This paper presents two high-voltage circuits used in power management, a switching driver for buck converter with optimized on-resistance and a low dropout (LDO) voltage regulator with 2-stacked pMOS pass devices. The circuit design is based on stacked MOSFETs, thus the circuits are technology independent.
High-voltage drivers with stacked devices suffer from slow switching
characteristics. In this paper, a new concept to adjust gate voltages of
stacked transistors is introduced for reduction of on-resistance. According
to the theory, a circuit is proposed that drives 2 stacked transistors of a
driver. Simulation results show a reduction of the on-resistance between
27 and 86 % and a reduction of rise and fall times between
16 and 83 % with a load capacitance of 150 pF at various supply
voltages, compared to previous work. The concept can be applied to each
high-voltage driver that is based on a number (
The high voltage compatibility of the low drop-out voltage regulator (LDO) is established by a 2-stacked pMOS transistors as pass device controlled by two regulators: an error amplifier and a 2nd amplifier adjusting the division of the voltages between the two pass transistors. A high GBW and good DC accuracy in line and load regulation is achieved by using 3-stage error amplifiers. To improve stability, two feedback loops are utilized.
In this paper, the 2.5 V I/O transistors of the TSMC 65 nm CMOS technology are used for the circuit design.
Power management plays an increasing role in electronic systems for consumers, sensors and automotive electronics. However, the standard transistors of nanometer CMOS technologies are only capable to handle low voltages within technology limits and are therefore not compatible with voltages of standard device interfaces and batteries. Thus one common method to design high-voltage circuits is to use high-voltage transistors, which are technology dependent (Bandyopadhyay et al., 2011). In contrast, high-voltage circuits based on stacked low-voltage CMOS transistors are more efficient because of their full compatibility with scaled technologies (Serneels and Steyaert, 2008; Nam et al., 2012; Bradburn and Hess, 2010).
High voltage circuits using stacked devices are a problem, when fast switching or high currents are required. Therefore this paper summarizes the design of two important high voltage circuits for power management, a driver for switching applications (Pashmineh et al., 2013b, c) and a low-dropout voltage regulator (Pashmineh et al., 2013a), both based on stacked transistors. The voltage between terminals of each transistor have been kept within the technology limit.
This work is organized as follows: Sect. 2 describes the structure and operation of a high-voltage driver based on stacked standard CMOS transistors. For reducing the on-resistance of drivers, a theory to calculate gate voltages of stacked transistors to drive the maximum drain current is presented. According to the theory a circuit design methodology is described to generate these voltages. Section 3 introduces the structure and operation of an LDO based on 2-stacked pMOS pass transistors. The circuit design of two regulators, which control the pass transistors, thus regulate the output and the voltages between the two pass devices, is described. Section 4 presents the simulation results of the proposed LDO and a 2-stacked CMOS driver in 65 nm TSMC technology. The results demonstrate a significantly low dropout voltage of the LDO and considerably improved rise and fall times of the driver. Finally, conclusions are given.
Drivers are one of the most important circuit blocks used in power management to switch converters and amplifiers.
In this paper, the proposed high-voltage drivers are based on stacked low-voltage standard CMOS transistors and are technology independent. Their disadvantage however, is that depending on the number of stacked transistors, switching speed may not satisfy requirements because of raised on-resistance of the pull-up and pull-down driver transistors, resulting in slower charge and discharge characteristics of capacitive output nodes.
This work focuses on reduction of the on-resistance of high-voltage drivers. In the following sections a new circuit topology for high-voltage drivers with a minimum on-resistance will be introduced.
A high-voltage driver based on stacked low-voltage standard CMOS transistors is shown in Fig. 1.
A high-voltage
The number of stacked transistors depends on the supply voltage, because the
voltage between the terminals of each standard transistor has to be equal to
or less than the nominal operating voltage Vn. With a supply voltage of VHDD,
which is in the range of
Node voltages characteristics of a
The driver is controlled by two input signals. The first is Vin, which varies between the ground and the nominal operating voltage Vn and switches the first nMOS transistor Mn1. The second input signal Vpin, which is level shifted from Vin and varies between VHDD–Vn and VHDD, switches the first pMOS transistor Mp1.
The main challenge in designing high-voltage drivers is the generation of gate voltages of cascode transistors of the stack (Mn2…Mnk, Mp2…Mpk), which need to fulfil two requirements.
First, the transistor in the stack of the driver output must be switched in
a way that the voltage between the terminals of each transistor is kept
within the technological limits. Second, the driver should pull-up and
pull-down with the maximum possible current by setting the appropriate gate
voltages for each of the
Therefore a theory describing the optimal gate drive voltages of the
According to the theory, external circuits (GCnk and GCpk) have been designed to generate these voltages (Fig. 1). This will be fully described in the following sections.
