XRP7713
Three Channel Digital PWM Step Controller
September 2018
Rev. 1.1.2
GENERAL DESCRIPTION
APPLICATIONS
• Multi Channel Power Supplies
The XRP7713 is a three output pulse-width
modulated (PWM) step-down DC-DC controller
with a built-in LDO for standby power and
GPIOs. The device provides a complete power
management solution in one IC and is fully
programmable via an I2C serial interface.
Independent Digital Pulse Width Modulator
(DPWM) channels regulate output voltages
and provide all required protection functions
such as current limiting and over-voltage
protection.
• Audio-Video Equipment
• Industrial & Telecom Equipment
• Processors & DSPs Based Equipment
FEATURES
• 3 Channel Step Down Controller
− Programmable Output Voltage 0.9V-5.1V
− Programmable 1.5MHz DPWM Frequency
− Integrated FET Drivers
Each output voltage can be programmed from
0.9V to 5.1V without the need of an external
voltage divider. The wide range of the
programmable DPWM switching frequency
(from 300 kHz to 1.5 MHz) enables the user to
optimize between efficiency and component
size. Input voltage range is from 4.75V to
25V.
An I2C bus interface is provided to
program the IC as well as to communicate
with the host for fault reporting and handling,
power rail parameters monitoring, etc.
• 4.75V to 5.5V and 5.5V to 25V Input
Voltage Range
• Up to 5 Reconfigurable GPIO Pins
• Fully Programmable via I2C Interface
• Independent Digital Pulse Width
Modulator (DPWM) channels
• Complete Monitoring and Reporting
• Complete Power Up/Down Sequencing
• Full On Board Protection
OTP, UVLO, OCP and OVP
The device offers a complete solution including
independently programmable: soft-start, softstop, start-up delay and ramp of each PWM
regulator.
• Built-in 3.3V/5V LDO
• PowerArchitect™ Design Software
• Green/Halogen Free 32-pin TQFN
TYPICAL APPLICATION DIAGRAM
Fig. 1: XRP7713 Application Diagram
1/30
Rev. 1.1.2
XRP7713
Three Channel Digital PWM Step Controller
ABSOLUTE MAXIMUM RATINGS
OPERATING RATINGS
These are stress ratings only and functional operation of
the device at these ratings or any other above those
indicated in the operation sections of the specifications
below is not implied. Exposure to absolute maximum
rating conditions for extended periods of time may affect
reliability.
Input Voltage Range..................................... 5.5V to 25V
Input Voltage VIN=VCCA ........................... 4.75V to 5.5V
Junction Temperature Range ....................-40°C to 125°C
Thermal Resistance θJA ...................................... 22°C/W
VCCA, VCCD, LDOOUT, GLx, VOUTx............................ 6V
VDD..................................................................... 2.0V
VIN....................................................................... 27V
LXx .............................................................. -1V to 27V
LXx ............................................................. -5V to -1V1
Logic Inputs, GPIOs, SDA, SCL ................................... 6V
BSTx, GHx .................................................... VLXx + 6V
ESD Rating (HBM - Human Body Model) .................... 2kV
Storage Temperature .............................. -65°C to 150°C
Lead Temperature (Soldering, 10 sec) ................... 300°C
Note 1: 200ns Transient
ELECTRICAL SPECIFICATIONS
Specifications with standard type are for an Operating Junction Temperature of TJ = 25°C only; limits applying over the full
Operating Junction Temperature range are denoted by a “•”. Minimum and Maximum limits are guaranteed through test,
design, or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25°C, and are provided for
reference purposes only. Unless otherwise indicated, VIN = 4.75V to 25V.
Quiescent Current
Parameter
Min.
Typ.
Max.
