KR100655454B1 - Current-starved ring oscillator of compensating the variation of supply voltage - Google Patents

Abstract

A current-starved ring oscillator for compensating the variation of a supply voltage is provided to maintain a constant output frequency by compensating the voltage variation, by changing a supply current in proportion to the variation of the supply voltage. In a current-starved ring oscillator compensates the variation of a supply voltage, a supply current generation part(210) supplies a constant current regardless of the variation of process and temperature and outputs a current varying in proportion to the variation of the supply voltage. A delay part(230) performs oscillation to generate a signal of a constant output frequency based on an output current of the supply current generation part, and the output frequency is constant even though the supply voltage is changed, by the current varying according to the variation of the supply voltage.

Description

CURRENT-STARVED RING OSCILLATOR OF COMPENSATING THE VARIATION OF SUPPLY VOLTAGE}

1 is an exemplary configuration diagram of a ring oscillator according to the prior art.

2 shows a circuit diagram of an inverting amplifier according to the prior art and an equivalent circuit thereof.

3 is an exemplary circuit diagram of a ring oscillator of current-starved structure according to the prior art.

4 is a schematic diagram of a current-stabbed ring oscillator compensating for power supply variations in accordance with the present invention.

5 is a configuration diagram of a supply current generator of a current-stabbed ring oscillator compensating for a supply power change according to the present invention.

6 is another configuration diagram of a supply current generator of a current-stabbed ring oscillator compensating for a supply power change according to the present invention.

<Description of the symbols for the main parts of the drawings>

110: reference current generating unit 120: current providing unit

130: delay unit 210: supply current generating unit

220: current providing unit 230: delay unit

310: voltage distribution unit 320: distribution voltage based current generation unit

325: operational amplifier 330: current mirror unit

340: reference current generator 350: supply voltage proportional current generator

360: current adder

The present invention relates to a current-stabbed ring oscillator for compensating supply power changes. More specifically, the current-stabilized ring oscillator improves the shortcomings in the variation of the output frequency in response to voltage changes. The present invention relates to a current-stabbed ring oscillator that compensates for power supply changes that can maintain a constant output frequency by changing the supply current in proportion to the change.

Ring oscillators have been widely used for measuring the delay time of a specific circuit because of the simplicity of design and the ease of measurement.

1 is an exemplary configuration diagram of a ring oscillator according to the prior art.

As shown, a ring oscillator according to the prior art is constructed by connecting an odd number (three or more) inverting amplifiers in a loop form.

In the ring oscillator shown in FIG. 1, a phase difference occurs between the input signal and the output signal by the load capacitors C _L1 to C _{L5 of the} respective inverting amplifiers I ₁ to I ₅ . This phase difference depends on the frequency of the input signal. When the input signal is circulated through the loop type inverting amplifiers I ₁ to I ₅ , the oscillation is performed at a frequency at which the phase difference is 180 degrees.

When the delay time of the inverting amplifiers I ₁ to I ₅ is Td and the number of the inverting amplifiers I ₁ to I ₅ used in the ring oscillator is N (N is odd), the ring oscillator oscillates. The oscillation frequency f _osc is expressed by the following equation.

f _osc = 1 / 2NT _d

According to Equation 1, the oscillation frequency f _osc of the ring oscillator may be variably adjusted according to the change of the delay time T _d of the inverting amplifiers I ₁ to I ₅ .

However, despite this simple operation principle and simplicity of design, the ring oscillator according to the prior art is very sensitive to the change in the manufacturing time, voltage change, temperature change (Process, Voltage, Temperature, PVT) and noise due to the delay time (T _d ). The disadvantage is that. Therefore, it is very sensitive to the change of PVT, and the change of the output frequency is very large even by a slight change, thereby limiting the application range of the ring oscillator.

2 is a circuit diagram of an inverting amplifier according to the related art and an equivalent circuit thereof. The delay time T _d of the inverting amplifier is determined by the RC delay time, and each parameter in calculating the RC delay time is as follows.

