METHOD AND CIRCUIT FOR MATCHING IMPEDANCE AND REGULATING VOLTAGE ACROSS A LOW VOLTAGE DEVICE

Abstract

A circuit for matching impedance and regulating a voltage of a high radio frequency line across a low voltage device that includes a differential input port, the high radio frequency lines, an internally routed line, a singled ended peak detection circuit, and a single-ended programmable variable impedance using a single-ended programmable variable impedance. The differential input port receives a differential high radio frequency signal using driver buffers. The internally routed line boosts the received differential high-frequency RF signal. The single-ended peak detection circuit detects peak voltages of the differential high-frequency RF signal. Depending on the peak value obtained at the output of the single-ended peak detection circuit, the single-ended programmable variable impedance that matches the impedance of each of high radio frequency lines and regulates the voltage of high radio frequency lines across said low voltage device to a pre-defined voltage.

Claims

1. A circuit for matching impedance and regulating a voltage of high radio frequency lines across a low voltage device using a single-ended programmable variable impedance by varying impedance of each of high radio frequency lines, said circuit comprising: a differential input port that comprises a plurality of driver buffers to receive a differential high-frequency Radio Frequency (RF) signal on said high radio frequency lines, wherein said high radio frequency lines comprise a positive line and a negative line; an internally routed line that boosts said differential high-frequency RF signal received on said high radio frequency lines, wherein said internally routed line is modelled as an LC circuit; a single-ended peak detection circuit that is configured to detect and measure peak voltages of boosted differential high-frequency RF signal on said positive line and said negative line; and a single-ended programmable variable impedance that is configured to match said impedance of said voltage of high radio frequency lines and regulate said voltage of high radio frequency lines across said low voltage device, wherein said impedance of said voltage of high radio frequency lines is matched by adjusting said impedance of said single-ended programmable variable impedance, wherein said voltage of high radio frequency lines across said low voltage device is regulated by changing at least one of a quality factor of said internally routed line or resonant frequency of said each of high radio frequency lines for regulating said voltage of said differential high-frequency RF signal to a pre-defined threshold voltage.

2. The circuit of claim 1, wherein said single-ended programmable variable impedance is configured to match an impedance between said positive line and said negative line across said low voltage device, wherein said impedance is matched between said positive line and said negative line by adjusting said impedance of said single-ended programmable variable impedance; and change at least one of variable resistance or variable capacitance of said single-ended programmable variable impedance to regulate said voltage of said differential high-frequency RF signal to said pre-defined threshold voltage.

3. The circuit of claim 1, wherein said single-ended programmable variable impedance is configured to remove said impedance mismatch between said positive line and said negative line of said high radio frequency line by adjusting said impedance of said single-ended programmable variable impedance based on a peak voltage difference between an output of said single-ended peak detection circuit of said positive line and said negative line.

4. The circuit of claim 1, wherein said single-ended programmable variable impedance comprises a variable resistance in series with a variable capacitance.

5. The circuit of claim 1, wherein said internally routed line comprises an inductor that models an inductance of said high radio frequency lines; and a capacitor that models a capacitance of said high radio frequency lines.

6. The circuit of claim 1, wherein said single-ended programmable variable impedance regulates said voltage of said differential high-frequency RF signal to said predefined threshold voltage based on said peak voltage measured at said output of said single-ended peak detection circuit.

7. The circuit of claim 1, wherein said single-ended programmable variable impedance is placed in series with said high radio frequency lines, wherein said regulated voltage is applied to said low voltage device.