Units
Conditions
9
mA
LDOOUT enabled (no load)
No switching converter channels enabled
I2C communication active
Switching frequency = 400kHz
180
µA
EN = 0V, VIN ≥ 5.2V
VIN Supply Current
28
mA
3 channels running,
GH and GH = 1nF load each
VIN=12V, Switching frequency = 300kHz
VIN Supply Current
50
mA
3 channels running,
GH and GH = 1nF load each
VIN=12V, Switching frequency = 1MHz
VIN Supply Current in STANDBY
VIN Supply Current in
SHUTDOWN
Step Down Controllers
Parameter
VOUT Regulation Accuracy
VOUT regulation range
Min.
Typ.
Max.
Units
Conditions
-20
20
mV
•
0.9V ≤ VOUT ≤ 2.5V
-40
40
mV
•
2.6V ≤ VOUT ≤ 5.1V
0.9
5.1
•
Programmable range of each channel2
VOUT set point resolution
50
VOUT set point resolution
100
0.9V ≤ VOUT ≤ 2.5V
VOUT Input Current
100
nA
0.9V < VOUT ≤ 2.5V
VOUT Input Resistance
120
kΩ
2.6V ≤ VOUT ≤ 5.1V
2.6V ≤ VOUT ≤ 5.1V
Note 2: Voltages above 5.1V can be obtained by using an external voltage divider.
2/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
Low Drop-out Regulator
Parameter
Min.
Typ.
Max.
Units
Conditions
LDOOUT Output Voltage
LDO = LOW
3.15
3.3
3.45
V
•
4.75V ≤ VIN ≤ 25V
0mA < ILDOOUT < 100mA
LDOOUT Output Voltage
LDO = HIGH
4.75
5.0
5.25
V
•
6.3 ≤ VIN ≤ 25V
0mA < ILDOOUT < 100mA
LDOOUT Short Circuit Current
Limit
110
220
mA
•
VLDOOUT = 0V
Max.
Units
Auxiliary ADCs
Parameter
Min.
Typ.
2
LSB
Linearity Error Differential
-1
1
LSB
Input Dynamic Range VIN
4.8
25
V
Max.
Units
Linearity Error Integral
Conditions
•
Isense ADC
Parameter
Min.
ADC LSB
Typ.
5
Input Dynamic Range
0
Conditions
mV
-320
mV
Max.
Units
Referred to the input
PWM Generators and Oscillator
Parameter
Min.
Output frequency range
300
Output Frequency Accuracy
-10
Typ.
1500
10
Conditions
Steps defined in the table in the PWM
Switching Frequency Setting section
below
kHz
%
Channel-to-channel phase shift
90
deg
Minimum On Time
40
ns
13
ns
1.5
ns
•
1nF of gate capacitance
Switching frequency = 300kHz
10% to 90% duty cycle, Frequency
dependent; refer to the graph in
performance characteristic section
Dead Time Adjustment Step
CLOCK IN Synchronization
Range
Maximum Duty Cycle2
Switching frequency = 1.5MHz
10% to 90% duty cycle, Frequency
dependent; refer to the graph in
performance characteristic section
%
•
86
%
•
Switching frequency = 300kHz
78
%
•
Switching frequency = 1.5MHz
-5
5
Note 2: The maximum duty cycle represents the maximum duty cycle commanded by the DPWM, is guaranteed by design,
and internally set to ensure proper sampling of the current during the off-time.
3/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
Digital Input/Output Pins (GPIO1-GPIO5) and ENABLE
3.3V CMOS logic compatible, 5V tolerant.
Parameter
Enable Pin Threshold
Min.
Typ.
Max.
Units
1.08
1.14
1.2
V
0.8
V
•
V
•
µA
•
VIO = 3.3V
V
•
ISINK = 1mA
V
•
ISOURCE = 1mA
•
ISOURCE = 0mA
Input Pin Low Level
Input Pin High Level
2.0
10
Input Pin Leakage Current
Input pin Capacitance
5
Output Pin Low Level
Output Pin High Level
pF
0.4
2.4
3.3
3.6
V
Typ.
Max.