R is the ON resistance value after the PMOS (or NMOS may be used depending on the inverting amplifier configuration) is turned on in the inverting amplifier structure of FIG. 2, and the capacitance C is at the inverter output. It is the capacitance value, that is, the capacitance value of the load capacitor C _L.

In the structure of such an inverting amplifier, the supply voltage VDD has a variation within approximately 10%. In addition, it may have a variation range of 10% or more depending on the supply voltage VDD state. The ON resistance R changes according to the change in the supply voltage VDD, and thus the output frequency f _osc of the ring oscillator also changes.

Thus, ring oscillators can be used for voltage controlled oscillators (VCOs) or test patterns to check the state of the process in feedback systems such as phase locked loops (PLLs), Frequency generators or pulse generators that must output a constant frequency irrespective of the fluctuation have a disadvantage that they are not actually used because of instability due to a change in output frequency. That is, the conventional ring oscillator has a disadvantage in that it is not suitable as an oscillator circuit without a configuration for adjusting the input signal since the variation of the frequency output with respect to the PVT change is large.

3 is an exemplary circuit diagram of a ring oscillator of current-starved structure according to the prior art.

The reference current generator 110 supplies a constant current regardless of a process, voltage, or temperature (PVT) using, for example, a bandgap reference circuit, and the current generated by the reference current generator 110 is a current providing unit ( 120).

The current providing unit 120 provides a current to each inverting circuit of the delay unit 130 in a current mirror manner.

The delay unit 130 is composed of a plurality of delay cells 130a to 130x and generates an output Vout of the ring oscillator.

The current-stabbed structure described with reference to FIG. 3 is more controllable in the ring oscillator type described with reference to FIG. 1 and is insensitive to changes in temperature and process.

In other words, the current-stabilized oscillator maintains a constant supply current through the reference current generator 110 to supply a constant current to process changes and temperature changes than the ring oscillator circuit shown in FIG. The amount of change in the output frequency with respect to the change can be reduced. However, the disadvantage is that it is vulnerable to fluctuations in supply voltage.

In more detail, the output frequency of the current-stabbed oscillator is determined as the inverse of the delay time of the delay unit 130, and the delay time of the delay unit 130 is the amount of charge charged to the equivalent capacitance of the delay unit 130. It means charging time.

As is known, since the charge time of the charge has a property that is proportional to the voltage and inversely proportional to the current, the charge time of the charge may be expressed as in Equation 2 below.

t = CV / I

(t is the charge charging time in the delay section, C is the capacitance value in the delay section, V is the supply voltage, and I is the current supplied to the delay section.)

As can be seen from Equation 2, the charging time t is proportional to the capacitance C and the supply voltage V and inversely proportional to the supply current I. In the current-stabbed ring oscillator structure of FIG. The capacitance C and the supply current I are configured to have a constant value. Therefore, as the supply voltage V increases or decreases, the charging time changes in proportion.

Since the charge time is inversely related to the output frequency of the current-stabbed ring oscillator, increasing the supply voltage (V) increases the charge time, which results in a decrease in the current-stabbed ring oscillator output frequency. In addition, decreasing supply voltage (V) reduces charging time, which results in an increase in the current-stabbed ring oscillator output frequency.

Table 1 summarizes the output frequency variation of the current-stabbed ring oscillator according to PVT (Process, Voltage, Temperature). The output frequency in Table 1 is a result of assuming that the reference current generator 110 supplies a constant current regardless of the PVT change and the reference output frequency is 50 MHz.