8. A method for matching impedance and regulating a voltage of high radio frequency lines across a low voltage device using a single-ended programmable variable impedance by varying impedance of each of high radio frequency lines, wherein said method comprises: receiving, using a differential input port which comprises a plurality of driver buffers, a differential high-frequency Radio Frequency (RF) signal; modelling, using an internally routed line, said received differential high-frequency RF signal on said high radio frequency lines; boosting, using an internally routed line, said received differential high-frequency RF signal on said high radio frequency lines; detecting, using a singled ended peak detection circuit, peak voltages of said boosted differential high-frequency RF signal on a positive line and a negative line of said high radio frequency lines; measuring, using a single-ended peak detection circuit, said peak voltages of said boosted differential high-frequency radio frequency signal on each of said positive line and said negative line; matching, using a single-ended programmable variable impedance, said impedance of said voltage of high radio frequency lines; and regulating, using said single-ended programmable variable impedance, said voltage of high radio frequency lines across said low voltage device by changing at least one of a quality factor of said internally routed line or resonant frequency of said each of high radio frequency lines for regulating said voltage of said differential high-frequency RF signal to a pre-defined threshold voltage.

9. The method of claim 8, wherein said method comprises: matching an impedance between said positive line and said negative line across a low voltage device, wherein said impedance is matched between said positive line and said negative line is matched by adjusting said impedance of said single-ended programmable variable impedance; changing at least one of variable resistance or variable capacitance of said single-ended programmable variable impedance to regulate said voltage of said differential high-frequency RF signal to said pre-defined threshold voltage; and accurately removing, using said single-ended programmable variable impedance, said impedance mismatch between said positive line and said negative line by adjusting an impedance of said single-ended programmable variable impedance based on a peak voltage difference between an output of said single-ended peak detection circuit of said positive line and said negative line.

10. The method of claim 8, wherein said method comprises adjusting, using said single-ended programmable variable impedance, said variable resistance, and said variable capacitance of said single-ended programmable variable impedance based on said peak voltage to regulate said voltage of said differential high-frequency RF signal to a pre-defined value.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] The embodiments herein will be better understood from the following detailed description with reference to the drawings, in which:

[0016] FIG. 1 illustrates a block diagram of a circuit for matching impedance and regulating a voltage of high radio frequency line across a low voltage device according to some embodiments herein;

[0017] FIG. 2 illustrates a circuit for matching impedance and regulating the voltage of the high radio frequency lines across the low voltage device according to some embodiments herein; and

[0018] FIG. 3 is a flow diagram that illustrates a method for matching impedance and regulating a voltage of high radio frequency lines across a low voltage device according to some embodiments herein.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0019] The embodiments herein and the various features and advantageous details thereof are explained more fully with reference to the non-limiting embodiments that are illustrated in the accompanying drawings and detailed in the following description. Descriptions of well-known components and processing techniques are omitted so as to not unnecessarily obscure the embodiments herein. The examples used herein are intended merely to facilitate an understanding of ways in which the embodiments herein may be practiced and to further enable those of skill in the art to practice the embodiments herein. Accordingly, the examples should not be construed as limiting the scope of the embodiments herein.

[0020] Various embodiments provide circuits and methods to regulate the voltage across a load resistor of a high radio frequency line of a radio frequency (RF) circuit. More particularly, the circuits and methods disclosed herein deal with the sensing and regulation of the voltage at the output port of the high radio frequency line to protect low voltage devices connected to a port. Also, to accurately remove the impedance mismatch between positive and negative lines of a differential long high radio frequency line.

[0021] As mentioned, there remains a need for a circuit and a method to match the impedance and regulate the voltage across a low voltage device driven by a long line carrying radio frequency signals in integrated circuits. Referring now to the drawings, and more particularly to FIGS. 1 through 3, where similar reference characters denote corresponding features consistently throughout the figures, there are shown preferred embodiments.

