BIAS CURRENT WITH HYBRID TEMPERATURE PROFILE

Information

  • Patent Application
  • 20240045455
  • Publication Number
    20240045455
  • Date Filed
    August 22, 2023
    9 months ago
  • Date Published
    February 08, 2024
    3 months ago
  • Inventors
    • WRENNER; Kevin R. (Essex Junction, VT, US)
    • YUN; Ruida (Weston, MA, US)
    • RICHARDSON; Kenneth G. (Longmont, CO, US)
  • Original Assignees
Abstract
Aspects of the present disclosure include a scalable proportional to absolute temperature (PTAT) hybrid circuit, comprising a bias mirror circuit configured to provide a zero temperature coefficient (ZTC) current, a PTAT control circuit configured to generate, based on the ZTC current, a PTAT current with a slope having a non-zero value, alter the PTAT current by at least scaling the PTAT current or changing the slope of the PTAT current to generate an altered PTAT current, and provide the altered PTAT current, a hybrid circuit configured to receive the ZTC current and the altered PTAT current, and output a larger current of the ZTC current and the altered PTAT current as a hybrid current.
Description
BACKGROUND

Integrated circuits (ICs) are commonly designed with a zero temperature coefficient (ZTC) bias scheme or a positive temperature coefficient (PTC) bias scheme (also known as proportional to absolute temperature (PTAT) bias). A ZTC bias circuit is a circuit that provides a bias current that is substantially invariant to temperature changes. A PTC bias circuit is a circuit that provides a bias current that changes proportionally with temperature. However, a ZTC bias circuit may be unable to provide sufficient current and/or gain above a certain temperature. Similarly, a PTC bias circuit, while able to provide sufficient current and/or gain above a certain temperature, may be unable to provide sufficient current and/or gain below a certain temperature.


Thus, improvements in such bias circuits are desired.


SUMMARY

The following presents a simplified summary of one or more aspects in order to provide a basic understanding of such aspects. This summary is not an extensive overview of all contemplated aspects, and is intended to neither identify key or critical elements of all aspects nor delineate the scope of any or all aspects. Its sole purpose is to present some concepts of one or more aspects in a simplified form as a prelude to the more detailed description that is presented later.


Aspects of the present disclosure include a scalable proportional to absolute temperature (PTAT) hybrid circuit, comprising a bias mirror circuit configured to provide a zero temperature coefficient (ZTC) current, a PTAT control circuit configured to generate, based on the ZTC current, a PTAT current with a slope having a non-zero value, alter the PTAT current by at least scaling the PTAT current or changing the slope of the PTAT current to generate an altered PTAT current, and provide the altered PTAT current, a hybrid circuit configured to receive the ZTC current and the altered PTAT current, and output a larger current of the ZTC current and the altered PTAT current as a hybrid current.


Aspects of the present disclosure include a scalable proportional to absolute temperature (PTAT) hybrid circuit, comprising a bias mirror circuit having a zero temperature coefficient (ZTC) current source configured to induce a ZTC current, a PTAT control circuit having two or more first source transistors, a first BJT connected to one of the two or more first source transistors, a first variable resistor connected to the first BJT, a first transistor connected to the first variable resistor, wherein the first BJT, the first variable resistor, and the first transistor are connected in series, a second transistor, a second variable resistor connected to a drain terminal of the second transistor and a first base of the first BJT, a third variable resistor connected to the second variable resistor, wherein the second transistor, the second variable resistor, and the third variable resistor are connected in series, a bandgap circuit having a second BJT and a third BJT, wherein a second base of the second BJT and a third base of the third BJT are connected to the second variable resistor and the third variable resistor, a fourth variable resistor connected to the second BJT of the bandgap circuit, and a third transistor connected to the fourth variable resistor, and a hybrid circuit.


Aspects of the present disclosure include a method of providing a hybrid current by a scalable proportional to absolute temperature (PTAT) hybrid circuit, comprising: providing a zero temperature coefficient (ZTC) current, generating, based on the ZTC current, a PTAT current having a slope having a non-zero value, altering the PTAT current by at least scaling the PTAT current or changing the slope of the PTAT current to generate an altered PTAT current, and outputting a larger current of the ZTC current and the altered PTAT current as a hybrid current.


To the accomplishment of the foregoing and related ends, the one or more aspects comprise the features hereinafter fully described and particularly pointed out in the claims. The following description and the annexed drawings set forth in detail certain illustrative features of the one or more aspects. These features are indicative, however, of but a few of the various ways in which the principles of various aspects may be employed, and this description is intended to include all such aspects and their equivalents.





BRIEF DESCRIPTION OF THE DRAWINGS

The disclosed aspects will hereinafter be described in conjunction with the appended drawings, provided to illustrate and not to limit the disclosed aspects, wherein like designations denote like elements, and in which:



FIG. 1 is a circuit diagram of an example of a hybrid circuit, including an inset graph of current versus temperature performance of the hybrid circuit, according to aspects of the present disclosure.



FIG. 2 is a circuit diagram of another example of the hybrid circuit of FIG. 1 according to aspects of the present disclosure.



FIG. 3 is a circuit diagram of a further example of the hybrid circuit of FIG. 1 according to aspects of the present disclosure.



FIG. 4 includes example graphs of example characteristics of the hybrid circuit, including current versus temperature performance, and corresponding temperature coefficient versus temperature performance, according to aspects of the present disclosure.



FIG. 5 is a circuit diagram of an example of another hybrid circuit, including an inset graph of current versus temperature performance of the hybrid circuit, according to aspects of the present disclosure.



FIG. 6 includes graphs of examples of current versus temperature profiles of a scalable PTAT hybrid circuit according to aspects of the present disclosure.



FIG. 7 is a circuit diagram of an example of a scalable PTAT hybrid circuit according to aspects of the present disclosure.



FIG. 8 is a flowchart of an example of a method for providing a hybrid current via a scalable PTAT hybrid circuit according to aspects of the present disclosure.



FIG. 9 illustrates examples of current supplies according to aspects of the present disclosure.



FIG. 10 is an example of a circuit configured as a variable resistor according to aspects of the present disclosure.



FIG. 11 illustrates additional examples of variable resistors according to aspects of the present disclosure.



FIG. 12 is an example of a PTAT generator according to aspects of the present disclosure.



FIG. 13 is an example of a PTAT generator with one or more variable resistors according to aspects of the present disclosure.





DETAILED DESCRIPTION

The detailed description set forth below in connection with the appended drawings is intended as a description of various configurations and is not intended to represent the only configurations in which the concepts described herein may be practiced. The detailed description includes specific details for the purpose of providing a thorough understanding of various concepts. However, it will be apparent to those skilled in the art that these concepts may be practiced without these specific details. In some instances, well known structures and components are shown in block diagram form in order to avoid obscuring such concepts.


According to one aspect of the present disclosure, an integrated circuit (IC) bias scheme may operate with a positive temperature coefficient (PTC) at temperatures above a threshold temperature, and with zero temperature coefficient (ZTC) at temperatures below the threshold temperature. This hybrid approach may compensate for gain loss at higher temperatures without sacrificing signal levels at lower temperatures.


In one aspect of the present disclosure, a scalable proportional to absolute temperature (PTAT) hybrid circuit may output a hybrid current having a ZTC current at temperatures below a threshold temperature and a PTC current at temperature above the threshold temperature. The PTAT hybrid circuit may be configured to control the current magnitude of the hybrid current, and/or the slope of the PTC current.


Referring to FIG. 1, a hybrid circuit 100 configured to provide a PTC current at temperatures above a threshold temperature, and a ZTC current at temperatures below the threshold temperature. The hybrid circuit 100 may include a ZTC current source 102 configured to provide a ZTC current IZTC into the hybrid circuit 100. The hybrid circuit 100 may include a PTC current source 104 configured to provide a PTC current IPTC into the hybrid circuit 100. The hybrid circuit 100 may include a first current sink 110 configured to sink the ZTC current IZTC. The hybrid circuit 100 may include a second current sink 112 configured to sink the PTC current IPTC. The first current sink 110 may be disposed in series, parallel, or other configurations with respect to the ZTC current source 102. The second current sink 112 may be disposed in series, parallel, or other configurations with respect to the PTC current source 104.


