A Schmitt Trigger (ST) is a bistable circuit in which the output changes state when the input rises above an upper threshold and again changes state when the input falls below a lower threshold. An ST thus includes hysteresis. The difference between the upper threshold voltage and the lower threshold voltage is the hysteresis voltage. ST circuits are often used as input buffers to an integrated circuit. As an input buffer, the ST circuit differentiates its input signal being a logic “high” versus a logic “low”.
A trend exists towards lower and lower supply voltages. For example, 1.8 V supply voltages are being pushed down to 1.2 V supply voltages. The downward pressure in supply voltages presents a problem for ST circuits in that the hysteresis voltage for many ST circuits is too large to accommodate lower desired supply voltages.
In some examples, a circuit includes a first pair of transistors coupled in series between a supply voltage node and an output node, and a second pair of transistors coupled in series between the output node and a ground node. The circuit further includes a first diode-connected transistor coupled between a first node between the first pair of transistors and the output node, and a second diode-connected transistor coupled between a second node between the second pair of transistors and the output node.
In another example, a circuit includes a first transistor having a first control input, and a second transistor coupled to the first transistor. The second transistor includes a second control input. A controller is configured to control the first and second control inputs. The circuit further includes an input buffer coupled to the controller. The input buffer includes a first pair of transistors coupled in series between a supply voltage node and an output node, a second pair of transistors coupled in series between the output node and a ground node, a first diode-connected transistor coupled between a first node between the first pair of transistors and the output node, and a second diode-connected transistor coupled between a second node between the second pair of transistors and the output node.
In yet another example, a circuit includes first through fourth transistors, The first transistor has a first control input and first and second current terminals. The first current terminal is coupled to a first supply voltage node. The second transistor has a second control input and third and fourth current terminals. The third current terminal is coupled to the second current terminal at a first node. The first and second control inputs are coupled to an input node. The first and second transistors are configured to pull the output node to a logic high level responsive to a voltage on the input node being below a first voltage threshold. The third transistor has a third control input and fifth and sixth current terminals. The fifth current terminal is coupled to the fourth current terminal at an output node. The fourth transistor has a fourth control input and seventh and eighth current terminals. The seventh current terminal is coupled to the sixth current terminal at a second node. The third and fourth control inputs are coupled to the input node. The eighth current terminal is coupled to a second supply voltage node. The third and fourth transistors are configured to pull the output node to a logic low level responsive to a voltage on the input node being above a second voltage threshold. The circuit also includes first and second diode-connected transistors. The first diode-connected transistor is coupled between the output node and the first node. When on, the first diode-connected transistor is configured to impose a voltage on the first node that is lower than the voltage on the first current terminal. The second diode-connected transistor is coupled between the output node and the second node. The second diode-connected transistor, when on, is configured to impose a voltage on the second node that is higher than the voltage on the eighth current terminal.
For a detailed description of various examples, reference will now be made to the accompanying drawings in which:
This disclosure is related to a modified Schmitt Trigger circuit. The modification causes the hysteresis voltage to be smaller than for a conventional ST circuit. For example, rather than having an upper threshold of 1.2 V and a lower threshold of 0.4 V for a conventional ST circuit (i.e., a 800 mV hysteresis voltage), the ST circuit described herein is characterized by a smaller hysteresis voltage (e.g., 80-250 mV). As such, the ST circuit described herein is more suitable for lower voltage operation (e.g., 1.2 V instead of 1.8 V). Further, the quiescent current consumption the described ST circuit is very low.
The description herein refers to transistors. A transistor includes a control input and a pair of current terminals. The control input and current terminals of a metal oxide semiconductor field effect transistor are the transistor's gate, drain, and source terminals, respectively. The control input and current terminals of a bipolar junction transistor are the transistor's base, emitter, and collector terminals, respectively.
M1 and M2 comprise a series-connected pair of transistors. This series pair is connected between a supply voltage node 101 (VDD) and an output voltage node 107 (VOUT). Similarly, M3 and M4 also comprise a series-connected pair of transistors connected between the output voltage node 107 and a ground node 105. The output node 107 is the node interconnecting the drains of M2 and M3. The gates of M5 and M6 are connected to the output node 107. The drain of M5 is connected to the ground node 105 and the drain of M6 is connected to the supply voltage node 101.
M7 and M8 comprise diode-connected transistors. M7 and M8 are oppositely doped (e.g., M7 is a pMOS device and M8 is an nMOS device). The gates of M7 and M8 are connected to their respective drains. The source of M7 is connected to the node interconnecting the drain of M1 to the source of M2 (node A). The source of M8 is connected to the node interconnecting the drain of M4 to the source of M2 (node B). Diode-connected transistors M7 and M8 may comprise low threshold voltage transistors, which are transistors that have a threshold voltage that is less than the threshold voltage of a standard transistor. An example of the threshold voltage for a low threshold voltage transistor is between 0.3V and 0.5V.