Voltage (V) Output frequency (MHz) Temperature (° C) Output frequency (MHz) fair Output frequency (MHz) 1.65 53.7 -25 52.21 A 51.05 1.80 51.05 25 51.05 B 51.16 1.95 48.3 85 50.1 C 49.97 % Change -5.35 ~ 5.2 % Change -1.86 ~ 2.27 % Change -2.5 to 0.2

As can be seen from Table 1, for example, when a constant current is supplied to PVT using a bandgap reference circuit, the output frequency can be canceled according to temperature and process changes. Will be affected. Therefore, the current-stabbed ring oscillator is sensitive to supply voltage characteristics, so there is a limit in configuring a circuit for mass production.

In order to solve these disadvantages of current-stabbed ring oscillators, a method of using a voltage clamping circuit or a voltage rectifier has been proposed so as not to change the supply voltage. However, this method also lowers the supply voltage to bring the ring oscillator to a voltage lower than the supply voltage. This has the disadvantage of lowering the voltage margin since it must be driven.

Summary of the Invention An object of the present invention is to improve the shortcoming of the change in the output frequency according to the voltage change in a current-stabbed ring oscillator, thereby compensating the voltage change by changing the supply current in proportion to the power supply change, thereby providing a constant output frequency. It is to provide a current-stabilized ring oscillator that compensates for sustained supply power variations.

In order to achieve the above technical problem, the present invention is a current-stabilized ring oscillator for compensating the power supply change, which outputs a constant current regardless of the process and temperature changes, but outputs a current that changes in proportion to the supply voltage change An oscillation that generates a signal having a constant output frequency based on a supply current generator and an output current of the supply current generator, and the output frequency is changed by the current that changes according to the supply voltage change. A current-stabilized ring oscillator is provided to compensate for supply power variations including delays configured to be constant.

In the current-stabbed ring oscillator for compensating the supply power change according to the present invention, the supply current generating unit, the reference current generating unit for outputting a constant current regardless of the process and the temperature and the supply voltage change, and A supply voltage proportional current generator for outputting a constant current regardless of the process and the temperature change and outputs a current that changes in proportion to the supply voltage change, and the current of the reference current generator and the supply voltage proportional current generator In addition, it may include a current summing unit for outputting a constant current irrespective of the process and the temperature change, but outputs a current that changes in proportion to the supply voltage change.

In addition, the current-stabilized ring oscillator for compensating for the power supply change in accordance with the present invention, it may further include a current providing unit for providing the output current of the supply current generating unit in the current-mirror form in the delay unit.

Further, in the current-stabbed ring oscillator for compensating the supply power change according to the present invention, the supply current generating unit, the voltage distribution unit for allocating the supply voltage and the current based on the voltage distributed by the voltage distribution unit A distribution voltage based current generating unit generating a and a current mirror unit for outputting a current generated by the distribution voltage based current generating unit.

In addition, in the current-stabbed ring oscillator for compensating the supply power change according to the present invention, the voltage divider includes two resistors connected in series with the supply voltage and ground, and among the two resistors to the supply voltage. Preferably, the magnitude of the connected resistor is greater than the resistor connected to the ground.

In addition, in the current-stabbed ring oscillator for compensating for the supply power change according to the present invention, the distributed voltage based current generator includes the voltage distributed to both terminals and the voltage of a node necessary for determining the current of the distributed voltage based current generator. The input voltage is equal to the voltage distributed at the node for determining the current and the voltage of the node, the resistor connected to the node for determining the current, the gate is connected to the output of the operational amplifier and the current mirror unit The MOS may include a MOS connected to a drain and a source connected to a resistor connected to a node required for determining the current.

In addition, in the current-stabbed ring oscillator for compensating supply power change according to the present invention, the current mirror unit, the first MOS is connected to the source and the gate of the output of the distributed voltage-based current generator, the drain is connected to the supply voltage And a second MOS having a gate connected to the gate of the first MOS, a drain connected to the supply voltage, and outputting a current having a value equal to a current generated by the distributed voltage based current generator at a source. have.