In this paper, the gate voltages of
First, the gates of the
The calculation has been performed for both closed (1) and open (2)
scenarios:
Operation in on-condition for a maximum drain current at an input signal
of 2.5 V, which switches the driver on. The gate voltages of nMOS
transistors have been calculated to switch the corresponding nMOS
transistors on, enabling a maximum drain current and a minimized
on-resistance of the pull-down path. As a result the driver's output can be
discharged to the ground. Operation in off-condition at an input signal of 0 V, which switches the
first nMOS transistor off. The calculated gate voltages of this condition
turn off the respective nMOS transistors. As a consequence, the output can
be charged to the high-voltage VHDD.
In both cases, the voltages between each transistor's terminals were kept
within the technologically required range.
In the next sections, both conditions are described in further detail.
In this case, the input signal is logical high, which is 2.5 V in this work, turning transistor Mn1 on. The gate voltages of the other transistors have been calculated to switch the corresponding transistors on and also to drive a maximum drain current. The driver output is discharged from the high-supply voltage VHDD to the ground.
Node Voltages of 3-stacked NMOS driver (on-condition, VHDD
The characteristics of the calculated gate voltages of 2-, 3-
and 4-stacked nMOS devices are mapped over the driver output voltages for
maximum drain currents as depicted in Fig. 2a, b and c. The driver has a
high supply voltage, which is
The calculated results prove that the source node voltage of each nMOS
transistor is proportional to the driver's output voltage. The gate terminal
has an offset to the source voltage, which is equal to the nominal operating
voltage (2.5 V). Due to this, the gate, drain and source voltage of
each nMOS transistor can be described as functions of the output voltage, as
shown in the following equations:
According to the above equations, the relations between node and output
voltages of a 3-stacked nMOS driver can be expressed with the following
conditions:
Vs2 and Vs3 are the source, Vg2 and Vg3 the gate and Vd2 and Vd3 the drain node voltages of the 2nd and 3rd nMOS transistor respectively. The above relations of node voltages correspond with the calculation results of a 3-stacked nMOS driver in Fig. 2b.
The gate voltages are calculated for a driver with a high supply voltage,
which is
From the calculation results of the required gate voltages of
an
Node Voltages of 3-stacked NMOS driver (off-condition).
Table 1 shows the results of
With an input signal of 0 V, which switches the first nMOS transistor off, the input signal of the pull-up path Vpin is equal to VHDD–Vn, which switches the first pMOS transistor on.
The gate voltages of the other pMOS transistors have been calculated for
switching the corresponding transistor on and also driving a maximum drain
current in the pull-up path to charge the output from the ground to the
high-supply voltage VHDD.
The calculated results of gate and source voltages of the pMOS transistors,
which are related to the output voltage, can be described with the following
functions:
Number
In off-condition the input signal Vin is 0 V, which switches the first nMOS transistor off. The gate voltages of the other nMOS transistors need to be adjusted in such a way that the corresponding transistors can be switched off as quickly as possible in order to avoid shot-through currents in the push-pull driver and to maintain the voltage between the nodes of each transistor within the technology limit. As a result, the output load will be charged with the highest possible rate.
To meet the above conditions, a stacked transistor must be switched off, if
the source node voltage rises to the limit:
In the off-state of each transistor, the gate-source voltage must be equal to or less than the threshold voltage.
Figure 4 shows the calculated gate and source voltages of a 3-stacked nMOS driver with a supply voltage of 7.5 V. The second nMOS transistor switches off at an output voltage of 2.5 V and the third at 5 V. Finally the driver output node is charged to 7.5 V.
Circuits to generate gate voltages of a 3-stacked NMOS driver.
A circuit design methodology for generation of voltages according the theoretical results is described in this section.
The circuit that generates the gate voltages of the 2nd nMOS
transistor Vg2 is depicted in Fig. 5a. As can be seen, the circuit is supplied
by VD2 and contains 3 pMOS transistors (mp21, mp22 and mp23) in series. The
transistor mp23 is gate-drain connected and the gate nodes of the other
transistors are determined by the voltages of the driver nodes Vd1 and Vd2 (drain
voltages of the driver transistors Mn1 and Mn2 in the pull-down path). The
dimensions of mp21 have been set for operation of transistor mp22 in saturation
region during the on-condition. The dimensions of the transistors mp22 and
mp23 are the same. Therefore, node n1 between mp22 and mp23 (Fig. 5a) supplies the
required gate voltage Vg2. According to the on- and off-conditions, the supply
voltage of this circuit (VD2) switches between 5 V–
The expression in Eq. (10) describes the required voltage of Vg2 during the
on-condition. It is derived from two equations with equal drain currents of
mp22 and mp23 in the saturation region.
