CN113922759A - LC voltage-controlled oscillator - Google Patents

Abstract

The invention discloses an LC voltage-controlled oscillator, which comprises an LC oscillating circuit and a cross coupling active module, wherein the LC oscillating circuit comprises an inductor, a main capacitance diode circuit, a power supply push compensation circuit and a coarse tuning capacitor bank, and the cross coupling active module, the inductor, the main capacitance diode circuit, the power supply push compensation circuit and the coarse tuning capacitor bank are coupled between two output ends of the voltage-controlled oscillator in parallel. The invention can obtain different positive power supply push values by adjusting the bias supply voltage of the power supply push compensation circuit, so that the whole power supply push is reduced to the minimum, the influence of power supply noise is reduced to the minimum, and the power supply noise of the LC voltage-controlled oscillator is smaller.

Description

LC voltage-controlled oscillator

[ technical field ]

The invention relates to a voltage-controlled oscillator, in particular to an LC voltage-controlled oscillator.

[ background art ]

The voltage-controlled oscillator is an oscillating circuit (VCO) having a corresponding relationship between an output frequency and an input control voltage, the frequency of the oscillator VCO is a function of the input signal voltage, and the operating state of the oscillator or the parameters of the elements of the oscillating circuit are controlled by the input control voltage to form a voltage-controlled oscillator.

The invention with application number CN201280011530.5 discloses a temperature compensation and coarse tuning bank switch in a low phase noise VCO, an LC oscillating circuit of the VCO includes a main varactor circuit and a temperature compensation varactor circuit coupled in parallel with the main varactor circuit. The main varactor circuit is used for fine tuning. The temperature compensating varactor circuit has a capacitance-voltage characteristic that is different from the capacitance-voltage characteristic of the main varactor circuit such that the effect of common mode noise across the two varactor circuits is minimized. The LC tank also has a plurality of switchable capacitor circuits set to coarse tuning. To prevent breakdown of the main thin oxide switch in each switchable capacitor circuit, each switchable capacitor circuit has a capacitive voltage divider circuit that reduces the voltage across the main thin oxide when the main switch is turned off.

The power supply push of the switchable capacitor circuit and the negative resistance circuit of the invention are both negative, and the influence of power supply noise on the LC voltage-controlled oscillator is large.

[ summary of the invention ]

The invention aims to provide an LC voltage-controlled oscillator with low power supply noise.

In order to solve the technical problem, the invention adopts the technical scheme that the LC voltage-controlled oscillator comprises an LC oscillating circuit and a cross coupling active module, wherein the LC oscillating circuit comprises an inductor, a main capacitance diode circuit, a power supply push compensation circuit and a coarse tuning capacitor bank, and the cross coupling active module, the inductor, the main capacitance diode circuit, the power supply push compensation circuit and the coarse tuning capacitor bank are coupled between two output ends of the voltage-controlled oscillator in parallel.

In the LC voltage-controlled oscillator, the power supply push compensation circuit includes at least one power supply push compensation unit circuit, the power supply push compensation unit circuit includes a third diode, a fourth diode, a third capacitor, a fourth capacitor, a third resistor and a fourth resistor, an anode of the third diode is connected to an anode of the fourth diode, and is connected to the input terminal of the bias voltage; the cathode of the third diode is connected with the first parallel coupling end of the power supply push compensation circuit through a third capacitor, and the cathode of the fourth diode is connected with the second parallel coupling end of the power supply push compensation circuit through a fourth capacitor; the first end of the third resistor is connected with the cathode of the third diode, and the first end of the fourth resistor is connected with the cathode of the fourth diode; the second end of the third resistor and the second end of the fourth resistor are connected with each other and connected with the input end of the power supply pushing compensation circuit bias power supply voltage.

In the LC vco described above, the power supply push compensation circuit includes a plurality of power supply push compensation unit circuits, and the plurality of power supply push compensation unit circuits are connected in parallel.