In some aspects of the present disclosure, the hybrid circuit 100 may include a first transistor 114 configured to provide a second current I2, which may be the maximum of zero current and the difference between the PTC current IPTC and the ZTC current IZTC. The hybrid circuit 100 may include a second transistor 116 configured to sink a first current I1, which may be the minimum of the ZTC current IZTC and the PTC current IPTC. The hybrid circuit 100 may include a third transistor 118 configured to sink a third current I3, which may be the ZTC current IZTC.


In certain aspects of the present disclosure, the hybrid circuit 100 may include a first current source 120 configured to accept a fourth current I4, which may be a summation current of the second current I2 and the third current I3. The hybrid circuit 100 may include a current mirror 122 configured to mirror the fourth current I4 and provide a hybrid current IHyb. The first current source 120 and the current mirror 122 may be connected to a voltage supply VDD.


During normal operation, in certain aspects of the present disclosure, the ZTC current source 102 may provide the ZTC current IZTC toward the first current sink 110. The ZTC current IZTC may cause a first gate voltage on a first gate terminal 140. The first gate voltage may turn the first current sink 110, the second transistor 116, and/or the third transistor 118 from an off state to an on state. The first gate voltage may cause the third transistor 118 to mirror the same amount of current (i.e., the third current I3) as IZTC Specifically, the first gate voltage may turn on the third transistor 118, which may provide the third current I3 Since the source terminal of the third transistor 118 is connected to the ground terminal, a third gate voltage may be developed on the drain terminal of the third transistor, which is shorted to a third gate terminal 144. Since the first current source 120 is consistently biased in the saturation regime (i.e., gate and drain terminals connected), the third gate voltage may cause the first current source 120 to provide the fourth current.


In some aspects, the PTC current source 104 may provide the PTC current IPTC toward the second current sink 112. The PTC current IPTC may cause a second gate voltage on a second gate terminal 142. The second gate voltage may be insufficient to turn on the second current sink 112 or the first transistor 114, or be sufficient to turn the second current sink 112 and the first transistor 114 from an off state to an on state, depending on the ZTC current IZTC as explained below.


In some aspects of the present disclosure, as shown in graph 146, for temperatures below a threshold temperature TTH, the ZTC current IZTC may be larger than the PTC current IPTC. As explained above, the ZTC current IZTC may induce the first gate voltage at the first gate terminal 140. Since the ZTC current IZTC is larger than the PTC current IPTC, the first gate voltage may turn on the second transistor 116. Consequently, the PTC current IPTC provided by the PTC current source 104 may not turn on the first transistor 114 because an entire amount of the PTC current IPTC is sunk through the second transistor 116. As such, the second current I2 is zero because the first transistor 114 is off. Therefore, the third current I3 and the fourth current I4 may both equal to the ZTC current IZTC, and the current mirror 122 will provide the hybrid current IHyb having the same current level as the ZTC current IZTC. In other words, for temperatures below the threshold temperature TTH, the hybrid current IHyb is equal to the ZTC current IZTC.


In other aspects of the present disclosure, for temperature above the threshold temperature TTH, the PTC current IPTC may be larger than the ZTC current IZTC. As explained above, the ZTC current IZTC may induce the first gate voltage at the first gate terminal 140. Since the PTC current IPTC is larger than the ZTC current IZTC, the first gate voltage may turn on the second transistor 116. However, the second transistor 116 is able to sink only the ZTC current IZTC (which is smaller than the PTC current IPTC). Consequently, a differential current (i.e., IPTC−IZTC) may be sunk through the second current sink 112. The differential current may cause the second gate voltage to be developed on the second gate terminal 142. The second gate voltage may turn on the first transistor 114 such that the second current I2 mirrors the differential current (i.e., IPTC−IZTC). Since the third current I3 may be equal to the ZTC current IZTC, the fourth current I4 may become a sum of the second current I2 and the third current I3, which is the PTC current IPTC (i.e., I2+I3=(IPTC−IZTC)+IZTC=IPTC). As a result, the current mirror 122 will provide the hybrid current IHyb having the same current level as the PTC current IPTC. In other words, for temperatures above the threshold temperature TTH, the hybrid current IHyb is equal to the PTC current IPTC.


In some aspects, the hybrid current IHyb provided by the hybrid circuit 100 may exhibit characteristics shown in the graph 146. Specifically, at temperatures below the threshold temperature TTH, the hybrid current IHyb may be constant with temperature. And, at temperatures above the threshold temperature TTH, the hybrid current IHyb may increase with temperature. The hybrid current IHyb may be the maximum current of the PTC current IPTC and the ZTC current IZTC.


In some aspects of the present disclosure, one or more of the first current sink 110, the second current sink 112, the first transistor 114, the second transistor 116, and/or the third transistor 118 may be nMOS (e.g., n-type metal oxide semiconductor field effect transistor (MOSFET)) or other n-type transistors. One or more of the first current source 120 and/or the current mirror 122 may be pMOS or other p-type transistors. The one or more of the first current sink 110, the second current sink 112, the first transistor 114, the second transistor 116, and/or the third transistor 118 may be the same or different (e.g., same or different widths, lengths, dopings, geometries, etc.). The one or more of the first current source 120 and/or the current mirror 122 may be p-type transistors may be the same or different (e.g., same or different widths, lengths, dopings, geometries, etc.).


In certain aspects, the slopes, curvatures, and/or shapes of the current vs. temperature behavior of the hybrid current IHyb may vary according to some aspects of the present disclosure.


Referring to FIG. 2, an example of the hybrid circuit 100, including one implementation of input current circuitry, is configured to provide a PTC current at temperatures above a threshold temperature and a ZTC current at temperature below the threshold temperature. The hybrid circuit 100 may include a ZTC current source 202, which is an example of the ZTC current source 102 that provides constant current as temperatures change. The hybrid circuit 100 may include a PTC current source 204, which is an example of the PTC current source 104 that provides current that increases with temperature.


In an aspect, it may be desirable to manage signal levels in On Off Keying (OOK) transmission across an isolation barrier. For example, it may be desirable to compensate for transmission transformer loss at temperatures above the threshold temperature TTH and/or reduce reception signal loss at temperature below the threshold temperature TTH. Specifically, a ZTC current source operating alone may provide a constant current below and above the threshold temperature TTH. However, as temperatures rise, the transformer loss may increase with the operating temperature. Since the current provided by the ZTC current source remains constant with temperature, the ZTC current source may be unable to compensate for the transmission transformer loss at temperatures above the threshold temperature TTH. Similarly, a PTC current source operating alone may provide a current that changes with temperature. As temperatures drop, the current provided by the PTC current source may decrease accordingly. This may cause reception signal loss at temperature below the threshold temperature TTH. Aspects of the present disclosure include the hybrid circuit 100 configured to provide a constant current at temperatures below the threshold temperature TTH and a variable temperature at temperatures above the threshold temperature TTH.


Referring to FIG. 3, an example of the hybrid circuit 300 configured to provide a source current with variable slopes at temperatures below and above the threshold temperature TTH. The hybrid circuit 300 may be configured to provide variable bias currents, such as but not limited to bias currents with different temperature coefficients (TCs) (i.e., rate of current change as a function of temperature change). For example, the hybrid circuit 300 may include a first TC current source 304-1 configured to provide a first TC current ITC-1, a second TC current source 304-2 configured to provide a second TC current ITC-2 . . . and an nth TC current source 304-n configured to provide an nth TC current ITC-n. Here, n may be a positive integer greater than 1. In some aspects, the hybrid circuit 300 may have two or more TC current sources with different TCs.