Units
I C Speed
400
kHz
Input Pin Low Level, VIL
1.0
V
Output Pin High Level (no load)
Conditions
Chip Enable rising threshold
I2C Specification
Parameter
Min.
2
Input Pin High Level, VIH
Hysteresis of Schmitt Trigger
Inputs, VHYS
2.31
V
0.165
V
Output Pin Low Level (open
drain or collector) VOL
Input Leakage Current
Output Fall Time from VIHMIN to
VILMAX
-10
20+0.1Cb3
Capacitance for each I/O Pin
Conditions
Based upon I C master clock
2
0.4
V
10
µA
Input is between 0.33V and 2.31V
250
ns
With a bus capacitance from 10pF to
400pF
10
pF
Max.
Units
ISINK = 3mA
Note 3: Cb is the capacitance of one bus in pF
Gate Drivers
Parameter
GH, GL Rise and Fall Time
Min.
Typ.
30
ns
GH, GL Pull-up On-State Output
Resistance
6
Ω
GH, GL Pull-down On-State
Output Resistance
3
Ω
GH, GL Pull-down Off-State
Output Resistance
50
kΩ
4/30
Conditions
At 10% to 90% of full scale pulse.
1nF Cload
VIN = VCCD = 0V
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
BLOCK DIAGRAM
Fig. 2: XRP7713 Block Diagram
5/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
PIN ASSIGNMENT
Fig. 3: XRP7713 Pin Assignment
PIN DESCRIPTION
Name
Pin Number
Description
VIN
30
Power source for the internal linear regulators to generate VCCA, VDD and the Standby LDO
(LDOOUT). Place a decoupling capacitor close to the controller IC. Also used in UVLO1 fault
generation – if VIN falls below the user programmed limit, all channels are shut down.
VCCA
29
Output of the internal 5V LDO. This voltage is internally used to power analog blocks. This pin
should be bypassed with a minimum of 4.7uF to AGND.
VCCD
18
Gate Drive input voltage. This is not an output voltage. This pin can be connected to VCCA to
provide power for the Gate Drive. VCCD should be connected to VCCA with the shortest
possible trace and decouple with a minimum 1µF capacitor. Alternatively, VCCD could be
connected to an external supply (not greater than 5V).
GL_RTN1GL_RTN3
28, 23,13
Power Ground. Ground connection for the low side gate driver. Connect at low side FET source.
AVDD
32
DVDD
1
Input for powering the internal digital logic. This pin should be connected to AVDD.
DGND
8
Digital Ground. Connect this pin to the ground plane at the exposed pad with a separate trace.
Output of the internal 1.8V LDO. This pin should be bypassed with a minimum of 2.2uF to
DGND.
6/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
Name
Pin Number
Description
AGND
9
Analog Ground. Connect this pin to the ground plane at the exposed pad with a separate trace.
GL1-GL3
27, 22, 14
Output pin of the low side gate driver. Connect directly to the respective gate of an external Nchannel MOSFET.
GH1-GH3
25, 20, 16
Output pin of the high side gate driver. Connect directly to the respective gate of an external Nchannel MOSFET.
LX1-LX3
26, 21, 15
Lower supply rail for the high-side gate driver (GHx). Connect this pin to the switching node at
the junction between the two external power MOSFETs and the inductor. These pins are also
used to measure voltage drop across bottom MOSFETs in order to provide output current
information to the control engine.
BST1-BST3
24, 19, 17
High side driver supply pin(s). Connect BST to an external boost diode and a capacitor as
shown in the front page diagram. The high side driver is connected between the BST pin and LX
pin.
GPIO1-GPIO3
2,3,4
These pins can be configured as inputs or outputs to implement custom flags, power good
signals and enable/disable controls. A GPIO pin can also be programmed as an input clock
synchronizing IC to external clock. Refer to the “GPIO Pins” Section and the “External Clock
Synchronization” Section for more information.