Further, in the current-stabbed ring oscillator for compensating for the supply power change according to the present invention, the supply voltage proportional current generator is based on a voltage distribution unit for allocating the supply voltage and a voltage distributed by the voltage distribution unit. A distribution voltage based current generating unit generating a furnace current and a current mirror unit outputting a current generated by the distribution voltage based current generating unit may be included.

In addition, in the current-stabbed ring oscillator for compensating the supply power change according to the present invention, the voltage divider includes two resistors connected in series with the supply voltage and ground, and among the two resistors to the supply voltage. Preferably, the magnitude of the connected resistor is greater than the resistor connected to the ground.

In addition, in the current-stabbed ring oscillator for compensating for the supply power change according to the present invention, the distributed voltage based current generator includes the voltage distributed to both terminals and the voltage of a node necessary for determining the current of the distributed voltage based current generator. The input voltage is equal to the voltage distributed at the node for determining the current and the voltage of the node, the resistor connected to the node for determining the current, the gate is connected to the output of the operational amplifier and the current mirror unit The MOS may include a MOS connected to a drain and a source connected to a resistor connected to a node required for determining the current.

In addition, in the current-stabbed ring oscillator for compensating supply power change according to the present invention, the current mirror unit, the first MOS is connected to the source and the gate of the output of the distributed voltage-based current generator, the drain is connected to the supply voltage And a second MOS having a gate connected to the gate of the first MOS, a drain connected to the supply voltage, and outputting a current having a value equal to a current generated by the distributed voltage based current generator at a source. have.

Hereinafter, a current-stabbed ring oscillator compensating for power supply variations of the present invention will be described in more detail with reference to the accompanying drawings.

4 is a schematic diagram of a current-stabbed ring oscillator compensating for power supply variations according to the present invention.

As shown, the current-stabbed ring oscillator compensating for the power supply change according to the present invention includes a supply current generator 210 and a delay unit 230. In addition, the current providing unit 220 may further include.

The supply current generator 210 outputs a constant current regardless of process and temperature changes, but outputs a current that changes in proportion to a supply voltage change. The difference from the reference current generator 110 described with reference to FIG. 3 is that the reference current generator 110 supplies a constant current irrespective of PVT, while the supply current generator 210 is output according to a change in supply voltage. The current also changes proportionally.

The delay unit 230 generates an oscillation that generates a signal having a constant output frequency based on the output current of the supply current generator 210, and even if the output voltage changes due to a current that changes according to a supply voltage change. Configured to be constant.

That is, in the current-stabbed ring oscillator of the related art, in order to prevent the change in the output frequency due to the change in the delay time according to the change in the supply voltage, even if the supply voltage changes, the current changes in proportion to the charging time of the delay unit 230. It is configured to maintain a constant output frequency by compensating for the change in the supply voltage by maintaining a.

The current-stabbed ring oscillator compensating for the supply power change according to the present invention may further include a current providing unit 220.

The current provider 220 provides the output current of the supply current generator 210 to the delay unit 230 in a current-mirror format. Since the current providing unit 220 is the same as the conventional current providing unit 120 described with reference to FIG. 3, a detailed description thereof will be omitted.

5 is a configuration diagram of a supply current generator of a current-stabbed ring oscillator compensating for a supply power change according to the present invention.

As shown, the supply current generator 210 includes a voltage divider 310, a distributed voltage based current generator 320, and a current mirror unit 330.

The voltage divider 310 distributes the supply voltage. As shown, the voltage distribution unit 210 includes two resistors R1 and R2 connected in series to the supply voltage Vdd and the ground Vss, and the resistor R1 connected to the supply voltage Vdd among the two resistors. ) Is preferably larger than the resistor R2 connected to the ground Vss.