In some aspects of the present disclosure, the hybrid circuit 300 may include a multiplexer/combining circuit 350 configured to select one or more of the currents provided by the first TC current source 304-1, the second TC current source 304-2 . . . and/or the nth TC current source 304-n. The currents that are selected may be determined by indications provided to the multiplexer/combining circuit 350. For instance, the selected input currents may have different slopes above and/or below the threshold temperature TTH. The hybrid circuit 300 may include a output 360 configured to output a hybrid current IHyb including a selected PTC current IS-PTC and a selected ZTC current IS-ZTC. The selected PTC current IS-PTC may include one or some combination of the first TC current ITC-1, the second TC current ITC-2 . . . the nth TC current ITC-n. The selected ZTC current IS-ZTC may include one or some combination of the first TC current ITC-1, the second TC current ITC-2 . . . the nth TC current ITC-n. In some optional implementations, the multiplexer/combining circuit 350 may be configured to apply one or more gain factors to the one or more of the first TC current ITC-1, the second TC current ITC-2 . . . the nth TC current ITC-n, prior to outputting the IHyb via the output 360. For example, the multiplexer/combining circuit 350 may amplify the magnitude of the currents prior to outputting the IHyb via the output 360.


In an aspect, the hybrid circuit 300 may additionally include a decision circuit 352 configured to provide one or more indication signals to the multiplexer/combining circuit 350 for indicating the selection of the one or some combination of the currents provided by the first TC current source 304-1, the second TC current source 304-2 . . . and/or the nth TC current source 304-n. The decision circuit 352 may optionally include one or more analog-to-digital converter (ADC). For example, the decision circuit 352 may receive analog input and output digital control signals. The decision circuit 352 may include logic, functions, or algorithms used to control how the multiplexer/combining circuit 350 generates the IHyb from one or some combination of the first TC current source 304-1, the second TC current source 304-2 . . . and/or the nth TC current source 304-n. For example, the decision circuit 352 may utilize an input 355 from a temperature sensor 354, e.g., for temperature-dependent generation of the output 360 and/or one or more optional inputs 353, to generate the indication signals. The one or more optional inputs 353 may include, but are not limited to, desired slopes of the current above and/or below the threshold temperature TTH. Based on the desired slopes, the decision circuit 352 may control the multiplexer/combining circuit 350 to select one or more of the currents provided by the first TC current source 304-1, the second TC current source 304-2 . . . and/or the nth TC current source 304-n.


Referring to FIG. 4, example graphs 400 include example characteristics of the hybrid circuit 100 shown in FIGS. 1 and 2, the hybrid circuit 300 shown in FIG. 3, and/or a p-type hybrid circuit 500 shown in FIG. 5 (below), including current versus temperature characteristic graphs 402 and corresponding temperature coefficient versus temperature characteristic graphs 404, which may be utilized in any of the aspects of the hybrid circuits described herein. In some instances, the temperature coefficients versus temperature characteristics may be derived based on the slope values of the current versus temperature characteristics (i.e., indicating the instantaneous change in the current versus temperature characteristics).


In some cases, a first current graph 410, which may be the same as or similar to graph 146, may illustrate a hybrid circuit output current based on a ZTC current having a zero slope over a first temperature range, and a PTC current having a positive slope over a second temperature range. A second current graph 412 may illustrate a hybrid circuit output current based on a ZTC current having a zero slope over some temperatures, and two PTC currents having different slopes over other temperatures. A third current graph 414 may illustrate a hybrid circuit output current based on a ZTC current having a first positive slope over some temperatures, and a PTC current having a second positive slope larger than the first positive slope over other temperatures. A fourth current graph 416 may illustrate a hybrid circuit output current based on a ZTC current having a first variably positive slope over some temperatures, and a PTC current having a second variably positive slope over other temperatures. The fourth current graph 416 may illustrate an example of a hybrid circuit having gradual (non-abrupt) transition between a ZTC current having a first zero or positive slope and a PTC current having a second positive slope larger than the slope of the ZTC current.


In some aspects of the present disclosure, a first TC graph 420 may illustrate the TC curve corresponding to the hybrid circuit output current in the first current graph 410. The first TC graph 420 shows that the slope of the ZTC current is zero and the slope of the PTC current is a positive number. A second TC graph 422 may illustrate the TC curve corresponding to the hybrid circuit output current in the second current graph 412. The second TC graph 422 shows that the slope of the ZTC current is zero and the slope of the PTC current increases with temperatures in a first temperature range and remains a positive number in a second temperature range. A third TC graph 424 illustrates the TC curve corresponding to the hybrid circuit output current in the third current graph 414. The third TC graph 424 shows that the slope of the ZTC current is a first positive number and the slope of the PTC current is a second positive number larger than the first positive number. A fourth TC graph 426 illustrates the TC curve corresponding to the hybrid circuit output current in the fourth current graph 416. The fourth TC graph 426 shows that the slope of the ZTC current increases with temperature, and the slope of the PTC current increases with temperatures in a first temperature range and remains a positive number in a second temperature range.


Other current and/or TC profiles may also be implemented according to aspects of the present disclosure.


Referring to FIG. 5, an example of a p-type hybrid circuit 500 is configured to provide a PTC current at temperatures above a threshold temperature and a ZTC current at temperature below the threshold temperature. The p-type hybrid circuit 500 may include a PTC current source 502 configured to sink the PTC current IPTC from the p-type hybrid circuit 500. The p-type hybrid circuit 500 may include a ZTC current source 504 configured to sink the ZTC current IZTC from the p-type hybrid circuit 500. The p-type hybrid circuit 500 may include a first P current source 550 configured to source the ZTC current IZTC toward the ZTC current source 504. The p-type hybrid circuit 500 may include a first P transistor 552 configured to provide a first P current IP-1, which may be the minimum of the PTC current IPTC and the ZTC current IZTC. The p-type hybrid circuit 500 may include a first P current mirror 554 configured to provide a third P current IP-3 that mirrors the ZTC current IZTC sourced by the first P current source 550. The third P current IP-3 may have the same magnitude as the ZTC current IZTC. The first p current source 550 may be disposed in series, parallel, or other configurations with respect to the ZTC current source 504.


In certain aspects of the present disclosure, the p-type hybrid circuit 500 may include a second P transistor 556 configured to provide a variable current ranging from zero to a differential current between the PTC current IPTC and the ZTC current IZTC as described in further details below. The p-type hybrid circuit 500 may include a second P current mirror 558 configured to provide a second P current IP-2 that mirrors the variable current provided by the second P transistor 556.


During normal operation, in certain aspects, the first P current source 550 may provide the ZTC current IZTC in response to the ZTC current source 504. Because the drain terminal and the gate terminal of the first P current source 550 are connected, the first P current source 550 may operate in the saturation regime and a fourth gate voltage at a fourth gate terminal 560 may be developed on the drain terminal and the gate terminal of the first P current source 550. Consequently, the fourth gate voltage may be applied to the fourth gate terminal 560, including the gate terminals of the first P transistor 552 and/or the first P current mirror 554. As a result, the first P current mirror 554 may source the third P current IP-3.


In some aspects of the present disclosure, as shown in a graph 590, for temperatures above a P threshold temperature TP-TH, the PTC current IPTC may be larger than the ZTC current IZTC. The PTC current IPTC may induce a fifth gate voltage at the fifth gate terminal 562. Since the PTC current IPTC is larger than the ZTC current IZTC, the fifth gate voltage may turn on the second P transistor 556 because the first P current IP-1 (having a current magnitude equaling to the ZTC current IZTC) is insufficient to supply the PTC current IPTC alone. The fifth gate voltage may turn on the second P transistor 556 such that the second P transistor 556 supplies the differential current between the PTC current IPTC and the ZTC current IZTC. Consequently, the second P current mirror 558 may mirror the second P transistor 556 and supply the second P current IP-2 (having the same magnitude as the differential current IPTC−IZTC). Therefore, the second P current IP-2 may equal to the differential current of IPTC−IZTC and the third P current IP-3 may equal to the ZTC current IZTC. As a result, the hybrid current IHyb may equal to the sum of the second P current IP-2 and the third P current IP-3, which is the PTC current IPTC. In other words, for temperatures above the P threshold temperature TP-TH, the hybrid current IHyb is equal to the PTC current IPTC.