In the LC voltage controlled oscillator, the main varactor diode circuit includes a first diode, a second diode, a first capacitor, a second capacitor, a first resistor and a second resistor, wherein an anode of the first diode is connected to an anode of the second diode and connected to a voltage signal input terminal of the voltage controlled oscillator; the cathode of the first diode is connected with a first parallel coupling end of the main capacitance-variable diode circuit through a first capacitor, and the cathode of the second diode is connected with a second parallel coupling end of the main capacitance-variable diode circuit through a second capacitor; the first end of the first resistor is connected with the cathode of the first diode, and the first end of the second resistor is connected with the cathode of the second diode; the second end of the first resistor and the second end of the second resistor are connected with each other and connected with the input end of the bias supply voltage of the main capacitance diode.

In the LC voltage-controlled oscillator, the coarse tuning capacitor bank is a switchable capacitor array, the switchable capacitor array includes a plurality of switchable capacitor unit circuits connected in parallel and a switching circuit, and the switching circuit includes a switching signal input end.

In the LC voltage-controlled oscillator, the switchable capacitor unit circuit includes a switching tube, a fifth capacitor, a sixth capacitor, a fifth resistor, and a sixth resistor, a first end of the fifth capacitor is connected to a first end of the sixth capacitor through the switching tube, and a control end of the switching tube is connected to an input end of the control voltage; the second end of the fifth capacitor is connected with the first parallel coupling end of the coarse tuning capacitor bank, and the second end of the sixth capacitor is connected with the second parallel coupling end of the coarse tuning capacitor bank; the first end of the fifth resistor is connected with the first end of the fifth capacitor, and the first end of the sixth resistor is connected with the first end of the sixth capacitor; the second end of the fifth resistor and the second end of the sixth resistor are connected with each other and connected with the input end of the bias supply voltage in parallel.

The digital signal input by the switching signal input end enables the switchable capacitor unit circuit to be selectively connected into or disconnected from the LC oscillating circuit; and the switchable capacitance unit circuit is switched off to reduce the total capacitance of the LC oscillating circuit, so that the output frequency of the LC voltage-controlled oscillator is increased.

In the LC voltage-controlled oscillator, the cross-coupled active module is an NMOS and PMOS cross-coupled transistor structure.

In the LC voltage-controlled oscillator, the bias voltage is divided by the power supply voltage, and the division ratio is a; the bias power supply voltage of the power supply push compensation circuit is divided by the power supply voltage, and the voltage division ratio is B; b > A

In the LC voltage controlled oscillator described above, the power supply push compensation circuit performs the following correction procedure:

1001) setting the number of times of bias power supply voltage adjustment of the power supply push compensation circuit as M;

1002) adjusting the bias supply voltage of the power supply push compensation circuit, and calculating the power supply push K of the LC voltage-controlled oscillator once every time the bias supply voltage of the power supply push compensation circuit is adjusted_VDDCalculating the power supply push K_VDDThe process of (2) is as follows;

setting power supply voltage VDD to VDD₁Obtaining the output frequency f of the LC voltage-controlled oscillator₁；

Setting power supply voltage VDD to VDD₂Obtaining the output frequency f of the LC voltage-controlled oscillator₂；

Power push K_VDD＝(f₂-f₁)/(VDD₂-VDD₁)；

1003) The bias supply voltage of the power supply push compensation circuit is adjusted for M times to obtain M power supply push values, wherein the bias supply voltage corresponding to the power supply push value with the smallest absolute value is used as the preferred value of the bias supply voltage of the power supply push compensation circuit.

The invention can obtain different positive power supply push values by adjusting the bias supply voltage of the power supply push compensation circuit, so that the whole power supply push is reduced to the minimum, the influence of power supply noise is reduced to the minimum, and the power supply noise of the LC voltage-controlled oscillator is smaller.

[ description of the drawings ]

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic block diagram of an LC voltage controlled oscillator according to an embodiment of the present invention.

Fig. 2 is a circuit diagram of an LC voltage controlled oscillator according to an embodiment of the present invention.

Fig. 3 is a circuit diagram of a cross-coupled active module according to an embodiment of the invention.

Fig. 4 is a circuit diagram of a switchable capacitive cell circuit according to an embodiment of the invention.

FIG. 5 is a flowchart illustrating power push calibration steps according to an embodiment of the present invention.