GPIO4_SDA,
GPIO5_SCL
VOUT1VOUT3
5,6
I2C serial interface communication pins. These pins can be re-programmed to perform GPIO
functions in applications when I2C bus is not used.
10, 11, 12
LDOOUT
31
ENABLE
7
AGND
Voltage sense. Connect to the output of the corresponding power stage.
Output of the Standby LDO. It can be configured as a 5V or 3.3V output. This pin should be
bypassed with a minimum of 2.2uF.
If ENABLE is pulled high, the chip powers up (logic reset, registers configuration loaded, etc.).
If pulled low for longer than 100us, the XRP7713 is placed into shutdown.
Exposed Pad Analog Ground. Connect to analog ground (as noted above for pin 11).
ORDERING INFORMATION(1)
Part Number
XRP7713ILB-F
XRP7713ILBTR-F
XRP7713EVB-DEMO-1
XR77XXEVB-XCM-V80
XRP7713EVB-DEMO-1-KIT
Junction Temperature
Range
Lead-Free
Package
-40°C≤TJ≤+125°C
Yes(2)
32-pin TQFN
Packing
Method
Default I2C
Address
Bulk
0x00
Tape & Reel
0x00
XRP7713 Evaluation Board
Configuration Module
Includes XRP7713EVB-DEMO-1 Evaluation Board,
XR77XXEVB-XCM-V80 Configuration Module and Power Architect
NOTES:
1.
Refer to www.exar.com/XRP7713 for most up-to-date Ordering Information.
2.
Visit www.exar.com for additional information on Environmental Rating.
7/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
TYPICAL PERFORMANCE CHARACTERISTICS
All data taken at TJ = TA = 25°C, unless otherwise specified - Schematic and BOM from Application Information section of
this datasheet.
Fig. 5: 12Vin Efficiency: Single Channel
300kHz - Channels not in use are disabled
FET: FDS8984; Inductor: 744310200 7x7x3mm
Fig. 4: 12Vin Efficiency: Single Channel
300kHz - Channels not in use are disabled
FET: Si4944; Inductor: 744314xxx 7x7x5mm
100%
2.5V
1.8V
90%
1.2V
Efficiancy
1.0V
80%
70%
60%
50%
0
1
2
3
4
5
Output Current (Amps)
Fig. 6: 5Vin Efficiency: Single Channel
300kHz - Channels not in use are disabled
FET: Si4944; Inductor: 744314xxx 7x7x5mm
Fig. 7: 5Vin Efficiency: Single Channel
300kHz - Channels not in use are disabled
FET: FDS8984; Inductor: 744314xxx 7x7x3mm
Fig. 8: Combined Efficiency: 3V3 1V8 & 1V0
300 kHz FET: FDS8984; Inductor: 744314xxx 7x7x3mm
Fig. 9: 12Vin Efficiency: Single Channel
1MHz - Channels not in use are disabled
FET: FDS8984; Inductor:744310200 7x7x3mm
8/30
Rev. 1.1.1
XRP7713
200
2000
190
1800
180
1600
170
1400
160
1200
ISD (µA)
ISD (µA)
Three Channel Digital PWM Step Controller
150
140
1000
800
130
600
120
400
110
200
100
0
5
10
15
20
25
4.7
VIN (V)
4.8
4.8
4.9
4.9
5.0
5.0
5.1
5.1
5.2
VIN (V)
Fig. 10: Shutdown Current
5.1V to 25V
Fig. 11: Shutdown Current
4.8V to 5.1V
Fig. 12: CH1:1.0V CH2:5V CH3:1.8V
Fig. 13: CH1:1.0V CH2:5V CH3:1.8V
Simultaneous Start-up Configuration
Simultaneous Soft-Stop
Fig. 14: CH1:1.0V CH2:5V CH3:1.8V
Fig. 15: CH1:1.0V CH2:5V CH3:1.8V
Sequential Start-up Configuration
Sequential Soft-Stop Configuration
Vout Shutdown = 0.8V, 1A load
9/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
Fig. 16: CH1:1.0V CH2:5V CH3:1.8V
Sequential Soft-Stop Configuration
Vout Shutdown = 0.8V, No load
Fig. 17: Load Transient Response
CH1: Iout (1A/div) CH2:Vout(3.3V)
Fig. 18: Temperature Regulation
1.0VOUT (±1% Vout window)
Fig. 19: Temperature Regulation
1.8VOUT (±1% Vo window)
Fig. 20: Temperature and Voltage Regulation
1.0VOUT (±1% Vout window)
Fig 21: Line/Load Regulation
1.8 VOUT (± 1% VOUT window)
10/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
FEATURES AND BENEFITS
− Possible to configure as traditional ‘enable’ pin for