In other aspects of the present disclosure, for temperature below the P threshold temperature TP-TH, the ZTC current IZTC may be larger than the PTC current IPTC. As such, the first P transistor 552 may supply the ZTC current IZTC as the first P current IP-1. Consequently, the fifth gate voltage may remain “high” to keep the second P transistor 556 off. The second P current mirror 558 may similarly remain in the off state and supply no current as the second P current IP-2. As a result, the hybrid current IHyb may equal to the sum of the second P current IP-2 and the third P current IP-3, which is the ZTC current IZTC. In other words, for temperatures below the P threshold temperature TP-TH, the hybrid current IHyb is equal to the ZTC current IZTC.


In some aspects, the hybrid current IHyb provided by the hybrid circuit 100 may exhibit characteristics shown in the graph 590. At temperatures below the P threshold temperature TP-TH, the hybrid current IHyb may be constant with temperature. At P threshold temperature TP-TH, the hybrid current IHyb may increase with temperature. The hybrid current IHyb may be the maximum current of the PTC current IPTC and the ZTC current IZTC.



FIG. 6 includes example graphs 601 and 605 of current versus temperature behaviors of a scalable PTAT hybrid circuit according to aspects of the present disclosure. Referring to graph 601, in certain aspects, a scalable PTAT hybrid circuit (described below in FIG. 7) may output a hybrid current exhibiting a first current versus temperature behavior 600 without PTAT scaling. In some aspects, the scalable PTAT hybrid circuit may perform a negative PTAT scaling such that the hybrid current is shifted to exhibit a second current versus temperature behavior 602. The second current versus temperature behavior 602 may be the first current versus temperature behavior 600 being shifted negatively by ΔI1. In other words, at a temperature t1, the current level of the first current versus temperature behavior 600 (without PTAT scaling) is ΔI1 higher than the current level of the second current versus temperature behavior 602 (due to the negative PTAT scaling).


Still referring to graph 601, in certain aspects, the scalable PTAT hybrid circuit may perform a positive PTAT scaling such that the hybrid current is shifted to exhibit a third current versus temperature behavior 604. The third current versus temperature behavior 604 may be the first current versus temperature behavior 600 being shifted positively by ΔI2. In other words, at a temperature t1, the current level of the first current versus temperature behavior 600 (without PTAT scaling) is ΔI2 lower than the current level of the third current versus temperature behavior 604 (due to the positive PTAT scaling).


Referring to graph 605, in some aspects of the present disclosure, the first current versus temperature behavior 600 of the PTAT hybrid circuit may have a slope of m1 in the positive temperature coefficient regime (without slope control). In an aspect of the present disclosure, the PTAT hybrid circuit may increase the slope of the output hybrid circuit to exhibit a fourth current verses temperature behavior 606 having a slope of m4 in the positive temperature coefficient regime. In another aspect, the PTAT hybrid circuit may decrease the slope of the output hybrid circuit to exhibit a fifth current verses temperature behavior 608 having a slope of m5 in the positive temperature coefficient regime.


In some aspects of the present disclosure, the PTAT hybrid circuit may perform both the PTAT scaling and the slope control.



FIG. 7 shows an example of a scalable PTAT hybrid circuit 700 configured to scale the current magnitude of a hybrid current, and/or adjust the slope of the hybrid current in the temperature dependent regime. In certain implementations, a scalable PTAT hybrid circuit 700 may include a bias minor circuit 702 configured to provide currents to the remaining portions of the scalable PTAT hybrid circuit 700. The bias mirror circuit 702 may include a ZTC current source 704 configured to provide a ZTC current (IZTC). The scalable PTAT hybrid circuit 700 may include a PTAT control circuit 720 configured to scale a magnitude of a hybrid current (IHYB) and/or a slope of the PTAT current (IPTAT). In some implementations, the PTAT control circuit 720 may be configured to provide the IPTAT. The scalable PTAT hybrid circuit 700 may include a hybrid circuit 770 configured to combine the IZTC and the IPTAT to provide the IHYB.


In some aspects, the PTAT control circuit 720 may include a first resistor R1. The PTAT control circuit 720 may include a first transistor T1. The PTAT control circuit 720 may include a second transistor T2. The PTAT control circuit 720 may include a second transistor R2. The R1, T1, T2, and R2 may be configured to determine the magnitude and/or slope of the IPTAT. The PTAT control circuit 720 may include a slope control circuit 730 configured to control the slope of the current versus temperature behaviors of the hybrid current as described in FIG. 6 and below.


In some aspects, the PTAT control circuit 720 may include a bandgap circuit 740 including a second bipolar junction transistor (BJT) Q2, and a third BJT Q3. The bandgap circuit 740 may optionally include a base current cancellation circuit BCC configured to prevent the base currents of the Q2 and/or Q3 from interfering with the slope of the IPTAT. The bandgap circuit 740 may be configured to generate at least a portion of the IPTAT.


The slope control circuit 730 may include a third resistor R3 and a fourth resistor R4. The resistances of the R3 and R4 may determine the voltages at V3 and/or V4, which controls the amount of current flow through Q1 and/or Q2. The R3 and R4 may be variable resistors.


In optional aspects, the scalable PTAT hybrid circuit 700 may include an optional bias-gain circuit 750 configured to keep collector voltages VC1, VC2 of the Q2 and Q3 constant.


In some aspects, the PTAT control circuit 720 may include first source transistors 722 configured to provide first source current (ISOURCE-1). The PTAT control circuit 720 may include second source transistors 732 configured to provide a second source current (ISOURCE-2). The PTAT control circuit 720 may include third source transistors 734 configured to provide a third source current (ISOURCE-3).


During operation, the bias minor circuit 702 may be configured to induce the ISOURCE-1 into the PTAT control circuit 720 via first source transistors 722 of the PTAT control circuit 720. A first voltage V1 may appear across the first resistor R1. The first resistor R1 may be a variable resistor ranging from 0Ω to 10 kiloohms (kΩ), for example 1.8 kΩ, 2 kΩ, 2.2 kΩ.


In one example, the first source current ISOURCE-1 may be approximately 50 microamps (μA), the first voltage drop VR1 may be 100 millivolts (mV), and the first resistor R1 may be 1.8 kΩ.


In some aspects, the first source current ISOURCE-1 may flow through the first transistor T1. A second voltage V2 induced by the first source current ISOURCE-1 may be applied to the gate of the first transistor T1. As a result, the first transistor T1 may be a triode device exhibiting linear current behavior. The second voltage V2 may be applied to the gate of the second transistor T2. As a result, the second transistor T2 may be a triode device exhibit linear current behavior. Other devices may also be used to apply the second voltage V2. The first transistor T1 and the second transistor T2 may be matched (e.g., same size). The ratio of the sizes of the T1 and the T2 may determine the slope and/or scaling of the IHYB.