[ detailed description of the invention ]

The structure and the principle of the LC voltage-controlled oscillator according to the embodiment of the present invention are shown in fig. 1 to 5, and the LC voltage-controlled oscillator includes an LC oscillating circuit and a cross-coupled active module (negative resistance circuit), where the LC oscillating circuit (LC resonant cavity) includes an inductor L, a main capacitance diode circuit, a power push compensation circuit (power push compensation diode circuit), a switchable capacitor array (coarse tuning capacitor array), and a voltage signal input terminal V_CTRLAnd two output terminals V_OUTPAnd V_OUTN. When V is input at the voltage signal input terminal_CTRLThe voltage changes, the capacitance value of the main capacitance diode circuit also changes, so that the output signal V_OUTPAnd V_OUTNWith a change in frequency.

The cross-coupled active module (negative resistance circuit), the inductor L, the main varactor circuit, the power push compensation circuit and the switchable capacitor array are coupled in parallel to two output ends V of the voltage-controlled oscillator_OUTPAnd V_OUTNIn the meantime. The cross-coupled active module (negative resistance circuit) provides negative resistance to compensate the positive resistance in the LC resonant cavity (inductor, switchable capacitor array, main varactor circuit, and power supply push compensation circuit) to make the output V of the voltage-controlled oscillator_OUTPAnd V_OUTNA signal with a frequency of 1/2 pi/√ (LC) is generated.

As shown in FIG. 2, the main varactor circuit includes a first diode D_V,1A second diode D_V,2A first capacitor C₁A second capacitor C₂A first resistor R₁And a second resistor R₂The anode of the first diode DV,1 and the second diode D_V,2Are connected with each other and connected with a voltage signal input terminal V of a voltage controlled oscillator_CTRL. First diode D_V,1Through a first capacitor C₁A first parallel coupling end connected with the main varactor diode circuit and a second diode D_V,2Through a second capacitor C₂And is connected with the second parallel coupling end of the main varactor circuit. A first resistor R₁Is connected to the cathode of a first diode DV,1, a second resistor R₂First end of the second diode D_V,₂The cathode of (1). A first resistor R₁Second terminal and second resistor R₂Are connected with each other and connected with an input end V of a main capacitance diode bias voltage supply voltage_BIAS2。

As shown in fig. 2, the power supply push compensation circuit includes a plurality of power supply push compensation unit circuits connected in parallel.

The power supply push compensation unit circuit comprises a third diode D_C,1A fourth diode D_C,2A third capacitor C₃A fourth capacitor C₄A third resistor R₃And a fourth resistor R₄A third diode D_C,1Anode of and a fourth diode D_C,₂Are connected to each other and to an input terminal V for a bias voltage signal. The bias voltage V is divided by the power supply voltage VDD. Third diode D_C,1Through a third capacitor C₃A fourth diode D connected with the first parallel coupling end of the power supply push compensation circuit_C,2Through a fourth capacitor C₄And the second parallel coupling end of the power supply push compensation circuit is connected. Third resistor R₃First end of the first diode D is connected with a third diode D_C,1A fourth resistor R₄First end of the fourth diode D_C,2Of a cathode. Third resistor R₃Second terminal and fourth resistor R₄Are connected with each other and connected with an input terminal V of a bias supply voltage of the power supply push compensation circuit_BIAS3. Power supply push compensation circuit bias supply voltage V_BIAS3Also divided by the supply voltage VDD.

As shown in FIG. 3, the cross-coupled active module includes a PMOS transistor M_P1、M_P2And N MOS tube M_N1、M_N2. Wherein, P MOS tube M_P1And M_P2The source electrode of the transistor is connected with a power supply voltage VDD, and an N MOS transistor M_N1And M_N2Is grounded. M_P1,M_N1Is connected to V_OUTNDrain to V_OUTP；M_P2,M_N2Is connected to V_OUTPDrain to V_OUTNAnd forming a cross pair transistor structure of NMOS and PMOS. The cross-coupled active module generates a negative resistance to form a complementary negative resistance circuit for compensating the resistance in the LC tank.

