The invention relates generally to the field of oscillators. More specifically, this invention relates to voltage controlled oscillators for signal generation in wireless communication applications.
A voltage-controlled oscillator (VCO) is a circuit that produces an oscillating signal using amplification, feedback and a resonant circuit to generate a repeating voltage waveform, such that its output frequency is proportional to its input voltage.
In wireless communication applications, VCOs operate over large frequency ranges. VCO's generally comprise a tank circuit and an amplifier circuit, operation of which will be well known. Biasing of such circuits is also known and described in U.S. Pat. No. 6,674,333 to Peckham et al, which describes a method for operating a band switchable VCO in different frequency bands. In typical band switching circuits, biasing of the amplifier or a tank circuit introduces noise which results in phase noise being present in the output of the VCO.
It is, therefore, desirable to provide a method and apparatus for reduced noise band switching circuits.
It is an object of the present invention to obviate or mitigate at least one disadvantage of previous voltage control oscillator circuits.
In a first aspect, the present invention provides a low-phase noise voltage control oscillator (VCO) comprising a voltage source for supplying a control voltage to the VCO core; a phase lock loop, having an output connected to an input of the voltage source; a VCO core, including an amplifier circuit and a tank circuit; having an output connected to an input of the phase lock loop; a capacitance divider circuit attenuator, located between the voltage source and the VCO core, for reducing noise from the voltage source to the VCO core to reduce frequency variation of the voltage source.
In a further embodiment, there is provided a method of reducing noise in a voltage control oscillator (VCO) comprising the steps of providing an attenuated voltage to a VCO core comprising an amplifier circuit and a tank circuit; and biasing the amplifier circuit via an amplifier bias including amplifier switches and the tank circuit via a tank bias including tank switches, to reduce noise in an output of the VCO core.
Other aspects and features of the present invention will become apparent to those ordinarily skilled in the art upon review of the following description of specific embodiments of the invention in conjunction with the accompanying figures.
Embodiments of the present invention will now be described, by way of example only, with reference to the attached Figures, wherein:
a is a graph showing a set of control signals for the apparatus of
Generally, the present invention provides a method and apparatus for reduced noise band switching circuits.
Turning to
Turning now to
In operation, the voltage source 58 generates an input voltage for the tank circuit 66 of the VCO core 62. Simultaneously, the bias control 12 transmits a first set of control signals to the amplifier bias 54 and a second set of control signal to the tank bias 56.
After the input voltage has been generated, it is transmitted to the attenuator 60 before being transmitted to the tank circuit 66. While the input voltage is being attenuated, the amplifier bias 54 and the tank bias 56 control operation of the amplifier circuit 64 and the tank circuit 66 by providing a noiseless bias voltage as will be described below. The combination of the attenuated input voltage and the noiseless biasing voltage results in an output which is also noiseless which results in a cleaner output signal. An example of the output is shown in
With attenuation, the slope of fout versus source voltage, or Kvco, decreases so that for any change in source voltage, there is a small change in fout. A lower Kvco, results in a reduction in phase noise as shown in the following equation:
Therefore, the attenuation of the input voltage provides a reduced noise signal to the tank circuit, further allowing the output of the VCO core to be reduced in noise.
Turning to
When an input voltage is delivered, the phase lock loop 68 start operating and the switch 71 is closed (in the ON state) to create a path to charge the second capacitor 72 to the value of the input voltage (Vin). After the phase lock loop 68 has been able to lock, the capacitance voltage divider is seen as in a enabled state and therefore only a small loop gain is experienced at point A which also allows for the noise of the voltage signal to be reduced which, in turn, results in small variations in frequency due to noise. This is because the DC portion of the input voltage is relatively constant and the AC portion of the input voltage has been attenuated which causes the noise from the input voltage to also attenuate which, in turn, reduces the frequency variation due to noise.
The output 80 of the attenuator is connected to the tank circuit and acts as a tuning, or control, voltage for the tank circuit 66. The output of the attenuator is connected between a pair of varactors 108 as shown in
When an input voltage is delivered, the switch 79 is closed (in the ON state) to create a path to charge the second capacitor 72 to the value of the input voltage (Vin). After the second capacitor 72 reaches the value of Vin, the capacitance voltage divider is seen as in a enabled state and therefore only a small loop gain is experienced at point A which also allows for small variations in frequency due to noise.
a shows a comparison of Vout and input voltage Vin over time.
With the negative feedback loop 83, when Vin fluctuates to 5V, Vout increases to 2.5 volts as determined by the capacitance divider equation, Vout is then fed back to, which corrects the voltage source pulling Vin back down to 1V.
The attenuator 60 also comprises a pair of switches 94 and 96 which are used to assist in the charging of the capacitors during the initial period when the phase lock loop 68 is attempting to lock.
The output voltage Vout is attenuated by the equation shown below:
The attenuated output of the attenuator allows for a less noisy input voltage to the tank circuit 66 than if the voltage source 58 was connected directly to the tank circuit 66 since the double capacitance voltage divider lowers the value of a which in turn lowers the phase noise of the circuit.
Turning to
The amplifier bias 54 comprises a pair of switches 100 which are controlled by the bias control 52 along with an amplifier biasing voltage source 102. The bias control 52 also controls an amplifier biasing voltage source 102. In order to provide a noiseless bias voltage to the amplifier circuit 64, when the bias control 52 senses a logic high (indicating a power up state for the VCO 10), the first set of control signals are sent to the amplifier bias 54 and to the amplifier biasing voltage source 102, comprising an amplifier switch control signal and a Vbiasampflifiercontrol signal, respectively.
Upon receipt of the amplifier switch control signal, the switches 100 in the amplifier bias 54 close and, upon receipt of the Vbiasamplifiercontrol signal, the biasing voltage source 102 starts. The amplifier biasing voltage source 102 charges across the switches 100 to provide an output voltage to the amplifier circuit 64.
After a predetermined period of time, the bias control 52 transmits a signal to the amplifier bias 54 to open the switches 100. This occurs after the output voltage of the switches 100 has attained a predetermined value.
By opening the switches 100 after the predetermined voltage has been reached, the voltage being transmitted from the switches 100 to the amplifier circuit 64 may be seen as noiseless since there is no direct connection between the amplifier biasing voltage source 102 and the amplifier circuit 64. Therefore, the VCO core 62 may operate under noiseless bias conditions. A sample timing diagram is shown in
Turning to
As with the amplifier bias, the tank bias 56 comprises a pair of switches 104 which are controlled by the bias control 52 by the second set of control signals which includes a tank switch control signal. A tank bias voltage source 106 is controlled by a Vbiastankcontrol control signal which is transmitted by the bias control 52. Operation of the tank bias 56 is similar to the operation of the amplifier bias 54, as disclosed above with respect to
Due to the size and costs of the parts required for the attenuators of the present invention, it will be understood that these attenuators are beneficial for use in integrated circuits.
The provision of an attenuated voltage and the bias control voltage to the VCO core, provides a reduced noise band switching circuit.
The above-described embodiments of the invention are intended as examples only. Alterations, modifications and variations may be effected to the particular embodiments by those of skill in the art without departing from the scope of the invention, which is defined solely by the claims appended hereto.
This application claims the benefit of U.S. Provisional Application No. 60/531,609, filed Dec. 23, 2003, which is incorporated herein by reference.
Number | Date | Country | |
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60531609 | Dec 2003 | US |