In some aspects, the bandgap circuit 740 may operate as described below. The ISOURCE-1, and therefore, the second voltage V2, may induce the ISOURCE-2 through second source transistors 732, the second BJT Q2, and the second transistor T2. Similarly, the ISOURCE-1 and the second voltage V2 may induce the ISOURCE-3 flowing through third source transistors 734 and the third BJT Q3. A second base-emitter voltage VBE-2 may be developed across the second BJT Q2 due to the ISOURCE-2. A third base-emitter voltage VBE-3 may be developed across the third BJT Q3 due to the ISOURCE-3. A difference in voltage ΔV between the VBE-2 and the VBE-3 may be generated due to one or more of a difference in the dimensions (e.g., emitter area) of the second BJT Q2 and the third BJT Q3, and/or a difference between the ISOURCE-2 and the ISOURCE-3. Individually, the VBE-2 and the VBE-3 are inversely proportional to temperature (i.e., as temperature increases, the corresponding voltage decreases) due to the P-N junction diode formed between the base and the emitter. Specifically, as temperature increases, the number of carriers injected increases, requiring less voltage to drive the same current. The difference in the base-emitter voltages (|VBE-2−VBE-3|, aka ΔV) is proportional to temperature (i.e., as temperature increases, the difference in voltage increases). Therefore, as temperature increases, the ΔV increases.


In some aspects, the third voltage V3 may be an improper fraction multiple (e.g., ˜(R3+R4)/R4) of ΔV. As the ΔV increases (e.g., due to temperature), the third voltage V3 decreases.


In certain aspects, the ISOURCE-3 may be mirrored by the hybrid circuit 770 to generate the IPTAT as described above. The ratio of the ISOURCE-2 and the ISOURCE-3 may be determined by one or more of the sizes of the Q2 and Q3, and/or the sizes of the second source transistors 732 and the third source transistors 734.


In certain aspects, the bias-gain circuit 750 may lock the collector voltages (VC1 and VC2) to match for the operation of the bandgap circuit 740. Alternatively or additionally, the bias-gain circuit 750 may provide the base currents to one or more of the Q2 and/or Q3. In some aspects, the bias-gain circuit 750 may prevent the introduction of undesirable temperature coefficients during the biasing of the bandgap circuit 740.


According to an aspect of the present disclosure, as the IZTC changes in current magnitude, the IPTAT will change accordingly. Referring to FIGS. 6 and 7, the IZTC in the hybrid circuit 700 for the first current versus temperature behavior 600 may change in current magnitude (i.e., shift up or increase in current magnitude, or shift down or decreases in current magnitude). During a change in IZTC in the bias mirror circuit 702, the ISOURCE-1 may change accordingly (i.e., a decrease in IZTC leads to a decrease in ISOURCE-1, and vice versa). As the ISOURCE-1 changes, the R1 and/or R2 may change correspondingly. As a result, the ISOURCE-2 may change, which leads to a change in the IPTAT.


For example, if the IZTC decreases in the bias mirror circuit 702, the ISOURCE-1 may decrease accordingly. The decrease in the ISOURCE-1 may lead to an increase in the R1/T1 pair resistance because voltage drop across the R1 may remain approximately constant due to a first BJT Q1 (i.e., V1 remains unchanged). As a result, the R2 may increase correspondingly, causing an decrease to the ISOURCE-2. Consequently, IPTAT may decrease.


In another aspect of the present disclosure, the slope of the hybrid current in the positive temperature coefficient regime may be controlled by selecting the temperature coefficient of the first voltage V1, which causes the resistance of the R1 to scale with temperature. The first voltage V1 may be determined by the values of the third resistor R3 and/or the fourth resistor R4 of the slope control circuit 730.


In some implementations, the R1, R2, R3, and R4 may be polysilicon variable resistors.


In an aspect of the present disclosure, V1 may provide a reference voltage. In the current example, V1 is generated on-chip via Q1. However, in some implementations, V1 may be provided off-chip. V1 may be a digital input. Other schemes to generate reference voltage and/or reference current may also be used according to aspects of the present disclosure. ISOURCE-1 and/or V1 may include a temperature coefficient. The triode FETs (i.e., the first transistor T1 and the second transistor T2) may be the tuning elements that change the pair resistance of R1/T1 and/or the pair resistance of R2/T2. The temperature dependency of ISOURCE-1 and/or V1 may be transferred to ISOURCE-2 and/or ISOURCE-3 via V2.


In optional aspects of the present disclosure, the temperature dependency of IPTAT may originate from the temperature dependencies of R1 and/or R2. In one aspect, the size difference between Q2 and Q3 may cause a difference in VBE-2 and VBE-3. The difference in the voltages may appear across R2, which generates the temperature dependency of IPTAT.


In some aspects of the present disclosure, the slope control circuit 730 may control V4. The ratios of R3 and R4 may determine the voltage value of V4, which may change the voltage value of V2. V3 may track VBE-2 and/or VBE-3.


An example of analysis of the first voltage V1 may be as follow:






V
R2
=ΔV=V
T×ln(n×m)


Here, VR2 is the voltage drop across the R2, VT=kT/q, T is the temperature, q is the electronic charge, n is the ratio of the sizes of the Q2 to the Q3, and m is the ratio of the sizes of the two or more second source transistors to the two or more third source transistors. Further,








V

BE



1




V

BE



2



=


V
4

-

V

BE



2










V

BE



1


=


V
3

-

V
1










V
4

=


V

R

2


+

V

T

2


+

V

BE­



2




,


wherein



V
4


=

V

BE



3










V
3

=


V
4

(



R
3

+

R
4



R
4


)








V
1

=



V
3

-

V

BE



1



=


V

B

G


.






Here, V4 may be the voltage between the R3 and R4, and VBE-1 may be the emitter-base voltage for Q1. VBE-1 is substantially constant except as adjusted by R3 to trim the slope of the hybrid current IHyb (example shown in the graph 605 of FIG. 6). By simplifying the equation above:








V
1

=



R
3


R
4




V

B

G




,




where VBG is the bandgap voltage of Q2.


Turning to FIG. 8, a method 800 of providing a hybrid current may be performed by the scalable PTAT hybrid circuit 700.


At block 805, the method 800 may provide a zero temperature coefficient (ZTC) current. For example, the bias mirror circuit 702 may provide a zero temperature coefficient (ZTC) current.


At block 810, the method 800 may generate, based on the ZTC current, a PTAT current with a slope having a non-zero value. For example, the PTAT control circuit 720 and/or the bandgap circuit 740 may generate, based on the ZTC current, a PTAT current with a slope having a non-zero value.


At block 815, the method 800 may provide a reference voltage to alter the PTAT current by at least scaling the PTAT current or changing the slope of the PTAT current to generate an altered PTAT current. For example, the PTAT control circuit 720, the Q1, the R1, T1, and/or the slope control circuit 730 may provide V1 (generated from dividing ISOURCE-1 by R1 to control the resistance(s) of R2 and/or T2 to alter the PTAT current by at least scaling the PTAT current or changing the slope of the PTAT current to generate an altered PTAT current.


At block 820, the method 800 may output a larger current of the ZTC current and the altered PTAT current as a hybrid current. For example, the hybrid circuit 770 may output a larger current of the ZTC current and the altered PTAT current as a hybrid current.



FIG. 9 illustrates examples of current supplies according with aspects of the present disclosure. The current supply 900 includes a resistor with a resistance of R, and a transistor have a dimension of W/L. When the gate voltage is applied, a current that is proportional to [1/R×W/L] flows through the transistor. The current supply 910 includes a variable resistor with a resistance of R/N, and a transistor have a dimension of W/L. When the gate voltage is applied, a current that is proportional to [N/R×W/L] flows through the transistor. Here N may be changed during the operation of the bias circuits described above to change the current supplied.



FIG. 10 illustrates another example of a circuit 1000 configured as a variable resistor according to aspects of the present disclosure. Here, an input voltage of VREF is applied to an op-amp, which supplies the gate voltage of the transistor. A drain current of IREF flows through the transistor, where the drain current IREF is a function of the input voltage VREF. In a first regime of operation, IREF may be linearly proportional to VREF (i.e, linear regime). In a second regime of operation, VREF may exceed the saturation voltage of the transistor, and IREF may be constant as VREF increases. As such, the circuit 1000 has an output behavior that emulates a variable resistor, where the effective variable resistance






R
=



V

R

E

F



J

R

E

F



.





