (PCB) to cause the first LO input terminal of the first MMIC and the fourth LO input terminal of the second MMIC to face in opposite directions. 8. The cascaded RF system of claim 1 , wherein the first MMIC and the second MMIC are arranged on a printed circuit board (PCB) to cause the first LO input terminal of the first MMIC and the fourth LO input terminal of the second MMIC to face each other. 9. The cascaded RF system of claim 1 , further comprising a control circuit configured to detect a state of failure of the first LO generation circuit of the first MMIC and, in case of failure, to switch from the first mode of operation to the second mode of operation of the cascaded RF system. 10. The cascaded RF system of claim 1 , wherein the first MMIC comprises a clock output terminal coupled to a second clock input terminal of the second MMIC, wherein the first MMIC is configured to forward the system clock signal to the second MMIC. 11. The cascaded RF system of claim 1 , wherein the first and the second MMICs are radar MMICs. 12. The cascaded RF system of claim 1 , wherein the first and the second MMICs form a first MMIC subsystem, and wherein the cascaded RF system further comprises a second MMIC subsystem comprising: a third MMIC comprising: a third LO generation circuit configured to generate a third LO signal based on the system clock signal during the second mode of operation; a third LO output terminal configured to output the third LO signal during the second mode of operation; a fifth LO input terminal for receiving the third LO signal during the second mode of operation; and a sixth LO input terminal for receiving the first LO signal during the first mode of operation; and a fourth MMIC comprising: a fourth LO generation circuit configured to generate a fourth LO signal based on the system clock signal; a fourth LO output terminal; a seventh LO input terminal configured to receive the third LO signal during the second mode of operation; and an eighth LO input terminal configured to receive the first LO signal during the first mode of operation. 13. A vehicle, comprising: a cascaded radio frequency (RF) system comprising a first monolithic microwave integrated circuit (MMIC) and a second MMIC: wherein the first MMIC comprises: a first local oscillator (LO) generation circuit configured to generate a first LO signal based a system clock signal during a first mode of operation of the cascaded RF system; a first LO output terminal configured to output first the LO signal during the first mode of operation; a first LO input terminal configured to receive the first LO signal during the first mode of operation; and a second LO input terminal configured to receive a second LO signal during a second mode of operation of the cascaded RF system, and wherein the second MMIC comprises: a second LO generation circuit configured to generate the second LO signal based on the system clock signal during the second mode of operation; a second LO output terminal configured to output the second LO signal during the second mode of operation; a third LO input terminal configured to receive the second LO signal during the second mode of operation; and a fourth LO input terminal configured to receive the first LO signal during the first mode of operation. 14. A radar monolithic microwave integrated circuit (MMIC), comprising: a local oscillator (LO) generation circuit configured to generate a first LO signal based on a system clock signal; an LO output terminal configured to output the first LO signal; a first LO input terminal configured to receive the first LO signal during a first mode of operation; and a second LO input terminal configured to receive a second LO signal from another radar MMIC during a second mode of operation. 15. The radar MMIC of claim 14 , wherein the radar MMIC is configured to operate its transmitter and receiver circuitry based on the first LO signal during the first mode of operation and to operate its transmitter and receiver circuitry based on the second LO signal during the second mode of operation. 16. The radar MMIC of claim 14 , wherein the first and the second LO input terminals are arranged on opposite sides of the radar MMIC. 17. The radar MMIC of claim 14 , further comprising a first clock input terminal and a second clock input terminal configured to receive the system clock signal. 18. The cascaded RF system of claim 5 , wherein the first a