Voltage level shifter and phase splitter

A high speed voltage level shifter and phase splitter circuit is provided. The voltage level shifter and phase splitter circuit includes an input signal and a first input inverter stage that receives the input signal and provides an inverted delayed out of phase signal to the input signal. A buffer stage receives the input signal and provides a buffered delayed in phase signal to the input signal. A first constant current source is coupled between the first input inverter stage and the buffer stage. A first output inverter stage is coupled to the first constant current source and provides a voltage level shifted and out of phase signal to the input signal. A second constant current source is coupled between the first input inverter stage and the buffer stage having an opposite polarity as the first constant current source. A second output inverter stage is coupled to the second constant current source and providing a voltage level shifted and in phase signal to the input signal.

FIELD OF THE INVENTION

The present invention relates generally to a high speed voltage shifter and phase splitter circuit.

DESCRIPTION OF THE RELATED ART

FIGS. 1 and 2 together illustrate a prior art voltage level shifter for providing first and second phase outputs. In FIG. 1 , an input voltage A 1 IN is applied to the voltage level shifter to produce a first phase output D. In FIG. 2 , an input voltage A 21 N is applied to the voltage level shifter to produce a second phase output D 2 . The input voltage A 1 IN and the input voltage A 21 N are out of phase with each other.

Referring to both FIGS. 1 and 2 , the respective input voltages A 1 IN and A 21 N are applied to input inverter stages coupled to a first voltage supply VDD. Node B 2 is inverter delayed by a single inverter stage formed of P-channel field effect transistor (PFET) P 1 and an N-channel field effect transistor (NFET) N 1 and out of phase to A 1 IN in FIG. 1 or A 21 N in FIG. 2 . Node BBB 2 is buffer delayed by a pair of parallel inverters formed by P 2 , N 2 and P 3 , N 3 and is in phase with A 1 IN in FIG. 1 or A 21 N in FIG. 2 . The input inverters NFETs N 1 and N 3 are connected to a common node labeled NET 3 and to a respective pair of NFETs N 5 , N 6 and N 7 , N 8 . Node NET 3 is coupled to a second voltage supply VDDQ via a pair of NFETs N 9 , N 10 . Output inverter stages formed of P 11 , N 11 , and P 12 , N 12 coupled between a second voltage supply VDDQ via a pair of PFETs P 13 , P 14 and ground via a pair of NFETs N 13 , N 14 . PFET P 13 is always turned on by a low enable input ENBAR applied to the gate input. NFET N 14 is always turned on by a high enable input ENN applied to the gate input. NFETs N 6 and N 8 are turned on by a high enable input ENN applied to the gate input, which together with NFETs N 5 and N 7 help to pull node NET 3 low. Output inverter stages formed of P 11 , N 11 , and P 12 , N 12 respectively receive a gate input of BBB 2 and B 2 .

FIGS. 4 , 5 , and 6 illustrate voltage waveforms of the prior art voltage level shifter of FIGS. 1 and 2 with voltage shown relative the vertical axis and time shown relative to the horizontal axis. In FIG. 4 , voltage waveforms A 1 IN, B 2 , BBB 2 , and NET 3 are illustrated. FIG. 5 provides an expanded view of the voltage waveforms A 1 IN, B 2 , BBB 2 , and NET 3 of FIG. 4 . FIG. 6 illustrates the input voltage waveform A 1 IN together with outputs D and D 2 of FIGS. 1 and 2 . The prior art level shifter has an operational time delay that is much greater than can be used effectively for high speed applications. Another problem with the prior art level shifter is that balanced output is not provided. As illustrated in FIG. 6 , with VDDQ of 1.5 Volts, the cross point of outputs D and D 2 is at about 1.07 Volts, rather than VDDQ/ 2 or 0. 75 Volts.

A need exists for an improved high speed voltage shifter and phase splitter circuit. It is desirable to provide such a voltage shifter and phase splitter circuit that achieves balanced outputs as well as a small delay. It is also desirable to provide such a voltage shifter and phase splitter circuit that minimizes the number of devices required to produce two phases so that less physical area is required.

SUMMARY OF THE INVENTION

A principal object of the present invention is to provide an improved high speed voltage shifter and phase splitter circuit. Other important objects of the present invention are to provide such voltage shifter and phase splitter circuit substantially without negative effect and that overcomes many of the disadvantages of prior art arrangements.

In brief, a high speed voltage level shifter and phase splitter circuit is provided. The voltage level shifter and phase splitter circuit includes an input signal. A first input inverter stage receives the input signal and provides an inverted delayed out of phase signal to the input signal. A buffer stage receives the input signal and provides a buffered delayed in phase signal to the input signal. A first constant current source is coupled between the first input inverter stage and the buffer stage. A first output inverter stage is coupled to the first constant current source and provides a voltage level shifted and out of phase signal to the input signal. A second constant current source is coupled between the first input inverter stage and the buffer stage having an opposite polarity as the first constant current source. A second output inverter stage is coupled to the second constant current source and providing a voltage level shifted and in phase signal to the input signal.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Having reference now to the drawings, in FIG. 3 there is shown a combined voltage level shifter and phase splitter circuit generally designated by the reference character 300 in accordance with the preferred embodiment.

In accordance with features of the preferred embodiment, combined voltage level shifter and phase splitter circuit 300 achieves better performance, balanced output, less FETs are used and less physical area is used, as compared to the prior art voltage level shifter of FIGS. 1 and 2 . The voltage level shifter and phase splitter circuit 300 is much faster and can run, for example, at a speed of 1 GHz. Voltage level shifter and phase splitter circuit 300 includes constant current sources and produces substantially balanced outputs of first and second phase outputs D and D 2 .