As shown in fig. 2 and 4, the switchable capacitor array includes a plurality of switchable capacitor unit circuits and switching circuits connected in parallel. The switching circuit includes an input terminal CAP [ N:0] for a switching signal.

The switchable capacitor unit circuit comprises a MOS transistor M_n，₁A fifth capacitor C_SW1A sixth capacitor C_SW2A fifth resistor R₅And a sixth resistor R₆Fifth capacitor C_SW1First terminal and sixth capacitor C_SW2First end of the MOS transistor M_n，₁Source and drain connections of MOS transistor M_n，₁Is connected with a control voltage V_CTo the input terminal of (1). Fifth capacitor C_SW1The second terminal of the first capacitor is connected with the first parallel coupling terminal of the switchable capacitor array, and the sixth capacitor C_SW2And the second end of the second switch is connected with the second parallel coupling end of the switchable capacitor array. Fifth resistor R₈Is connected with a fifth capacitor C_SW1A first terminal of (1), a sixth resistor R₉First terminal of the sixth capacitor C_SW2The first end of (a). Fifth resistor R₅Second terminal and sixth resistor R₆Are connected to each other and are connected in parallel to an input terminal V of a bias supply voltage_BIAS1。C_P1And C_P2Is a parasitic (stray) capacitance.

As shown in FIG. 2, CAP [ N:0]]Is a digital signal input end connected with a serial bus interface and an MOS tube M_n，₁Gate control voltage V of_CIs a digital signal CAP [ N:0]And (4) controlling. By controlling MOS transistor M_n，₁Gate control voltage V of_CInput digital signal CAP [ N:0]]Make the switchable capacitor array C_SCAThe switchable capacitor unit circuit can be selectively connected into or disconnected from the LC oscillating circuit, the total capacitance of the LC oscillating circuit can be increased by increasing the number of the switchable capacitor units, and therefore the output frequency of the LC voltage-controlled oscillator is reduced; the total capacitance of the LC oscillating circuit can be reduced by disconnecting the switchable capacitance unit, so that the output frequency of the LC voltage-controlled oscillator is increased.

Power Supply pushing (supplying) K_VDDThe influence coefficient of the change of the power supply voltage on the output frequency of the voltage-controlled oscillator. If the supply voltage VDD rises to raise the output frequency of the voltage controlled oscillator, K_VDDIs a positive value; if the power supply voltage VDD rises and the output frequency of the voltage-controlled oscillator falls, K_VDDIs negative.

Following is a power Supply pushing (supplying) K of each module circuit in the embodiment of the present invention_VDDThe analysis is carried out in such a way that,

as shown in FIG. 3, if the power supply voltage VDD rises, the negative resistance circuit M_N1,M_N2,M_P1,M_P2Parasitic junction capacitance C of the gate_P1,C_P2The power supply voltage rises due to the rise of the power supply voltage, so that the equivalent capacitance of the overall negative resistance circuit increases, and the frequency decreases.

The switchable capacitor array structure is shown in fig. 2 and 4, and is formed by connecting a plurality of switchable capacitor unit circuits in parallel, so that power supply pushing of the array can be discussed only with respect to one switchable capacitor unit circuit.

When the switchable capacitive cell circuit is on, i.e. V_BIAS1＝0,V_C＝VDD,M_n1The equivalent parasitic capacitance of the gate-source and the gate-drain of the transistor increases with the rise of the power supply voltage;

when the switchable capacitive cell circuit is switched off, i.e. V_BIAS1＝VDD,V_C＝0,M_n1Parasitic Junction Capacitance (Parasitic Junction Capacitance) C of the source to ground and the drain to ground_P1,C_P2The capacitance of the switchable capacitor array is increased along with the increase of the power voltage, and the overall capacitance of the switchable capacitor array is increased along with the increase of the power voltage, so that the power push of the switchable capacitor array is a negative value.

The following discusses the power biasing of the main varactor circuit according to embodiments of the present invention. As shown in fig. 2, e.g. supply voltage V_DDRising, due to the integration of a voltage controlled oscillator into the phase locked loop, V_CTRLLocked by the whole phase-locked loop, but V is caused to be constant_BIAS2And (4) rising. As can be seen from the capacitance-voltage characteristics of the varactor, the equivalent capacitance decreases as the cathode voltage increases without changing the anode voltage of the varactor. Therefore, the power voltage rises, the equivalent capacitance of the main varactor circuit will drop, so that the frequency rises, and the power of the main varactor circuit is pushed to a positive value.