[0022] FIG. 1 illustrates a block diagram 100 of a circuit for matching impedance and regulating a voltage of high radio frequency lines across a low voltage device according to some embodiments herein. The block diagram 100 includes high radio frequency lines 102, a differential input port 104, an internally routed line 106, a singled ended peak detection circuit 108, and a single-ended programmable variable impedance 110. The high radio frequency lines 102 includes a positive line and a negative line. The high radio frequency lines 102 carries a differential high Radio Frequency (RF) signal on across the low voltage device. The differential input port 104 receives a differential high radio frequency signal using driver buffers. The received differential high-frequency radio signal on high radio frequency lines 102 is modeled using the internally routed line 106. The internally routed line 106 is used to boost the received differential high-frequency RF signal on the high radio frequency lines 102. The single-ended peak detection circuit 108 (i) detects peak voltages of the differential high-frequency RF signal on each positive line and negative line and (ii) generates an output that is equivalent to peak voltage of the differential high-frequency RF signal. In some embodiments, the single-ended peak detection circuit 108 (i) detects peak voltages of the differential high-frequency RF signal on each positive line and negative line individually. Depending on the peak voltage difference between the output of single-ended peak detection circuit 108 of the positive line and the negative line, the single-ended programmable variable impedance 110 performs impedance matching between the positive line and the negative line by adjusting an impedance of the single-ended programmable variable impedance 110. Depending on the peak voltage obtained at the output of the single-ended peak detection circuit 108, the single-ended programmable variable impedance 110 regulates the voltage of the differential high-frequency RF signal to a pre-defined voltage by changing at least one of a quality factor of the internally routed line 106 or resonant frequency of the high radio frequency lines 102 by changing at least one of the variable resistance or variable capacitance of the variable impedance.

[0023] In some embodiments, the low voltage devices connected with one or more high radio frequency lines that include one or more positive lines and one or more negatives lines for the high-frequency RF signal transmission. In some embodiments, each positive lines and negative lines of the high radio frequency lines 102 connected with the differential input port 104, the internally routed line 106, the single-ended peak detection circuit 108 and the single-ended programmable variable impedance 110, for removing the impedance mismatch between the positive line and the negative line of the high radio frequency line 102 and regulating the voltage of the high radio frequency lines. The single-ended programmable variable impedance 110 controls parameters associated with each of the high radio frequency line 102 individually or together to regulate the voltage of high frequency lines across the low voltage device. In some embodiments, the parameters associated with the high frequency lines 102 includes at least one of resistance, impedance, capacitance or inductance. The single-ended programmable variable impedance 110 includes at least one of variable resistance or variable capacitance. In some embodiments, the impedance of the single-ended programmable variable impedance 110 is adjusted to match the impedance between each of the high frequency lines 102 that includes at least one of the positive line or the negative line. The variable resistance and the variable capacitance are changed by the single-ended programmable variable impedance 110 to regulate the voltage of the differential high-frequency RF signal to the pre-defined threshold voltage.

[0024] FIG. 2 illustrates a circuit 200 for matching impedance and regulating the voltage of the high radio frequency lines 102 across the low voltage device using the single-ended programmable variable impedance 110 by varying impedance of each of high radio frequency lines 102 according to some embodiments herein. The circuit 200 includes the differential input port 104, the internally routed line 106, the single-ended peak detection circuit 108, and the single-ended programmable variable impedance 110. The high radio frequency lines 102 includes a positive line 202A and a negative line 202B. The differential input port 104 includes one or more driver buffers 204A-N that are connected at each of the positive line 202A and the negative line 202B of the high radio frequency lines 110. The high-frequency lines 102 carries a differential high Radio Frequency (RF) signal across the low voltage device. The positive line 202A and the negative line 202B receive the differential high-frequency RF signal a transmission line used for the communication. The received differential high-frequency RF signal is boosted using the internally routed line 106. In some embodiments, the internally routed line 106 includes an inductor and a capacitor. The internally routed line 106 boosts the received differential high-frequency RF signal. In some embodiments, the inductance of the high radio frequency lines 102 is modeled by the inductor. In some embodiments, line capacitance and input capacitances of the circuit 200 connecting to the high radio frequency lines 102 are modeled by the capacitor. The single-ended peak detection circuit 108 detects and measures peak voltages of the differential high-frequency RF signal on each of the positive line 202A and the negative line 202B. In some embodiments, the low voltage device may include devices with low voltage ratings at an input port of the low voltage device. In some embodiments, the voltage of the boosted high radio frequency signal may increase at the output port of the radio frequency line due to inductance and capacitance of the high radio frequency line when the frequency of the high radio frequency signal is close to a resonant frequency of the internally routed line 106.