Here, the effective variable resistance varies with VREF while IREF remains substantially constant.



FIG. 11 illustrates additional examples of variable resistors according to aspects of the present disclosure. A variable resistor circuit 1100 may operate in the triode operation. Here, the field effect transistor may operate under the condition where |VGS−VT|>>VDS. During the triode operation,








V

D

S



J
D




R

D

S






or, equivalently, VDS≈IDRDS. As shown in the graph 1102, RDS operates as a variable resistor in the resistive range. Here, the resistance of the transistor between the drain and the source is a variable resistor that is a function of the applied gate to source voltage.


Similarly, in some aspects of the present disclosure, a variable resistor circuit 1110 may include a built-in fixed resistor in series with the transistor. In some instances, having a built-in fixed resistor may extend the resistive range of the variable resistor circuit 1110 as shown in the graph 1112. In certain aspects, by adding the fixed resistor in series, the linearity may be improved over temperature and/or process. Either type of variable resistor circuits shown in FIG. 11 may be implemented in the bias temperature circuit according to aspects of the present disclosure.



FIG. 12 illustrates an example of a PTAT generator 1200 according to aspects of the present disclosure. Referencing FIGS. 7 and 12, the PTAT generator 1200 may be an implementation of the slope control circuit 730 and the bandgap circuit 740. Here, V4 may equal to the base-emitter voltage (VBE) of the third BJT Q3. V3 may equal to








V

B

E


(


R
4



R
3

+

R
4



)

.





FIG. 13 illustrates an example of a PTAT generator 1300 with one or more variable resistors according to aspects of the present disclosure. Referencing FIGS. 7 and 13, the PTAT generator 1300 may be an implementation of the slope control circuit 730 and the bandgap circuit 740. Here, the reference voltage may be derived as follows. V3 may be calculated as 1+KVBE-3. The voltage V5 may be calculated as (1+K)(VBE-3−VBE-2), which may be simplified to (1+K)ΔVBE. The expression may be further simplified to V1=KVBE+ΔVBE, which is the bandgap type reference voltage according to aspects of the present disclosure.


Aspects of the present disclosure include a scalable proportional-to-absolute-temperature (PTAT) hybrid circuit, including a bias minor circuit configured to provide a zero temperature coefficient (ZTC) current, a PTAT control circuit configured to generate, based on the ZTC current, a PTAT current with a slope having a non-zero value, to alter the PTAT current by at least scaling the PTAT current or changing the slope of the PTAT current to generate an altered PTAT current, and to output a larger current of the ZTC current and the altered PTAT current as a hybrid current.


Aspects of the present disclosure include the PTAT hybrid circuit above, wherein the bias mirror circuit comprises a ZTC current source.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the PTAT control circuit comprises two or more first source transistors configured to provide a first source current through a first bipolar junction transistor (BJT), a first variable resistor, and a first transistor.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the PTAT control circuit further comprises the first BJT, the first variable resistor, and the first transistor, wherein the first BJT, the first variable resistor, and the first transistor are connected in series.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the PTAT control circuit further comprises a slope control circuit configured to change the slope of the PTAT current.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the slope control circuit comprises a second transistor, a second variable resistor, and a third variable resistor, wherein the second transistor, the second variable resistor, and the third variable resistor are connected in series.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein a drain of the second transistor is connected to a base of the first BJT.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the PTAT control circuit comprises a bandgap circuit configured to generate the PTAT current.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the bandgap circuit comprises a first bipolar junction transistor (BJT) and a second BJT, wherein a first gate of the first BJT is connected to a second gate of the second BJT.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the bandgap circuit comprises a base current cancellation circuit.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the PTAT control circuit further comprises a bias gain circuit.


Aspects of the present disclosure include a scalable proportional-to-absolute-temperature (PTAT) hybrid circuit, comprising a bias mirror circuit having a zero temperature coefficient (ZTC) current source configured to induce a ZTC current, a PTAT control circuit having two or more first source transistors, a first BJT connected to one of the two or more first source transistors, a first variable resistor connected to the first BJT, a first transistor connected to the first variable resistor, wherein the first BJT, the first variable resistor, and the first transistor are connected in series, a second transistor, a second variable resistor connected to a drain terminal of the second transistor and a first base of the first BJT, a third variable resistor connected to the second variable resistor, wherein the second transistor, the second variable resistor, and the third variable resistor are connected in series, a bandgap circuit having a second BJT and a third BJT, wherein a second base of the second BJT and a third base of the third BJT are connected to the second variable resistor and the third variable resistor, a fourth variable resistor connected to the second BJT of the bandgap circuit, and a third transistor connected to the fourth variable resistor, and a hybrid circuit.


Aspects of the present disclosure include the PTAT hybrid circuit above, further including two or more second source transistors, wherein a drain of one of the two or more source transistors is connected to a second collector of the second BJT.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, further including two or more third source transistors, wherein a drain of one of the two or more source transistors is connected to a third collector of the third BJT.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, further comprising a base current cancellation circuit connected to the second base of the second BJT and the third base of the third BJT.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the first transistor and the third transistor are matched in size.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein a first width of the second BJT is twice a second width of the third BJT.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, further comprising a bias gain circuit.


Aspects of the present disclosure include any of the PTAT hybrid circuits above, wherein the first variable resistor, the second variable resistor, the third variable resistor, and the fourth variable resistor are polysilicon variable resistors.


Aspects of the present disclosure include a method of providing a hybrid current by a scalable proportional to absolute temperature (PTAT) hybrid circuit, comprising: providing a zero temperature coefficient (ZTC) current, generating, based on the ZTC current, a PTAT current with a slope having a non-zero value, altering the PTAT current by at least scaling the PTAT current or changing the slope of the PTAT current to generate an altered PTAT current, and outputting a larger current of the ZTC current and the altered PTAT current as a hybrid current.


Aspects of the present disclosure include a hybrid circuit, including a first current sink configured to sink a zero temperature coefficient (ZTC) current provided by a ZTC current source, a second current sink configured to sink a positive temperature coefficient (PTC) current provided by a PTC current source, a first transistor configured to provide a first current having a first current magnitude of zero in response to the ZTC current being larger than the PTC current or a second current magnitude of a difference between the PTC current and the ZTC current in response to the PTC current being larger than the ZTC current, a second transistor configured to provide a second current having a third current magnitude of the ZTC current in response to the PTC current being larger than the PTC current or a fourth current magnitude of the PTC current in response to the ZTC current being larger than the ZTC current, a third transistor configured to provide a third current mirroring the ZTC current, a fourth transistor configured to provide a sum current of the first current and the third current, and a current mirror configured provide a hybrid current mirroring the sum current.


Aspects of the present disclosure include the aspect above, further including the ZTC current source and the PTC current source.


Aspects of the present disclosure include any of the aspects above, wherein the ZTC current source comprises a plurality of current sources configured to each provide a corresponding source current having a different temperature coefficient of a plurality of temperature coefficients.


Aspects of the present disclosure include any of the aspects above, wherein the PTC current source comprises a plurality of current sources configured to each provide a corresponding source current having a different temperature coefficient of a plurality of temperature coefficients.


Aspects of the present disclosure include any of the aspects above, further including a plurality of current sources configured to each provide a corresponding source current having a different temperature coefficient of a plurality of temperature coefficients.


Aspects of the present disclosure include any of the aspects above, further including a multiplexer configured to receive one or more source currents of the plurality of current sources, combine the one or more source currents as a combined current, and output the combined current as the PTC current or the ZTC current.


Aspects of the present disclosure include any of the aspects above, further including a temperature sensor configured to measure a temperature associated with the hybrid circuit, and output an indication indicating the temperature measured by the temperature sensor.


Aspects of the present disclosure include any of the aspects above, further including a decision circuit configured to select the one or more source currents based at least partially on the indication.