Power supply push K from integral voltage controlled oscillator_VDDIn view of the action of, K_VDDThe smaller the absolute value of (c), the less influence on the power supply noise. From the above analysis, it can be seen that there is an opportunity for K to be included in a module other than a varactor circuit_VDDPositive values, the remaining modules K_VDDAre all negative. However, the main varactor circuit also involves the voltage-controlled oscillator gain (K)_VCO) Cannot be optimized for power pushes.

As shown in fig. 2, the third diode D of the power supply push compensation circuit_C,1A fourth diode D_C,2The anode of the power supply is connected with a bias voltage V, the bias voltage V is divided by a power supply voltage VDD, the voltage division ratio is A, and then V is VDD A; power supply push compensation circuit bias supply voltage V_BIAS3Is also divided by the supply voltage VDD, V assuming a division ratio of B_BIAS3At B, VDD B>On the premise of A, different positive power supply pushing values can be obtained by adjusting different values of A and B.

Adjusting power supply push compensation circuit bias supply voltage V_BIAS3Different positive power supply push values can be obtained, and through the adjustment and selection process shown in fig. 5, the overall power supply push of the voltage-controlled oscillator can be reduced to the minimum, and meanwhile, the influence of power supply noise is reduced to the minimum.

As shown in FIG. 5, the initial bias supply voltage of the power supply push compensation circuit is V_BIAS3(0)Initial power supply push K of LC voltage-controlled oscillator_VDD(0). The number of adjustments is set to M.

Bias supply voltage V for power supply push compensation circuit_BIAS3Adjusting the bias supply voltage of the power supply push compensation circuit to V every time_BIAS3Calculating the power supply push K of the primary LC voltage-controlled oscillator_VDDCalculating the power supply push K_VDDThe process of (2) is as follows;

setting power supply voltage VDD to VDD₁Obtaining the output frequency f of the LC voltage-controlled oscillator₁；

Setting power supply voltage VDD to VDD₂Obtaining the output frequency f of the LC voltage-controlled oscillator₂；

Power push K_VDD＝(f₂-f₁)/(VDD₂-VDD₁)。

Bias supply voltage V for power supply push compensation circuit_BIAS3M times of adjustment is carried out, M power supply push presses K can be obtained_VDDOne power supply push K with the smallest absolute value_VDDBias supply voltage V of the corresponding power supply push compensation circuit_BIAS3Bias supply voltage V as power supply push compensation circuit_BIAS3Preferred values are.

Claims (10)

1. An LC voltage-controlled oscillator comprises an LC oscillating circuit and a cross coupling active module, wherein the LC oscillating circuit comprises an inductor, a main capacitance diode circuit and a coarse tuning capacitor bank, the cross coupling active module, the inductor, the main capacitance diode circuit and the coarse tuning capacitor bank are coupled between two output ends of the voltage-controlled oscillator in parallel, and the LC oscillating circuit is characterized by comprising a power supply push compensation circuit, and the power supply push compensation circuit is coupled between the two output ends of the voltage-controlled oscillator in parallel.

2. The LC voltage controlled oscillator of claim 1, wherein the power supply push compensation circuit comprises at least one power supply push compensation unit circuit, the power supply push compensation unit circuit comprises a third diode, a fourth diode, a third capacitor, a fourth capacitor, a third resistor and a fourth resistor, an anode of the third diode and an anode of the fourth diode are connected with each other and connected with an input end of a bias voltage; the cathode of the third diode is connected with the first parallel coupling end of the power supply push compensation circuit through a third capacitor, and the cathode of the fourth diode is connected with the second parallel coupling end of the power supply push compensation circuit through a fourth capacitor; the first end of the third resistor is connected with the cathode of the third diode, and the first end of the fourth resistor is connected with the cathode of the fourth diode; the second end of the third resistor and the second end of the fourth resistor are connected with each other and connected with the input end of the power supply pushing compensation circuit bias power supply voltage.