[0025] The long differential line may cause impedance mismatch between positive and negative lines due to on-chip variations. Depending on the peak voltage difference between the positive line 202A and the negative line 202B, the single-ended programmable variable impedance 110 adjusts the impedance on at least one of the positive line 202A or the negative line 202B for impedance matching between positive line 202A and the negative line 202B when an impedance mismatch is identified between positive line 202A and the negative line 202B. Depending on the peak voltage obtained at the output of the single ended peak detection circuit 108, the single-ended programmable variable impedance 110 regulates the voltage of the differential high-frequency RF signal across the low voltage device to a pre-defined threshold voltage by changing at least one of a quality factor of the internally routed line 106 or resonant frequency of the high radio frequency lines 102 by changing at least one of variable resistance 206A-N or the variable capacitance 208A-N of the single-ended programmable variable impedance 110. In some embodiments, the single-ended programmable variable impedance 110 controls the quality factor of the circuit to regulate voltage from the differential input port 104 of the high radio frequency lines 102 to the output port of the high radio frequency lines 102.

[0026] In some embodiments, the output of the single-ended peak detection circuit 108 may include voltage variation between the pre-defined voltage and the voltage of the boosted differential high-frequency RF signal. In some embodiments, the single-ended programmable variable impedance 110 may be placed in series with the high radio frequency lines 102. The single-ended programmable variable impedance 110 includes a variable resistance 206A-N in series with a variable capacitance 208A-N.

[0027] In some embodiments, the single-ended programmable variable impedance 110 regulates the voltage of the differential high-frequency RF signal to a pre-defined value by adjusting the variable resistance (206A-N) and the variable capacitance (208A-N) of the single-ended programmable variable impedance 110 based on the peak voltage measured at the output of the single-ended peak detector circuit 108. In some embodiments, the single-ended programmable variable impedance 110 is configured to accurately remove the impedance mismatch between the positive line 202A and the negative line 202B of the high radio frequency lines 102 depending on the difference in the peak voltage obtained at the output of the single-ended peak detection circuit 108 on each of positive line (202A) and negative line 202B.

[0028] FIG. 3 is a flow diagram that illustrates a method for matching impedance and regulating a voltage of the high radio frequency lines 102 across a low voltage device according to some embodiments herein. At step 302, a differential high-frequency Radio Frequency (RF) signal is received using the differential input port 104. In some embodiments, the high radio frequency lines 102 carries the differential high Radio Frequency (RF) signal on across the low voltage device. At step 304, the received high-frequency RF signal is boosted on the high radio frequency lines 102 using the internally routed line 106. At step 306, peak voltages of the boosted differential high-frequency RF signal are detected on the positive line 202A and the negative line 202B of the high radio frequency line 102 using the single-ended peak detection circuit 108. At step 308, the peak voltages of the differential high-frequency radio frequency signal are measured on each of positive line 202A and the negative line 202B using the single-ended peak detection circuit 108. At step 310, a single-ended programmable variable impedance 110 accurately matches the impedance of the positive line 202A and the negative line 202B by adjusting the single-ended programmable variable impedance 110. At step 312, the voltage of the differential high-frequency RF signal regulates to a pre-defined threshold voltage using the single-ended programmable variable impedance 110.

[0029] The foregoing description of the specific embodiments will so fully reveal the general nature of the embodiments herein that others can, by applying current knowledge, readily modify and/or adapt for various applications such specific embodiments without departing from the generic concept, and, therefore, such adaptations and modifications should and are intended to be comprehended within the meaning and range of equivalents of the disclosed embodiments. It is to be understood that the phraseology or terminology employed herein is for the purpose of description and not of limitation. Therefore, while the embodiments herein have been described in terms of preferred embodiments, those skilled in the art will recognize that the embodiments herein may be practiced with modification within the spirit and scope of the appended claims.