all 3 outputs
− 2 GPIOs can be dedicated to the I2C Interface as
required by the customers design
General DPWM Benefits:
• Eliminate temperature and time variations associated
with passive components in:
• Frequency and Synchronization Capability
− Selectable switching frequency between 300kHz and
1.5MHz
− Output set point
− Feedback compensation
− Channel to channel phase relationship is a fixed 90
degrees
− Frequency set point
− Under voltage lock out
− Main oscillator clock and DPWM clock can be
synchronized to external sources
− Input voltage measurement
− ‘Master’, ‘Slave’ and ‘Stand-alone’ Configurations
are possible
− Gate drive dead time
• Tighter parameter
frequency set point
tolerances
including
operating
• Internal MOSFET Drivers
− Internal FET drivers (3Ω/6Ω) for each Channel
• Easy configuration and re-configuration for different
Vout, Iout, Cout, and Inductor selection by simply
changing internal PID coefficients. No need to change
external passives for a new output specification.
− Built-In Automatic Dead-time adjustment
− 30ns Rise and Fall times
• PowerArchitect™ Design and Configuration Software:
• Higher integration: Many external circuits can be
handled by monitoring or modifying internal registers
• Selectable DPWM
Frequency
frequency
and
Controller
− In its simplest form only VIN, VOUT, and Iout for
each channel is required.
Clock
− The software calculates configuration register
content based upon customer requirements. PID
coefficients for correct loop response (for automatic
or customized designs) can be generated and sent
to the device.
Other Benefits:
• A single voltage is needed for regulation [no External
LDO required].
− Configurations can be saved and/or recalled
− GPIOs can be configured easily and intuitively
• I2C interface allows:
− Synchronization configuration can be adjusted
− Communication with a System Controller or other
Power Management devices for optimized system
function
− Interface can be used for real-time debugging and
optimization
• Customizing XRP7713 with customer parameters
− Access to modify or read internal registers that
control or monitor:
− Once a configuration is finalized it can be sent to
MaxLinear and can reside in pre-programmed parts
that customers can order with an individual part
number.
− Output Current
− Input and Output Voltage
− Soft-Start/Soft-Stop Time
− Allows parts to be used without I2C interface
− ‘Power Good’
System Benefits:
− Part Temperature
− Enable/Disable Outputs
• Reliability is enhanced via communication with the
system controller which can obtain real time data on
an output voltage, input voltage and current.
− Over Current
− Over Voltage
− Temperature Faults
• System processors can communicate with the
XRP7713 directly to obtain data or make adjustments
to react to circuit conditions
− Adjusting fault limits and disabling/enabling
faults
− Packet Error Checking (PEC) on I2C communication
• A system process or could also be configured to log
and analyze operating history, perform diagnostics and
if required, take the supply off-line after making other
system adjustments.
• 5 Configurable GPIO pins, (3 if I2C is in use). Pins can
be configured in several ways:
− Fault reporting (including OCP, OVP, Temperature,
Soft-Start in progress, Power Good)
• If customer field service is a possibility for your end
product, parameter reporting and history would
provide additional capabilities for troubleshooting or
aid in future system upgrades.