The distribution voltage based current generator 320 generates a current based on the voltage distributed by the voltage distribution unit 310. As shown, the distributed voltage based current generator 320 has a voltage Va distributed by the voltage distributor 310 at both terminals and a node B necessary for determining current of the distributed voltage based current generator 320. The voltage Vb is input, and the allocated voltage Va and the voltage Vb of the node B required for the current determination of the distributed voltage base current generator 320 are the same, and the operational amplifier 325 is allocated. A resistor R3 connected to the node B necessary for determining the current of the voltage based current generator 320, a gate is connected to the output of the operational amplifier 325, and a drain is connected to the current mirror unit 330. And a MOS M1 to which a source is connected to R3.

The current mirror unit 330 outputs a current generated by the distribution voltage based current generator 320. As shown, the current mirror unit 330 may include a first MOS MP1 having a source and a gate connected to an output of the distribution voltage based current generator 320, and a drain connected to a supply voltage, and the first MOS MP1. And a second MOS (MP2) for outputting a current having a value equal to a current generated by the distributed voltage based current generator at a source, a gate connected to a gate of the gate, a drain connected to the supply voltage, and a source.

Referring to Figure 5 will be described in more detail the supply current generator of the current-stabilized ring oscillator compensating for the power supply change according to the present invention.

The voltage of the node A, that is, the divided voltage Va is determined by the ratio of the two resistors R1 and R2 of the voltage divider 310. Since the divided voltage Va is determined by the ratio of the two resistors R1 and R2, the voltage is determined only by the change in the supply voltage regardless of the process change or the temperature change. In addition, the resistor R1 has a larger resistance value than the resistor R2, and thus may reduce the current flowing through the resistor R3.

Meanwhile, the negative feedback operation of the associating amplifier 325 causes the voltage Vb of the node B to be equal to the divided voltage Va.

Therefore, the current flowing through the resistor R3 becomes Va / R3. This current is output to Iout by a current mirror composed of one MOS MP1 and a second MOS MP2.

 In the supply current generator circuit, the operational amplifier 325 keeps the voltage Va and the voltage Vb always equal as long as the gain is higher than a predetermined level with respect to a process or temperature change, and the MOS M1 is maintained. In order to flow the current generated in R3, the gate-source voltage (Vgs) is changed in response to its process and temperature change, thereby keeping the current flowing in R3 constant.

The supply current generator circuit is simpler than the conventional band gap reference circuit, and the supply current generator can be implemented without using the diode process used for the band gap, which is efficient in terms of high integration and reduced manufacturing cost.

6 is another configuration diagram of a supply current generator of a current-stabbed ring oscillator compensating for a supply power change according to the present invention.

As shown, the supply current generating unit 210 ′ outputs a constant current regardless of the process and the temperature and the supply voltage change, and a constant current regardless of the process and temperature change. Process and temperature change by adding the current of the supply voltage proportional current generator 350, which outputs a current that is proportionally changed in accordance with the supply voltage, the reference current generator 340 and the supply voltage proportional current generator 350 It includes a current summing unit 360 for outputting a constant current irrespective of, but outputs a current that changes in proportion to the supply voltage change.

The supply current generator 210 ′ shown in FIG. 6 adds a supply voltage proportional current generator 350 to a reference current generator 340 that outputs a constant current regardless of a conventional PVT change, thereby designing a conventional circuit. Is used as it is, and the supply voltage proportional current generator 350 is similar to the power supply generator 210 described with reference to FIG. 5, the voltage divider 310 and the divided voltage based current generator 320. And, it may be implemented to include the current mirror unit 330.

Although the present invention has been described in detail, this is for illustrative purposes only, and the protection scope of the present invention is not limited thereto, and the protection scope of the present invention is defined through the description of the claims.

As described above, according to the present invention, in the conventional current-stabbed ring oscillator, the shortcoming of the change in output frequency is widened according to the voltage change, thereby compensating the voltage change by changing the supply current in proportion to the power supply change. It can maintain a constant output frequency.

