The present invention relates generally to techniques which are effectively applied for improving the characteristics of a voltage controlled oscillation circuit (VCO) capable of switching from one oscillating frequency to another as well as the characteristics of an on-chip VCO, and facilitating measurements of the characteristics of such VCOs, and more particularly, to techniques which are effectively utilized in a VCO mounted in a high frequency semiconductor integrated circuit for demodulating a reception signal and modulating a transmission signal in radio communication apparatuses, for example, a portable telephone and the like which can transmit and receive signals in a plurality of bands.
A radio communication system such as a portable telephone uses a PLL (phase locked loop) circuit which has a VCO for generating an oscillating signal at a predetermined frequency. The oscillating signal is combined with a reception signal and a transmission signal. Conventional portable telephones include a dual-band portable telephone which can handle signals in two frequency bands, for example, a GSM (Global System for Mobile Communication) signal in a band of 880-915 MHz and a DCS (Digital Cellular System) signal in a band of 1710-1785 MHz. Some dual-band portable telephones are designed to support two different bands with a single PLL circuit by switching the frequency of the PLL circuit.
In recent years, however, a need exists for a triple-band portable telephone which can handle, for example, a PCS (Personal Communication System) signal in a band of 1850-1915 MHz in addition to the GSM and DCS signals. It is also contemplated that the portable telephones are required to support a larger number of bands in the future.
For a high frequency semiconductor integrated circuit (hereinafter called the “high frequency IC”) designed to modulate a transmission signal and demodulate a reception signal, for use in such a portable telephone which can support a plurality of bands, a direct conversion system is effective from a viewpoint of a reduction in the number of parts. While the direct conversion system is relatively easy in supporting a plurality of bands, a VCO should be capable of oscillating over a wide frequency range. In this event, when a single VCO is used with the intention to cover the overall frequency range, the resulting VCO would be extremely sensitive to a control voltage applied thereto, and therefore vulnerable to extraneous noise and fluctuations in a power supply voltage.
On the other hand, a reduction in the number of parts may be effectively accomplished by forming a VCO, which has been typically fabricated in a module separate from a high frequency IC in many cases, on the same semiconductor chip on which the high frequency IC is fabricated. However, since an on-chip VCO manufactured by the current technologies experiences large variations in the absolute value of the oscillating frequency, the on-chip VCO must be provided with a function of correcting the oscillating frequency after the manufacturing. However, if the variations are corrected by trimming based on a mask option or a bonding wire option, typically used in conventional semiconductor integrated circuits, the cost is inevitably increased.