Voltage level shifter and phase splitter circuit 300 includes a plurality of input inverter stages 302 , 304 , and 306 coupled to a first voltage supply VDD. An input signal A 1 IN, for example, of 0.9V-1.5V is applied to the input inverter stages 302 and 304 . Node B 2 is inverter delayed by the single inverter stage 302 formed of P-channel field effect transistor (PFET) 308 and an N-channel field effect transistor (NFET) 310 and is out of phase to the input signal A 1 IN. Node BBB 2 is buffer delayed by the pair of parallel inverters 304 and 306 formed by 312 , 314 and 316 , 318 and is in phase with the input signal A 1 IN. The input inverter NFETs 310 and 318 are connected to a common node labeled NET 3 and to a respective pair of NFETs 320 , 322 and 324 and 326 . Node NET 3 is coupled to a second voltage supply VDDQ via a pair of NFETs 328 , 330 . An enable input ENN is applied to the gate input of NFETs 322 and 326 and is normally high, which helps NET 3 pull down via NFETs 320 , 322 and 324 and 326 . The input inverter stages 302 , 304 , and 306 and node NET 3 generally correspond to the prior art voltage level shifter of FIG. 1 .

The inverter 302 and buffer stage formed by inverters 304 and 306 are tuned such that delay at node BBB 2 and B 2 is about the same. Voltage for example, of 1.4V-1.6V to be shifted is applied at input VDDQ.

Voltage level shifter and phase splitter circuit 300 includes a pair of constant current sources generally designated by the reference characters 332 and 334 in accordance with the preferred embodiment. A first PFET 336 is coupled between input VDDQ and a node NET 4 . NET 4 is a source connection of a pair of PFETs 338 and 340 of the constant current source 332 . PFET 338 is connected in series with NFETs 342 and 344 . PFET 340 is connected in series with NFETs 346 and 344 . The gates of PFETs 338 and 340 are connected together and connected to the gate of NFET 344 at a node NET 5 . The gate of NFET 342 is connected to node BBB 2 . The gate of NFET 346 is connected to node B 2 . The drain connection of PFET 340 and NFET 346 define an output node NET 6 .

Constant current source 334 is similarly arranged with an opposite polarity connection to nodes B 2 and BBB 2 as the first constant current source 332 . Constant current source 334 includes a source connection of a pair of PFETs 348 and 350 connected to node NET 4 . PFET 348 is connected in series with NFETs 352 and 354 . PFET 350 is connected in series with NFETs 356 and 354 . The gates of PFETs 348 and 350 are connected together and connected to the gate of NFET 354 at a node NET 8 . The gate of NFET 352 is connected to node B 2 . The gate of NFET 356 is connected to node BBB 2 . The drain connection of PFET 350 and NFET 356 define an output node NET 9 .

When ENBAR is low PFET 336 turns on and NET 4 is approximately at VDDQ. PFETs 338 and 340 and PFETs 348 and 350 are self-biased and function as a resistor. In operation, an input signal A 1 IN is applied, node BBB 2 rises following input signal A 1 IN and node B 2 falls. When node BBB 2 rises up to VDD/ 2 and node B 2 falls down to VDD/ 2 , at that time equal amount of current is flowing through NFET 342 and NFET 346 and through NFET 352 and 356 . Such arrangement gives equal amount of current through each leg, producing balanced outputs D and D 2 . In one cycle, node B 2 is low, NFET 346 of current source 332 and NFET 352 of current source 334 turn off. At that time, node BBB 2 is high, NFET 342 of current source 332 and NFET 356 of current source 334 are on. In a next cycle, node B 2 is high, NFET 346 of current source 332 and NFET 352 of current source 334 are on. At that time, node BBB 2 is low, NFET 342 of current source 332 and NFET 356 of current source 334 turn off. NFETs 344 and 354 receiving constant current are constantly on.

A pair of output inverter 358 and 360 is coupled to the nodes NET 6 and NET 9 of the first and second constant current sources 332 and 334 . A PFET 362 and an NFET 364 connected in series between VDDQ and ground forms the output inverter 358 with a gate input connected to NET 6 . The drain connection of PFET 362 and NFET 364 define an output node D 2 . Similarly, a PFET 366 and an NFET 368 forms the output inverter 360 with a gate input connected to NET 9 . The drain connection of PFET 366 and NFET 368 define an output node D.

When A 1 IN goes high, BBB 2 will go high and NFET 356 will turn on and the output D of output inverter 360 is in phase with A 1 IN and voltage level is shifted at VDDQ (1.4V-1.6V). When A 1 IN goes high, B 2 will go low and NFET 346 will turn off and the output D 2 of output inverter 358 is out of phase to A 1 IN and voltage level is shifted at VDDQ.

FIGS. 7 and 8 illustrate voltage waveforms of the combined voltage level shifter and phase splitter 300 in accordance with the preferred embodiment with voltage shown relative the vertical axis and time shown relative to the horizontal axis. FIG. 7 provides an expanded view of the voltage waveforms A 1 IN, B 2 , BBB 2 , and NET 3 . FIG. 8 illustrates the input voltage waveform A 1 IN together with outputs D and D 2 of the combined voltage level shifter and phase splitter 300 of FIG. 3 . Note that the cross point of outputs D and D 2 is at about 0.75 Volts or VDDQ/2, resulting from the constant current sources 332 and 334 in the voltage level shifter and phase splitter 300 . Balanced outputs D and D 2 of the combined voltage level shifter and phase splitter 300 of FIG. 3 are provided with an improvement of 98 pico-seconds in operational time delay as compared to the prior art voltage level shifter of FIGS. 1 and 2 .