The present disclosure relates to drivers for capacitive loads and, more particularly, to single-ended or differential integrated architectures of drivers including voltage transistors.
In the emerging technology known as “Silicon Photonics,” optical devices are integrated with electronic components. A classical “Silicon Photonics” application includes an optical transmitter and an optical receiver and is shown in
Together with optical modulators, optical switches are commonly integrated with electrical functional circuits in a “Silicon Photonic” integrated circuit. Driving these optical modulators commonly may require both high voltage and high speed capabilities, with the constraint of driving large capacitive loads with very short rise and fall time constants.
An example of these functional circuits is the driver for the Mach Zehnder optoelectronic modulator of
In an MZ optoelectronic modulator, such a selective interference is used to modulate a continuous wave laser beam, but the same principle of constructive or destructive interference is commonly used also to perform other optical functions, like optical switches variable attenuators etc.
The driver is commonly required to have high current capability at high power efficiency. If CL is the value of the capacitance of the MZ optoelectronic modulator, the required capability of the output driver may be approximated as follows:
wherein tr and tf are the rise time and the fall time constants, respectively.
Prior art approaches may include high voltage level shifters to convert the CMOS digital input signals, that are constrained within a low voltage supply (Vdd1), to the output buffer voltage levels (Vout) required to drive the Mach Zehnder optoelectronic modulators, as schematically shown in
The MZ optoelectronic modulator is indicated as an exemplary field of application of the applicant's disclosure, though the disclosed architectures may be used also for driving in general any kind of load, in particular other capacitive loads and not exclusively MZ optoelectronic modulators.
A flexible and cost efficient driver architecture may be adapted to drive capacitive loads, such as, for example, a Mach Zehnder optoelectronic modulator.
The driver architecture may comprise low-voltage transistors and may generate a high output driving voltage with a large swing without requiring a high-voltage level shifter. Single-ended and differential architectures of an integrated CMOS driver architecture, particularly suited to drive a substantially capacitive load, such as, for example, a Mach Zehnder optoelectronic modulator, are disclosed.
Fully integrated single-ended and differential CMOS driver architectures suitable for realizing high speed driving stages of different types of loads, in particular, of a Mach Zehnder optoelectronic modulator or of distributed fully differential Mach Zehnder optoelectronic modulators, which show a dominant capacitive load impedance, are shown.
An input inverter including the transistors M1-M2 (M′1-M′2) is driven by a CMOS compatible switching input signal VIN (V′IN). An integrated capacitor C (C′) is pre-charged at a desired voltage equal to Vref−Vth, wherein Vth is the threshold voltage of the cascode stage M3 (M′3), during one semi-period of the input square waves. In this way, the working point of the cascode stage M3 (M′3) switches from a deep cutoff condition to a functioning condition close to the interdiction region, in order to restore the initial charge of the capacitor C. Whenever the output of the inverter is switched to the low voltage supply Vdd1, the switching network M4, M5 and M6 (M′4, M′5 and M′6) is configured to force at a voltage close to Vdd1+Vref−Vth the gate of the single high-voltage transistor M9 (M′9), that functions as an active load, thus causing a great overdrive to the transistor M9 (M′9). The class AB amplifier, comprising by the three transistors M9, M8 and M7 (M′9, M′8 and M′7), ensures an output peak voltage equal to:
Vdd1+Vref−Vth−VgsM9;
wherein VgsM9 is the gate-source voltage on the transistor M9.
The Vout peak could also be programmable by adjusting the reference voltage Vref. This last feature may be desirable also for calibration purposes. The high efficiency (class AB) and cross-conduction of the three output transistors are optimized by calibrating the delay D (D′) according to the characteristics of the load in order to turn-on the transistors M7 and M8 (M′7 and M′8) only when M9 (M′9) has turned off. The two transistors M5 (M′5) and M6 (M′6) of the switching network are used to ensure a fast discharge of the gate-source capacitance of M9 (M′9).
The time graphs of
When the input voltage VIN (V′IN) switches low, the voltage VA (V′A) switches high and the control terminal of the active load M9 (M′9) is disconnected from ground. Therefore, the switch M4 (M′4) turns on and the voltage VB (V′B) equals the voltage VA (V′A). After a certain time delay, determined by the delay D (D′), has elapsed, the transistor M7 (M′7) and thus also the transistor M8 (M′8) turn off. Accordingly, the output voltage Vout (V′out) on the supplied capacitive load increases and becomes practically equal to the voltage VB (V′B), i.e. in practice, equal to the voltage VA (V′A) (i.e. determined by the reference voltage Vref (V′ref)). During this phase, the supplied capacitive load is charged through the transistor M9 (M′9), thus the rise time tr of the output voltage may be finely determined by fixing the resistance of the transistor M9 (M′9) in a conduction state.
When the input voltage VIN (V′IN) switches high, the voltage VA (V′A) switches low at a voltage slightly smaller than the reference voltage Vref (V′ref) in a time interval determined by the recovery time of the transistor M1 (M′1). Therefore, the transistors M5 (M′5) and M6 (M′6) of the switching network turn on, the control terminal of the active load M9 (M′9) is grounded and the transistor M4 (M′4) is off. After a certain time delay, determined by the delay D (D′), has elapsed, the transistor M7 (M′7) and thus also the transistor M8 (M′8) turn on, thus the output voltage Vout on the supplied capacitive load decreases. During this phase, the supplied capacitive load is discharged through the transistors M8 (M′8) and M7 (M′7), thus the fall time tf of the output voltage may be finely determined by fixing the resistance in conduction state of these transistors.
The transistors may be sized to get the desired output peak current and the desired rise and fall time simply by adjusting the aspect ratio of the transistors M7(M′7) and M9 (M′9) and the delay D (D′). In order to limit the total in-out current capability, a series resistor R may be connected in series to the supplied load, as shown in
The disclosed approach does not need any type of level shifter to adapt the low voltage input signal to the output buffer, furthermore it allows Vout peak programmability through a reference voltage Vref, that may be easily controlled by a digital-to-analog converter. Moreover, the disclosed architectures have a low power consumption and a high power efficiency. The claims as filed are integral part of this description and are herein incorporated by reference.
Number | Date | Country | Kind |
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VA2010A0091 | Dec 2010 | IT | national |
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Number | Date | Country | |
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20150301362 A1 | Oct 2015 | US |
Number | Date | Country | |
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Parent | 13989488 | US | |
Child | 14788724 | US |