Each of the diode-connected transistors M7 and M8 generates a bias voltage (e.g., 0.7 V). The bias voltage from M7 is referred to as V_M7 and the bias voltage from M8 is V_M8. When M6 and M8 are on, which is the case when VOUT is high, the voltage on node B is VDD minus V_M8 (e.g., VDD−0.7V). Similarly, when M5 and M7 are on, which is the case when VOUT is low, the voltage on node A is the ground potential plus V_M7 (e.g., GND+0.7V).
When VIN is low (e.g., ground potential), pMOS devices M1 and M2 are on, and nMOS devices M3 and M4 are off. With M1 and M2 being on, the output node 107 is pulled up to VDD through M1 and M2, and thus VOUT is high. When VIN is high (e.g., VDD), M1 and M2 are off, and M3 and M4 are on. With M3 and M4 being on, the output node 107 is pulled low to ground through M3 and M4 and thus VOUT is low. Transistors M5-M8 cause the circuit to implement an upper threshold and a lower threshold to thereby provide hysteresis. If VIN is low (and VOUT is high), VOUT will not transition to a logic low signal level until VIN exceeds the upper threshold, at which time VOUT becomes a low signal level. As VIN then decreases, VOUT will remain low until VIN falls below the lower threshold, at which time VOUT will be forced high.
As VIN continues to ramp up as shown, M4 will turn on (as shown at 205) before M3 turns on because the source voltage for M4 is smaller than the source voltage for M3, and thus M4 is caused to be turned on with a smaller gate voltage (VIN) than for M3. Once M4 turns on, the voltage on node B drops as shown at 211 due to the current flow from the supply voltage node 101 through M6, M8, and M4 to ground.
As VIN continues to increase, eventually the voltage on the gate-to-source voltage across M3 is high enough to turn M3 on as well, as indicated at 215 in
Meanwhile, while VIN is ramping up with VOUT being high, M5 and M7 are off and M1 and M2 are on, which not only pulls VOUT high but also causes the node A voltage to be high as well (VDD) as shown at 230. Upon VOUT transitioning at 220 to a low level, M5 and M7 turn on, which, as indicated at transition 232, pulls node A to the potential ground plus V_M7 as shown at 235.
The difference between the upper threshold 221 and the lower threshold is the hysteresis voltage (HV) for the disclosed ST circuit. A conventional ST circuit lacks the diode-connected transistors, and thus the corresponding node B voltage at 250 is higher (VDD) than for the disclosed ST circuit (VDD-V_M8). Similarly, the corresponding node A voltage is lower (ground) for a conventional ST circuit than for the disclosed ST circuit (ground+V_M7). Because the upper threshold is lower and the lower threshold is higher for the disclosed ST circuit as compared to the thresholds for a conventional ST circuit, the HV of the disclosed ST circuit of
The current consumption during switching operations of the ST's transistors is mainly driven by the current through transistors M5 and M6 which are directly connected to ground and VDD, respectively. For a conventional ST, the quiescent current is generally not limited by any particular circuit function. However, quiescent current of a conventional ST could be reduced by including a series resistor (instead of M7 and M8, that is, replacing each of M7 and M8 by a resistor). However, in that case the quiescent current linearly scales with the voltage across the resistors. In the ST circuit described herein (e.g.,
In addition to lower current consumption during switching, the current decrease in combination with the smaller hysteresis voltage results in a faster decrease of quiescent current during switching events. This allows for a lower quiescent current consumption for the same input voltage VIN. Alternatively stated, the smaller hysteresis voltage provides for more precise control of the output voltage with the same current consumption.
Other types of buffer circuits include a differential pair precision comparator that includes a bias current. Such circuits are quite accurate but unfortunately have relatively high static current consumption due to the bias current needed for the comparator. As noted above, the bias current consumption of the disclosed ST circuit 100 is relatively low. Further, the disclosed ST circuit 100 does not require a comparator thereby making it a smaller area option. Yet another buffer circuit includes a conventional Schmitt Trigger and multiple inverter stages (and additional transistors) to control feedback loops from the output to the input the input. The disclosed ST 100 of
The output node 107 from ST circuit 100 is provided to an inverter 410, which logically inverts the voltage on node 107 and provides the inverted voltage to a level shifter 420. The inverter 410 further sharpens the edges of the output voltage from the ST circuit 100 and the level shifter adjusts the voltage to a different level.
One more input signals 505 may be provided to the buck converter of
In this description, the term “couple” or “couples” means either an indirect or direct connection. Thus, if a first device couples to a second device, that connection may be through a direct connection or through an indirect connection via other devices and connections. Modifications are possible in the described embodiments, and other embodiments are possible, within the scope of the claims.
This application claims priority to U.S. Provisional Application No. 62/632,234, filed Feb. 19, 2018, which is hereby incorporated by reference.
Number | Date | Country | |
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62632234 | Feb 2018 | US |