Principe of a LDO with two cascaded pass devices PD1 and PD2.
Circuit of the regulator 1.
In the on-condition, when the high supply voltage of driver VHDD is
The current Imp23 of the transistor mp23 begins to flow when the gate-source voltage of mp23 exceeds its threshold voltage. In this case, the desired voltage of 5 V at node n1 is limited to 5 V–Vth. To solve this problem, a pMOS transistor (such as P1 in Fig. 6) has been connected in parallel to mp3. The gate of this transistor (P1) is biased by Vb1. When the nominal voltage is not an exact fraction of the high supply voltage VHDD, this parallel pMOS transistor (P1) enables the generated voltage at the node n1 to approach the conditions in Eq. (7).
Circuit of the regulator 2.
Figure 5b shows a circuit generating the gate voltage (Vg3) of the third nMOS
transistor. This gate control circuit GCn3 comprises 5 pMOS transistors
(mp31-mp35) in series, with a supply voltage VD3, which switches
between 7.5 V–
In on-condition, the voltage of the node 3 (n3) can be calculated from
the drain current equations of mp33, mp34 and mp35, which are operated in saturation
region:
When the nominal voltage Vn is a fraction of the high-supply voltage VHDD, the
supply voltage VD3 is switched to 7.5 V in on-condition. The generated
voltage Vg3 (Eq. 12) follows Eq. (2). By connecting 2 pMOS transistors in
series (P2 and P3 in Fig. 6), parallel to the gate-drain connected pMOS
(mp34 and mp35), the generated voltage Vg3 can approach condition of Eq. (7), when
VHDD is unequal to
Comparison results between this work (A) and model B.
Transistor dimensions width/length (
Transistor dimensions width/length (
2-stacked CMOS HV-driver with gate-control circuits.
Simulation results of a 2-stacked CMOS driver
Simulation results of this work in comparison with B.
With a similar procedure a circuit generating the gate voltage of the
This problem can be solved by connecting pMOS transistors in series biased
by reference voltages, in parallel to the gate-drain connected pMOS
transistors. When the driver's supply voltage VHDD is not equal to
The circuits generating gate voltages of pMOS transistors in the pull-up driver are made up of the complement form of the described circuits. Thus nMOS transistors are used instead of pMOSs (mpk), which are used in the proposed 2-stack CMOS high-voltage driver in 65 nm technology (Fig. 10).
In this work, a low drop-out voltage (LDO) is designed, as can be seen in Fig. 7. It is supplied with 5 V and based on standard low-voltage transistors in 65nm TSMC technology with a nominal voltage of 2.5 V (Dearn et al., 2005; D'Souza et al., 2011; Kuttner et al., 2011). Two-stacked pMOSs (PD1 and PD2) are used as pass transistors. The circuit contains two regulators (Regulators 1 and 2) connected to the gates of pass transistors, respectively. Regulator 1 controls the output voltage (VOUT) according to the reference voltage (Vref) by controlling the first pass transistor PD1. Regulator 2 controls the gate of the second pass transistor (PD2) the partitioning of the high voltage between supply and output between the pass devices PD1 and PD2. In the following sections, the design of both regulators will be described in more detail.
DC simulation of the LDO.
AC characteristics of the open loop (REG1, P1, load).
Line regulation (VOUT) with 500 mV input voltage step.
Line regulation (
Load regulation (VOUT) with 250 mA load current step.
Load regulation (
Figure 8 shows Regulator 1 composed of a 3-stage amplifier. It is supplied by low voltage VCC of 2.5 V and high voltage VDD of 5 V while comparing the output Vout with a reference voltage Vref. The first stage is a single-ended differential amplifier (AMP1) with a pMOS current mirror as active load. Furthermore, the differential amplifier is supplied by the (nominal) low voltage of 2.5 V. To avoid an overvoltage between transistor terminals, both high-voltage input signals (Vout and Vref) are reduced to lower voltages by voltage dividers.
The second stage, a common source amplifier (AMP2), is also supplied with a low voltage VCC. It drives the 3rd stage, consisting of a common source amplifier and a MOS diode load operating as a buffer (BUF). It provides both level shifting and low impedance drive to the pass device PD1. This stage utilizes stacked transistors. The first is a main transistor of the CS amplifier, and the 2nd and 3rd transistor shield high voltage. The 4th transistor is a pMOS diode connected to PD1 and controls the drain current of this pass transistor of the LDO.
Figure 9 shows Regulator 2. This circuit regulates the 2nd-stacked pass transistor PD2 and the actual voltage between PD1 and PD2 (VMID) by comparing this voltage with VMID_REF. VMID_REF is the voltage generated by a voltage divider between the high voltage input VDD and the output VOUT.
