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Cutting the noise for automotive radar and transceivers

Slashing the noise by a third of previous levels paves way to use of millimetre-band wireless communications terminals using silicon semiconductors


Fujitsu has developed a low-noise signal-generating circuit that can be used in automotive radar and other millimetre-band (30 GHz to 300 GHz) transceivers.

Also known as phase-locked loop circuit, a signal generating circuit generates a low-noise, highly stable signal by synchronising the oscillator signal to the reference signal.

In recent years, to enhance the resolution of radar and expand the capacity of wireless communications, efforts have been focused on developing transceivers operating in the millimetre-band frequency range above 30 GHz.

To raise the performance of millimetre-band transceivers and be able to produce them in mass quantities, it is necessary to use silicon-based semiconductors rather than the compound semiconductors(4) that have been used up until now. The problem, however, has been the difficulty of generating low-noise signals in the millimetre band.

Fujitsu has now developed a low-noise signal-generating circuit which consists of multiple comparators for operating sequential comparisons to reference signal. In doing so, they succeeded in reducing unwanted noise in the millimetre-band signal by 5 dB, to roughly one-third of previous levels, paving the way for the production of fully integrated millimetre-band transceiver circuits implemented on silicon semiconductors.

This technology is expected to make a significant contribution to raising the performance - and enabling the mass production - of automotive radars and other millimetre-band transceivers. A portion of these results were obtained through "Advanced Research on 79GHz-band Radar Systems," a research program commissioned by Japan's Ministry of Internal Affairs and Communications as part of its "Research and Development project for Expansion of Radio Spectrum Resources".

Background

In recent years, to enhance the resolution of radar and expand the capacity of wireless communications, efforts have been focused on developing transceivers operating in the millimetre-band frequency range above 30 GHz.

For the high frequency integrated circuits (ICs) used to send and receive millimetre-band signals, compound semiconductors, whose physical properties are well-suited to high frequency applications, are being used (Figure 1).

To integrate the features of a signal-processing circuit on a single chip, raise its level of performance, and enable it to be mass manufactured, however, silicon is more suitable than compound semiconductors (Figure 2). That is why research efforts have focused on creating millimetre-band transceiver ICs using silicon semiconductors.

Technological Challenges

Millimetre-band transceiver ICs need a signal-generating circuit to generate millimetre-band signals. Conventional millimetre-band signal-generating circuits compare the low frequency comparator signals, which are divided from the frequency of millimetre-band oscillator signals, to the low-noise, highly stable reference signals from the reference oscillator.

They then synchronize these two signals to generate low-noise, highly stable signals (Figure 3). Because the reference signal and comparator signal share the same frequency and a comparison is made one time for each cycle of the reference signal, the phase difference signal of the comparison results cannot be made sufficiently large compared to the noise generated from the phase difference detection circuits, and results in the problem of high levels of noise.


Figure 3. Conventional signal-generating circuit and timing illustration

In particular, because the level of noise generated by the transistors made of silicon semiconductors is high compared to that of compound semiconductors, there has been a need for circuit technology that generates low-noise and highly stable millimetre-band signals.

The newly developed technology employs a new architecture in which multiple phase difference detection circuits and delay circuits are connected in a line, enabling multiple comparisons to be made.

In the new circuit, the frequency of the comparison signal is raised and, furthermore, the reference signal is split into multiple signals, enabling multiple comparisons per cycle.

A phase difference signal is generated from each comparison, and because there are now more differential signals, their relative size, in relation to the noise generated by the phase difference detection circuit, is now larger, thereby enabling a reduction in the impact of the generated noise. Signal noise was successfully reduced by 5 dB below previous levels, resulting in approximately just one-third of the previous noise level.

Figure 4. Newly-developed signal-generating circuit and timing illustration

Results

The use of these technologies paves the way to the production of millimetre-band transceiver ICs implemented on silicon semiconductors. Accordingly, they are expected to make a significant contribution to raising the performance - and enabling the mass production - of automotive radars and other millimetre-band transceivers. Moreover, because the lower noise reduces electricity consumption and lowers the number of parts needed in a radar, they also will contribute to reducing burden on the environment.

Future Plans

In applying these technologies, Fujitsu plans to develop a single-chip millimetre-band transceiver IC module.

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