The present invention relates to clock receiver designs. Clock receivers can be used in high speed digital to analog converters, analog to digital converters, and clock distribution circuits which, in turn, are provided in integrated circuits. These high speed components typically operate in about the 1-5 GHz frequency range but can operate as low as 100 MHz. Performance of CMOS clock receivers can be severely impacted by duty cycle errors and cross point errors, which cause interference in the receiver such as phase noise, jitter, and frequency limit problems. Embodiments of the present invention address solutions to reduce duty cycle errors and cross point errors in CMOS clock receivers.
High speed clocked circuit systems often are driven by externally supplied clock systems. When circuit systems operate at clock speeds of 100 MHz-5 GHz or more, input clock signals usually are not provided as conventional square wave signals. Instead, the input clock signals often are differential signals that approximate sinusoids much closer than square waves. They often are “small swing” signals, having signal amplitudes that are smaller than the voltage sources (VDD) present within the circuit systems. Moreover, the input clock signals cannot be guaranteed to have a 50% duty cycle; instead, the two phases Φ1 and Φ2 of a clock signal have different durations.
Designers of high speed circuit systems face other challenges from the sinusoidal clock inputs. For example, some circuit systems require a full swing CMOS square wave with controlled cross points. A clock generator must convert a differential sinusoid signal to a rail-to-rail CMOS clock signal with controllable cross points, regardless of the cross points that are presented in the differential clock signal.
Accordingly, the inventors have identified a need in the art for a clock generator system that can manage duty cycles of a differential input clock and correct for asymmetry in such duty cycles. Moreover, the inventors have identified a need in the art for a clock generator that can detect and manage cross points of a differential input clock and correct such cross points when they deviate from ideal levels.
a is a simplified diagram of a duty cycle error detector according to an embodiment.
b is a simplified diagram of a duty cycle error detector according to an embodiment.
Embodiments of the present system provide a system for correcting duty cycle errors in a clock receiver that may include a differential amplifier that may inputs for a pair of differential clock signals. A duty cycle error detector may have inputs for a pair of amplified clock signals and an output for a duty cycle error correction signal. A signal conditioner may also be provided with the differential amplifier having an input for the duty cycle error correction signal. Furthermore, the signal conditioner may adjust the differential clock signals in response to the duty cycle error correction signal.
Embodiments of the present system also provide a system for correcting cross point errors in a clock receiver that includes a differential amplifier that may have inputs for a pair of differential clock signal. A cross point error detector may have inputs for a pair of amplified clock signals and an output for a cross point error correction signal. A signal conditioner may also be provided with the differential amplifier having an input for the cross point error correction signal. Furthermore, the signal conditioner may adjust the differential clock signals in response to the cross point error correction signal.
A duty cycle correction feedback loop may be included in the clock receiver 300. A duty cycle error detector 370 may have inputs for the differential clock outputs. The duty cycle error detector 370 may detect an imbalance between the two phases of the differential clock signals and generate a duty cycle error correction signal ΔDC therefrom. The duty cycle error detector 370 may further have an output for the duty cycle error correction signal ΔDC that is coupled to signal conditioner 310 to adjust the two current sources 320, 330 in equal but opposite amounts.
According to an embodiment, a clock receiver 400 of
The duty cycle error detector may be implemented as an integrator of various types.
The differential clock outputs may be inserted into a duty cycle error feedback loop and inputted into a duty cycle error detector according to the present invention. The duty cycle detector may detect errors in the differential output signals' duty cycles. In this example, duty cycle φ1 for outp is shorter than the ideal 50% duty cycle while duty cycle φ2 for outn is longer than the ideal 50% duty cycle. From the errors detected, the duty cycle error detector may generate a duty cycle correction signal ΔDC as shown in
The signal conditioner, responsive to ΔDC, may adjust the voltages/currents for differential clock signals accordingly. In this example, the clock signal inp may be adjusted with a positive offset +ΔDC, and the clock signal inn may be adjusted with a negative offset −ΔDC, where both offsets are the same amount. The adjusted clock signals may be processed by the clock receiver and may be inserted into the duty cycle error feedback loop to check for duty cycle errors. The inputs to the duty cycle error detector in this iteration are illustrated in
The signal conditioner that is responsive to ΔDC may be located in any part of the clock receiver. According to an embodiment, a clock receiver 1000 of
A duty cycle error correction feedback loop may be included in the clock receiver 1000. A duty cycle detector 1070 may have inputs for the differential clock outputs. The duty cycle error detector may detect an imbalance between the two phases of the differential clock signals and generate a duty cycle error correction signal ΔDC therefrom. The duty cycle error detector 1070 may further have an output for the duty cycle error correction signal ΔDC that is coupled to signal conditioner 1020 to adjust the two current sources 1030, 1040 in equal but opposite amounts.
According to an embodiment, a clock receiver 1100 of
A duty cycle error correction feedback loop may be included in the clock receiver 1100. A duty cycle detector 1180 may have inputs for the differential clock outputs. The duty cycle error detector may detect an imbalance between the two phases of the differential clock signals and generate a duty cycle error correction signal ΔDC therefrom. The duty cycle error detector 1180 may further have an output for the duty cycle error correction signal ΔDC that is coupled to signal conditioner 1120 to adjust the two current sources 1130, 1140 in equal but opposite amounts.
A cross point correction feedback loop may be included in the clock receiver 1200. A cross point error detector 1280 may have inputs for the differential clock outputs. The cross point detector 1280 may detect the cross points of the two differential clock signals and may send the detection result to an integrator 1290. The integrator 1290 may generate a cross point error correction signal ΔCP therefrom. The integrator may further have an output for ΔCP that is coupled to signal conditioner 1220 to adjust the two current sources 1230, 1240 in equal amounts with the same polarity.