Regulator 2 consists of two parts: a voltage to current converter input with high-to-low voltage level shift function, a differential current to voltage converter and a 3-stage error amplifier. To simplify the design of this high-voltage circuit, the high input voltages VMID and VMID_REF are converted into currents by the voltage to current converter.
The currents are then subtracted from each other in a differential current
to voltage converter
Transistor dimensions, capacitor and resistor values of the designed circuits are given in Tables 3 and 4.
In this section, the simulation results of both proposed high-voltage circuits (the high-voltage driver based on 2-stacked CMOS and the LDO with 2-stacked pass transistors), are presented and described.
Figure 10 shows the proposed 2-stack CMOS high-voltage driver in 65 nm technology. Vin is the input signal of the pull-down path and Vpin, level-shifted from Vin, switches the pull-up path. The simulation results of this circuit, supplied with 4.5 and 5 V are shown in Fig. 11a and b, respectively. Figure 11a shows that at logic low input the gate voltage Vg2 switches transistor Mn2 off by reducing the gate-source voltage below Vth. The output voltage VOUT has been charged to 5 V and the source node Vs2 to 2.5 V, which is half of the output voltage. When the input signal is 2.5 V, the output is discharged from 5 V and Vs2 from 2.5 to 0 V. The simulation results in Fig. 11a and b show that the voltage Vg2 follows the rule according to Eqs. (2) and (7) respectively.
Figure 12 shows the output and the drain current of this work (A) in comparison to previous work B (Serneels and Steyaert, 2008) with a supply voltage of 4 V. In the previous work, the gate voltages of the second nMOS and pMOS transistors of a 2-stacked CMOS driver are fixed to the high level of the input signal. The principle of the work B is applied on a 2-stack CMOS driver in 65 nm technology with a nominal voltage of the I/O devices of 2.5 V. The comparison between the results of the rise/fall time and on-resistance of both works with different supply voltages (3.5, 4, 4.5 and 5 V) are given in Table 2. The initial pull-down and pull-up on-resistances of this work are respectively 27–30 and 39–86 % less than B. The rise and fall times of the output voltage of this paper are improved by approximately 24–83 and 16–20 % with a load capacitance of 150 pF. This indicates that the driver is able to switch faster.
The voltage between each transistor's terminals was kept within the nominal technology limit.
Figure 13 shows the simulation results of the proposed LDO output vs. the load current for different values of reference voltages VREF. The output VOUT is maintained constant according to VREF. As the supply voltage drops from 5 to 3.5 V, the output remains constant and follows the reference voltage VREF.
Figure 14 shows the frequency response of the Regulator 1. The AC characteristics are
obtained from the open loop gain and phase at the operating
point VDD
The simulation results of the line regulation response of the proposed LDO
are depicted in Figs. 15 and 16. The high-supply voltage VDD is varied
from 4.5 to 5 V with rise and fall slew rates of 50 mV
The load regulation response is obtained by the load current ILOAD varied
from 5 to 250 mA with rise and fall slew rates of 50 mA
The load regulation transient response and the steady-state output
In this paper, two high-voltage circuits for power management, a high-voltage driver and an LDO, are presented. The circuits are based on stacked transistors and are compatible with scaled technologies.
For high-voltage drivers, a theory to calculate and design circuits generating gate voltages of stacked transistors to drive a maximum drain current is introduced. By optimally adjusted gate voltages, the driver output provides a minimum on-resistance.
The theory is applied to a 2-stack CMOS driver in 65 nm with a nominal
voltage of 2.5 V. Considering the simulation results the gate and source
voltages follow the theoretical optimum characteristics. The rise and fall
times of the output are improved considerably, which indicate a reduced
on-resistance driver. The principle can be applied to
As a second high-voltage circuit for power management, a high-voltage LDO voltage regulator is presented. The circuit is based on the same technology using stacked 2.5 V transistors. An error amplifier controls the main pass transistor and regulates the output voltage. The error amplifier uses 3 stages and has 2 feedback loops, achieving high DC accuracy, as well as good AC and transient characteristics. The second of the stacked pass transistors is controlled by a separate amplifier with lower bandwidth, allowing seamless operation from power down to high load currents. The amplifier equalizes voltage drop across both pass transistors. Therefore, transistor lifetime can be extended and the overvoltage between transistor terminals is avoided. The LDO with stacked devices is suitable for the integration of power management on standard CMOS technologies.
The authors would like to thank Stefan Bramburger for his contribution to design and layout of the LDO and Kay-Uwe Schulz for supporting the measurement setup and the printed circuit board. This work is funded by the German National Science Foundation (DFG).Edited by: B. Wicht Reviewed by: two anonymous referees