Aspects of the present disclosure include a hybrid circuit including a first current sink connected to a zero temperature coefficient (ZTC) current source, corresponding gate terminals of a second transistor and a third transistor, and a ground terminal, a second current sink connected to a positive temperature coefficient (PTC) current source, a corresponding gate terminal of a first transistor, and the ground terminal, the first transistor connected to a corresponding drain terminal of the second transistor, a corresponding drain terminal of the third transistor, a corresponding drain terminal of a fourth transistor, and the ground terminal, the second transistor connected to the ZTC current source, the PTC current source, a corresponding gate terminal of the first current sink, a corresponding gate terminal of the second current sink, the corresponding gate terminal of the first transistor, the corresponding gate terminal of the third transistor, and the ground terminal, the third transistor connected to the ZTC current source, the corresponding gate terminal of the first current sink, the corresponding gate terminal of the second transistor, a corresponding drain terminal of the first transistor the corresponding drain terminal of the fourth transistor, and the ground terminal, the fourth transistor connected to a voltage supply, a corresponding gate terminal of a current mirror, the corresponding drain terminal of the first transistor, and the corresponding drain terminal of the third transistor, the current mirror connected to the voltage supply.


Aspects of the present disclosure include the aspect above, wherein the first transistor is configured to provide a first current having a first current magnitude of zero in response to the ZTC current being larger than the PTC current, or a second current magnitude of a difference between the PTC current and the ZTC current in response to the PTC current being larger than the ZTC current.


Aspects of the present disclosure include any of the aspects above, wherein the second transistor is configured to provide a second current having a third current magnitude of the ZTC current in response to the PTC current being larger than the PTC current, or a fourth current magnitude of the PTC current in response to the ZTC current being larger than the ZTC current.


Aspects of the present disclosure include any of the aspects above, wherein the fourth transistor is configured to provide a sum current of the first current and the third current.


Aspects of the present disclosure include any of the aspects above, wherein the current mirror is configured provide a hybrid current mirroring the sum current.


Aspects of the present disclosure include any of the aspects above, wherein the third transistor mirror is configured to provide a current mirroring the ZTC current.


Aspects of the present disclosure include any of the aspects above, further including a plurality of current sources connected to a multiplexer, the multiplexer connected one or more of a decision circuit or a temperature sensor, the decision circuit, and the temperature sensor.


Aspects of the present disclosure include any of the aspects above, wherein the plurality of current sources are configured to each provide a corresponding source current having a different temperature coefficient of a plurality of temperature coefficients.


Aspects of the present disclosure include any of the aspects above, wherein the multiplexer is configured to receive one or more source currents of the plurality of current sources, combine the one or more source currents as a combined current, and output the combined current as the PTC current or the ZTC current.


Aspects of the present disclosure include any of the aspects above, wherein the temperature sensor is configured to measure a temperature associated with the hybrid circuit, and output an indication indicating the temperature measured by the temperature sensor.


Aspects of the present disclosure include any of the aspects above, wherein the decision circuit is configured to select the one or more source currents based at least partially on the indication.


Aspects of the present disclosure include a method of providing a hybrid current including sinking, by a first current sink, a zero temperature coefficient (ZTC) current provided by a ZTC current source, sinking, by a second current sink, a positive temperature coefficient (PTC) current provided by a PTC current source, providing, by a first transistor, a first current having a first current magnitude of zero in response to the ZTC current being larger than the PTC current or a second current magnitude of a difference between the PTC current and the ZTC current in response to the PTC current being larger than the ZTC current, providing, by a second transistor, a second current having a third current magnitude of the ZTC current in response to the PTC current being larger than the PTC current or a fourth current magnitude of the PTC current in response to the ZTC current being larger than the ZTC current, providing, by a third transistor, a third current mirroring the ZTC current, providing, by a fourth transistor, a sum current of the first current and the third current, and providing, by a current mirror, a hybrid current mirroring the sum current.


The above detailed description set forth above in connection with the appended drawings describes examples and does not represent the only examples that may be implemented or that are within the scope of the claims. The term “example,” when used in this description, means “serving as an example, instance, or illustration,” and not “preferred” or “advantageous over other examples.” The detailed description includes specific details for the purpose of providing an understanding of the described techniques. These techniques, however, may be practiced without these specific details. For example, changes may be made in the function and arrangement of elements discussed without departing from the scope of the disclosure. Also, various examples may omit, substitute, or add various procedures or components as appropriate. For instance, the methods described may be performed in an order different from that described, and various steps may be added, omitted, or combined. Also, features described with respect to some examples may be combined in other examples. In some instances, well-known structures and apparatuses are shown in block diagram form in order to avoid obscuring the concepts of the described examples.


Information and signals may be represented using any of a variety of different technologies and techniques. For example, data, instructions, commands, information, signals, bits, symbols, and chips that may be referenced throughout the above description may be represented by voltages, currents, electromagnetic waves, magnetic fields or particles, optical fields or particles, computer-executable code or instructions stored on a computer-readable medium, or any combination thereof.


Several aspects of telecommunication systems will now be presented with reference to various apparatus and methods. These apparatus and methods will be described in the following detailed description and illustrated in the accompanying drawings by various blocks, components, circuits, processes, algorithms, etc. (collectively referred to as “elements”). These elements may be implemented using electronic hardware, computer software, or any combination thereof. Whether such elements are implemented as hardware or software depends upon the particular application and design constraints imposed on the overall system.


By way of example, an element, or any portion of an element, or any combination of elements may be implemented as a “processing system” that includes one or more processors. Examples of processors include microprocessors, microcontrollers, graphics processing units (GPUs), central processing units (CPUs), application processors, digital signal processors (DSPs), reduced instruction set computing (RISC) processors, systems on a chip (SoC), baseband processors, field programmable gate arrays (FPGAs), programmable logic devices (PLDs), state machines, gated logic, discrete hardware circuits, and other suitable hardware configured to perform the various functionality described throughout this disclosure. One or more processors in the processing system may execute software. Software shall be construed broadly to mean instructions, instruction sets, code, code segments, program code, programs, subprograms, software components, applications, software applications, software packages, routines, subroutines, objects, executables, threads of execution, procedures, functions, etc., whether referred to as software, firmware, middleware, microcode, hardware description language, or otherwise.


Accordingly, in one or more example embodiments, the functions described may be implemented in hardware, software, or any combination thereof. If implemented in software, the functions may be stored on or encoded as one or more instructions or code on a computer-readable medium. Computer-readable media includes computer storage media. Storage media may be any available media that may be accessed by a computer. By way of example, and not limitation, such computer-readable media may comprise a random-access memory (RAM), a read-only memory (ROM), an electrically erasable programmable ROM (EEPROM), optical disk storage, magnetic disk storage, other magnetic storage devices, combinations of the aforementioned types of computer-readable media, or any other medium that may be used to store computer executable code in the form of instructions or data structures that may be accessed by a computer.


The various illustrative blocks and components described in connection with the disclosure herein may be implemented or performed with a specially-programmed device, such as but not limited to a processor, a digital signal processor (DSP), an ASIC, a FPGA or other programmable logic device, a discrete gate or transistor logic, a discrete hardware component, or any combination thereof designed to perform the functions described herein. A specially-programmed processor may be a microprocessor, but in the alternative, the processor may be any conventional processor, controller, microcontroller, or state machine. A specially-programmed processor may also be implemented as a combination of computing devices, e.g., a combination of a DSP and a microprocessor, multiple microprocessors, one or more microprocessors in conjunction with a DSP core, or any other such configuration.