According to an embodiment, a clock receiver 1300 of
Since PMOS type transistors only conduct when the gate input is low and NMOS type transistors only conduct when the gate input is high, the cross point error detector 1400 may not conduct at most times because the differential clock signals controlling the transistors are usually in a high or low state in opposite relations to each other. However, when the differential clock signals are in their transition region, where neither differential clock signal is either high or low, all transistors may conduct at this time. The transition region also contains the cross points of the two differential clock signals. Therefore, the Detector Output current of
The size ratio of the transistors may also define the ideal cross point. For example, PMOS widths may be set wider than NMOS windows resulting in the ideal cross point to be higher than actual cross point because the NMOS transistors would require larger gate voltages to compensate for the narrower window size in order to conduct the same current as the PMOS transistors. Conversely, NMOS widths may be set wider than PMOS windows resulting in the ideal cross point to be lower than the actual cross point. When the Detector Output current of the cross point detector equals zero, the loop stabilizes indicating that the actual cross point is at the ideal cross point.
Cross point error detector 1400 is shown with PMOS type transistors and NMOS type transistors; however, any complimentary transistor types may be used. Also, cross point error detector 1400 is shown with 8 transistors; however, other numbers of transistors may be used. For example, only half of cross point error detector with PMOS transistors 1410, 1420 and NMOS transistors 1450, 1460 with the same configuration as shown in
The differential clock outputs may be inserted into a cross point error feedback loop and inputted into a cross point error detector according to the present invention. The cross point detector may detect the cross point of the two differential clock outputs, and the cross point's relation to the ideal cross point. In this example, the actual cross point is lower than the ideal cross point. The cross point error detector and integrator may calculate a cross point error correction signal ΔCP as shown in
The signal conditioner, responsive to ΔCP, may adjust the voltages/currents for differential clock signals accordingly. In this example, both clock signals are adjusted in the positive direction in the same amount. The adjusted clock signals may be processed by the clock receiver and may then be inserted into the cross point error feedback loop to check for the cross point location. The inputs to the cross point error detector in this iteration are illustrated in
According to an embodiment, the clock receiver 1900 of
A cross point correction feedback loop may be included in the clock receiver 1900. Cross point detectors 1940 may detect the cross point of the differential clock signals before the last inverters 1931, 1936 of the inverter stages 1930, 1935 respectively while cross point detector 21945 may detect the cross point of the differential clock signals after the inverter stages 1930, 1935. The output currents of the cross point detectors 1940, 1945 may be subtracted from each other by current subtractor 1950. Since the amplitude of the cross point detector output currents depend on the cross point deviation, the subtraction result may represent the imbalance of the cross points before and after the last inverter of the inverter stages. If the subtraction result is zero, it may indicate that the cross point before and after the last inverter of the inverter stage are the same. The subtraction result may then be inputted to an integrator 1960 to generate a cross point error correction signal ΔCP therefrom. The integrator may further have an output for ΔCP that is coupled to signal conditioner 1920 to adjust the two current sources 1930, 1940 in equal amounts with the same polarity.
Since duty cycle errors and cross point errors are not mutually exclusive and both may cause distortion in the same clock receiver, both duty cycle error correction and cross point error correction may be needed in a clock receiver. Therefore, a clock receiver may include both a duty cycle error correction feedback loop and a cross point error correction feedback loop. According to an embodiment, clock receiver 2000 of
A duty cycle error correction feedback loop and a cross point correction feedback loop may be included in the clock receiver 2000. A duty cycle error detector 2060 may have inputs for the differential clock outputs. The duty cycle error detector 2060 may detect imbalance between the two phases of the differential clock signals and generate a duty cycle error correction signal ΔDC therefrom. The duty cycle error detector may further have an output for the duty cycle error correction signal ΔDC that is coupled to signal conditioner 2020 to adjust the two current sources 2021, 2022 in an equal amount but opposite polarity.
A cross point error detector 2040 may also have inputs for the differential clock outputs. The cross point detector 2040 may detect the cross points of the two differential clock signals and may send the detection result to an integrator 2050. The integrator 2050 may generate a cross point error correction signal ΔCP therefrom. The integrator may further have an output for ΔCP that is coupled to signal conditioner 2020 to adjust the two current sources 2021, 2022 in equal amounts with the same polarity.
In this embodiment, signal conditioner 2020 may be shared by both feedback loops; however, each feedback loop may have its own signal conditioner device. A duty cycle signal conditioner may be located in any part of the circuit while a cross point signal conditioner may not be placed before any differential amplifiers and may not be placed after single-ended inverters. If a signal conditioner is shared by both feedback loops, the shared signal conditioner's location may be limited by cross point signal conditioner location restrictions. Also, any duty cycle error correction embodiment of the present invention may be used in conjunction with any cross point error correction embodiment of the present invention. Moreover, both feedback loops may work independently of each other.
It should be understood that the present invention may be utilized in other applications such as signal level shifting of various signal types. These signals may include PECL, LVDS, CML, and pseudo-nmos signals. It should be also understood that the present invention may be operable on range of frequency spectrums such as 100 MHz-5 GHz and above 5 GHz. Several embodiments of the present invention are specifically illustrated and described herein. However, it will be appreciated that modifications and variations of the present invention are covered by the above teachings and within the purview of the appended claims without departing from the spirit and intended scope of the invention.