Claims (11)

A current-stabbed ring oscillator that compensates for power supply variations A supply current generator for outputting a constant current regardless of process and temperature changes, but outputs a current that changes in proportion to a supply voltage change; A delay unit configured to generate a signal having a constant output frequency based on the output current of the supply current generating unit, and wherein the output frequency is constant even if the supply voltage changes due to a current that changes according to the supply voltage change A current-stabbed ring oscillator for compensating for power supply changes, including. The method of claim 1, The supply current generator, A reference current generator for outputting a constant current regardless of the process, the temperature, and the supply voltage change; A supply voltage proportional current generator for outputting a constant current irrespective of the process and the temperature change and outputting a current that changes in proportion to the supply voltage change; A current adder for adding a current of the reference current generator and the supply voltage proportional current generator to output a constant current regardless of the process and the temperature change, but outputting a current that changes in proportion to the supply voltage change. The current-stabilized ring oscillator to compensate for the power supply change that includes. The method according to claim 1 or 2, A current providing unit providing an output current of the supply current generating unit to the delay unit in a current-mirror format A current-stabbed ring oscillator for compensating for a supply power change further comprising. The method of claim 1, The supply current generator, A voltage distribution unit for allocating the supply voltage; A distribution voltage based current generation unit generating current based on the voltage distributed by the voltage distribution unit; Current mirror unit for outputting the current generated by the distribution voltage based current generator The current-stabilized ring oscillator to compensate for the power supply change that includes. The method of claim 4, wherein The voltage distribution unit, Two resistors connected in series with the supply voltage and ground; A current-stabbed ring oscillator for compensating for power supply variations, wherein a magnitude of a resistor connected to the supply voltage of the two resistors is greater than a resistor connected to the ground. The method of claim 4, wherein The distributed voltage based current generator, An operational amplifier having input voltages at both terminals and voltages of nodes required for current determination of the distributed voltage base current generator, wherein the distributed voltages and voltages of nodes required for current determination are the same; A resistor connected to the node for determining the current; A MOS having a gate connected to the output of the operational amplifier, a drain connected to the current mirror, and a source connected to a resistor connected to a node necessary for determining the current; The current-stabilized ring oscillator to compensate for the power supply change that includes. The method of claim 4, wherein The current mirror unit, A first MOS having a source and a gate connected to an output of the distributed voltage based current generator and a drain connected to a supply voltage; A second MOS having a gate connected to the gate of the first MOS, a drain connected to the supply voltage, and outputting a current having a value equal to a current generated by the distributed voltage based current generator at a source; The current-stabilized ring oscillator to compensate for the power supply change that includes. The method of claim 2, The supply voltage proportional current generator, A voltage distribution unit for allocating the supply voltage; A distribution voltage based current generation unit generating current based on the voltage distributed by the voltage distribution unit; Current mirror unit for outputting the current generated by the distribution voltage based current generator The current-stabilized ring oscillator to compensate for the power supply change that includes. The method of claim 8, The voltage distribution unit, Two resistors connected in series with the supply voltage and ground; A current-stabbed ring oscillator for compensating for power supply variations, wherein a magnitude of a resistor connected to the supply voltage of the two resistors is greater than a resistor connected to the ground. The method of claim 8, The distributed voltage based current generator, An operational amplifier having input voltages at both terminals and voltages of nodes required for current determination of the distributed voltage base current generator, wherein the distributed voltages and voltages of nodes required for current determination are the same; A resistor connected to the node for determining the current; A MOS having a gate connected to the output of the operational amplifier, a drain connected to the current mirror, and a source connected to a resistor connected to a node necessary for determining the current; The current-stabilized ring oscillator to compensate for the power supply change that includes. The method of claim 8, The current mirror unit, A first MOS having a source and a gate connected to an output of the distributed voltage based current generator and a drain connected to a supply voltage; A second MOS having a gate connected to the gate of the first MOS, a drain connected to the supply voltage, and outputting a current having a value equal to a current generated by the distributed voltage based current generator at a source; The current-stabilized ring oscillator to compensate for the power supply change that includes.

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