The functions described herein may be implemented in hardware, software executed by a processor, firmware, or any combination thereof. If implemented in software executed by a processor, the functions may be stored on or transmitted over as one or more instructions or code on a non-transitory computer-readable medium. Other examples and implementations are within the scope and spirit of the disclosure and appended claims. For example, due to the nature of software, functions described above may be implemented using software executed by a specially programmed processor, hardware, firmware, hardwiring, or combinations of any of these. Features implementing functions may also be physically located at various positions, including being distributed such that portions of functions are implemented at different physical locations. Also, as used herein, including in the claims, “or” as used in a list of items prefaced by “at least one of” indicates a disjunctive list such that, for example, a list of “at least one of A, B, or C” means A or B or C or AB or AC or BC or ABC (i.e., A and B and C).


Computer-readable media includes both computer storage media and communication media including any medium that facilitates transfer of a computer program from one place to another. A storage medium may be any available medium that may be accessed by a general purpose or special purpose computer. By way of example, and not limitation, computer-readable media may comprise RAM, ROM, EEPROM, CD-ROM or other optical disk storage, magnetic disk storage or other magnetic storage devices, or any other medium that may be used to carry or store desired program code means in the form of instructions or data structures and that may be accessed by a general-purpose or special-purpose computer, or a general-purpose or special-purpose processor. Also, any connection is properly termed a computer-readable medium. For example, if the software is transmitted from a website, server, or other remote source using a coaxial cable, fiber optic cable, twisted pair, digital subscriber line (DSL), or wireless technologies such as infrared, radio, and microwave, then the coaxial cable, fiber optic cable, twisted pair, DSL, or wireless technologies such as infrared, radio, and microwave are included in the definition of medium. Disk and disc, as used herein, include compact disc (CD), laser disc, optical disc, digital versatile disc (DVD), floppy disk and Blu-ray disc where disks usually reproduce data magnetically, while discs reproduce data optically with lasers. Combinations of the above are also included within the scope of computer-readable media.


The previous description of the disclosure is provided to enable a person skilled in the art to make or use the disclosure. Various modifications to the disclosure will be readily apparent to those skilled in the art, and the common principles defined herein may be applied to other variations without departing from the spirit or scope of the disclosure. Furthermore, although elements of the described aspects may be described or claimed in the singular, the plural is contemplated unless limitation to the singular is explicitly stated. Additionally, all or a portion of any aspect may be utilized with all or a portion of any other aspect, unless stated otherwise. Thus, the disclosure is not to be limited to the examples and designs described herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims
  • 1. A scalable proportional to absolute temperature (PTAT) hybrid circuit, comprising: a bias circuit configured to provide an input current;a PTAT control circuit configured to: generate, based on the input current, a PTAT current with a slope having a non-zero value,provide a reference voltage to alter the PTAT current by at least scaling the PTAT current or changing the slope of the PTAT current to generate an altered PTAT current, andprovide the altered PTAT current;a hybrid circuit configured to: receive a zero temperature coefficient (ZTC) current and the altered PTAT current; andoutput a larger current of the ZTC current and the altered PTAT current as a hybrid current.
  • 2. The scalable PTAT hybrid circuit of claim 1, wherein the PTAT control circuit is further configured to provide the reference voltage by controlling a resistance of one or more variable resistors.
  • 3. The scalable PTAT hybrid circuit of claim 2, wherein the PTAT control circuit comprises two or more first source transistors configured to provide a first source current through a first bipolar junction transistor (BJT), a first variable resistor, and a first transistor.
  • 4. The scalable PTAT hybrid circuit of claim 3, wherein the PTAT control circuit is further configured to control the resistance by: controlling an amount of the first source current; andmirroring a second source current through the one or more variable resistors.
  • 5. The scalable PTAT hybrid circuit of claim 4, wherein the one or more variable resistors include a second variable resistor and a second transistor.
  • 6. The scalable PTAT hybrid circuit of claim 5, wherein the first variable resistor and the second variable resistor maintain a substantially fixed ratio.
  • 7. The scalable PTAT hybrid circuit of claim 3, wherein: the PTAT control circuit further comprises a slope control circuit configured to change the slope of the PTAT current; andthe slope control circuit comprises: a second transistor;a second variable resistor; anda third variable resistor, wherein the second transistor, the second variable resistor, and the third variable resistor are connected in series.
  • 8. The scalable PTAT hybrid circuit of claim 1, wherein the PTAT control circuit is further configured to provide the reference voltage by supplying an external reference voltage.
  • 9. The scalable PTAT hybrid circuit of claim 1, wherein the bias circuit comprises a ZTC current source configured to provide the ZTC current.
  • 10. The scalable PTAT hybrid circuit of claim 1, wherein: the PTAT control circuit comprises a bandgap circuit configured to generate the PTAT current;the bandgap circuit comprises a first bipolar junction transistor (BJT) and a second BJT; anda first gate of the first BJT is connected to a second gate of the second BJT.
  • 11. The scalable PTAT hybrid circuit of claim 10, wherein the bandgap circuit comprises a base current cancellation circuit.
  • 12. A scalable proportional to absolute temperature (PTAT) hybrid circuit, comprising: a bias mirror circuit having a zero temperature coefficient (ZTC) current source configured to induce a ZTC current;a PTAT control circuit having: two or more first source transistors;a first BJT connected to one of the two or more first source transistors;a first variable resistor connected to the first BJT;a first transistor connected to the first variable resistor, wherein the first BJT, the first variable resistor, and the first transistor are connected in series;a second transistor;a second variable resistor connected to a drain terminal of the second transistor and a first base of the first BJT;a third variable resistor connected to the second variable resistor, wherein the second transistor, the second variable resistor, and the third variable resistor are connected in series;a bandgap circuit having a second BJT and a third BJT, wherein a second base of the second BJT and a third base of the third BJT are connected to the second variable resistor and the third variable resistor;a fourth variable resistor connected to the second BJT of the bandgap circuit; anda third transistor connected to the fourth variable resistor; anda hybrid circuit.
  • 13. The PTAT hybrid circuit of claim 12, further comprising: two or more second source transistors, wherein a drain of one of the two or more source transistors is connected to a second collector of the second BJT.
  • 14. The PTAT hybrid circuit of claim 13, further comprising: two or more third source transistors, wherein a drain of one of the two or more source transistors is connected to a third collector of the third BJT.
  • 15. The PTAT hybrid circuit of claim 12, further comprising a base current cancellation circuit connected to the second base of the second BJT and the third base of the third BJT.
  • 16. The PTAT hybrid circuit of claim 12, wherein the first transistor and the third transistor are matched in size.
  • 17. The PTAT hybrid circuit of claim 12, wherein a first width of the second BJT is twice a second width of the third BJT.
  • 18. The PTAT hybrid circuit of claim 12, further comprising a bias gain circuit.
  • 19. The PTAT hybrid circuit of claim 12, wherein the first variable resistor, the second variable resistor, the third variable resistor, and the fourth variable resistor are polysilicon variable resistors.
  • 20. A method of providing a hybrid current by a scalable proportional to absolute temperature (PTAT) hybrid circuit, comprising: providing a zero temperature coefficient (ZTC) current;generating, based on the ZTC current, a PTAT current with a slope having a non-zero value;providing a reference voltage to alter the PTAT current by at least scaling the PTAT current or changing the slope of the PTAT current to generate an altered PTAT current; andoutputting a larger current of the ZTC current and the altered PTAT current as a hybrid current.
CROSS REFERENCE TO RELATED APPLICATIONS

The current application is a continuation-in-part of U.S. patent application Ser. No. 17/901,244 filed Sep. 1, 2022, which claims priority to, and the benefit of, U.S. Provisional Application No. 63/355,347 filed Jun. 24, 2022 and entitled “BIAS CURRENT WITH HYBRID TEMPERATURE COEFFICIENT PROFILE,” the contents of which are hereby incorporated by reference in their entireties.

Provisional Applications (1)
Number Date Country
63355347 Jun 2022 US
Continuation in Parts (1)
Number Date Country
Parent 17901244 Sep 2022 US
Child 18453882 US