3. The LC vco of claim 2, wherein the power supply droop compensation circuit comprises a plurality of said power supply droop compensation unit circuits connected in parallel.

4. The LC voltage controlled oscillator of claim 1, wherein the main varactor diode circuit comprises a first diode, a second diode, a first capacitor, a second capacitor, a first resistor and a second resistor, wherein an anode of the first diode and an anode of the second diode are connected to each other and connected to the voltage signal input terminal of the voltage controlled oscillator; the cathode of the first diode is connected with a first parallel coupling end of the main capacitance-variable diode circuit through a first capacitor, and the cathode of the second diode is connected with a second parallel coupling end of the main capacitance-variable diode circuit through a second capacitor; the first end of the first resistor is connected with the cathode of the first diode, and the first end of the second resistor is connected with the cathode of the second diode; the second end of the first resistor and the second end of the second resistor are connected with each other and connected with the input end of the bias supply voltage of the main capacitance diode.

5. The LC voltage controlled oscillator of claim 1, wherein the coarse tuning capacitor bank is a switchable capacitor array comprising a plurality of switchable capacitor cell circuits connected in parallel and a switching circuit comprising a switching signal input.

6. The LC voltage-controlled oscillator according to claim 5, wherein the switchable capacitor unit circuit comprises a switching tube, a fifth capacitor, a sixth capacitor, a fifth resistor and a sixth resistor, wherein a first end of the fifth capacitor is connected with a first end of the sixth capacitor through the switching tube, and a control end of the switching tube is connected with an input end of a control voltage; the second end of the fifth capacitor is connected with the first parallel coupling end of the coarse tuning capacitor bank, and the second end of the sixth capacitor is connected with the second parallel coupling end of the coarse tuning capacitor bank; the first end of the fifth resistor is connected with the first end of the fifth capacitor, and the first end of the sixth resistor is connected with the first end of the sixth capacitor; the second end of the fifth resistor and the second end of the sixth resistor are connected with each other and connected with the input end of the bias supply voltage in parallel.

7. The LC VCO as claimed in claim 6, wherein said switching signal input terminal inputs digital signals, said switching transistor is an MOS transistor, a gate of the MOS transistor is connected to said control voltage input terminal, a control voltage of the gate of the MOS transistor is controlled by said digital signals, the digital signals inputted from the switching signal input terminal enable the switchable capacitive unit circuit to be selectively connected to or disconnected from the LC tank circuit; and the switchable capacitance unit circuit is switched off to reduce the total capacitance of the LC oscillating circuit, so that the output frequency of the LC voltage-controlled oscillator is increased.

8. The LC voltage controlled oscillator of claim 1, wherein the cross-coupled active modules are NMOS and PMOS cross-pair transistor structures.

9. The LC voltage controlled oscillator of claim 2, wherein the bias voltage is divided by a supply voltage with a division ratio of a; the bias power supply voltage of the power supply push compensation circuit is divided by the power supply voltage, and the voltage division ratio is B; b > A.

10. The LC voltage controlled oscillator of claim 2, wherein the power supply push compensation circuit is calibrated as follows:

1001) setting the number of times of bias power supply voltage adjustment of the power supply push compensation circuit as M;

1002) adjusting the bias supply voltage of the power supply push compensation circuit, and calculating the power supply push K of the LC voltage-controlled oscillator once every time the bias supply voltage of the power supply push compensation circuit is adjusted_VDDCalculating the power supply push K_VDDThe process of (2) is as follows;

setting power supply voltage VDD to VDD₁Obtaining the output frequency f of the LC voltage-controlled oscillator₁；

Setting power supply voltage VDD to VDD₂Obtaining the output frequency f of the LC voltage-controlled oscillator₂；

Power push K_VDD＝(f₂-f₁)/(VDD₂-VDD₁)；

1003) The bias supply voltage of the power supply push compensation circuit is adjusted for M times to obtain M power supply push values, wherein the bias supply voltage corresponding to the power supply push value with the smallest absolute value is used as the preferred value of the bias supply voltage of the power supply push compensation circuit.

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