− Allows a Logic Level interface with other non-digital
IC’s or as logic inputs to other devices
11/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
FUNCTIONAL DESCRIPTION AND OPERATION
The XRP7713 is a three output digital pulse width modulation (DPWM) controller with integrated
gate drivers for the use in synchronous buck switching regulators. Each output voltage can be
programmed from 0.9V to 5.1V without the need of an external voltage divider. The wide range of
the programmable DPWM switching frequency (from 300kHz to 1.5MHz) enables the user to
optimize for efficiency or component sizes. The digital regulation loop requires no external passive
components for network compensation. The loop performance does not need to be compromised
due to component tolerance, aging, and operating condition. Each digital controller provides a
number of safety features, such as over-current protection (OCP) and over-voltage protection
(OVP). The chip also provides over-temperature protection (OTP) and under-voltage lock-out
(UVLO) for two input voltage rails. The XRP7713 also has up to 5 GPIOs and a Standby Linear
Regulator to provide standby power. An I2C bus interface is provided to program the IC as well as
to communicate with the host for fault reporting and handling, power rail monitoring, channel
enable and disable, Standby LDO voltage reconfiguration, and Standby LDO enable and disable.
The XRP7713 offers a complete solution for soft-start and soft-stop. The delay and ramp of each
PWM regulator can be independently controlled. During soft-stop, the output voltage ramps down
with a programmable slope until it reaches a pre-set value. This pre-set value can be programmed
between within zero volts and the target voltage with the same set target voltage resolution.
REGISTER TYPES
There are two types of registers in the XRP7713: read/write registers and read-only registers. The
read/write registers are used for the control functions of the IC and can be programmed using
configuration non-volatile memory (NVM) or through an I2C command. The read-only registers are
for feedback functions such as error/warning flags and for reading the output voltage or current.
NON-VOLATILE CONFIGURATION MEMORY
The non-volatile memory (NVM) in XRP7713 stores the configuration data for the chip and all of the
power rails. This memory is normally configured during manufacturing time. Once a specific bit of
the NVM is programmed, that bit can never be reprogrammed again [i.e. one-time programmable].
During chip power up, the contents in the NVM are automatically transferred to the internal
registers of the chip. Programmed cells have been verified to be permanent for at least 10 years
and are highly reliable.
POWER UP AND SEQUENCING REQUIREMENTS
The XRP7713 can be programmed to sequence its outputs for nearly any imaginable loading
requirement. However, there are some important sequencing requirements for the XRP7713 itself.
When power is applied to the XRP7713, the 5V VCCA and 1.8V AVDD regulators must come up and
stabilize to provide power for the analog and digital blocks of the IC. The Enable Pin must remain
below its logic level high threshold until the AVDD is regulating to ensure proper loading of the
configuration registers. For systems that control the Enable signal through a microcontroller or
other processor, this is simply a matter of providing the proper delay to the Enable signal after
power up. However, most users will want the part to automatically power up when power is
applied to the system. To that end there are a number of recommended solutions.
The most ideal sequencing method is to provide an RC time constant delay from DVDD to the
Enable pin. A 10kohm resistor and a 0.1uF are all that is required. If the system needs to
externally control the Enable pin as well, it is recommended that the Enable pin be pulled to ground
using an open drain I/O. Using 3.3V active logic would back feed DVDD and exceed the maximum
rated voltage of the pin.
12/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
For those using active 3.3V or 5V logic on the Enable pin an RC delay from VCCA to the Enable pin
may be used. When using an RC delay from VCCA, attention must be paid to the amount of
bypass capacitance loading AVDD since it will delay the time it takes for AVDD to power up and
regulate. The AVDD and DVDD pins do not require more than 2.2uF for proper bypassing. See
Figure 22 for the recommended components for sequencing the Enable pin through an RC delay
from VCCA. If more capacitance is added to AVDD and DVDD, the time constant must be
increased. Once Enable is asserted, an internal CHIP_READY flag goes high and enables the I2C to
acknowledge the Host’s serial commands. Channels that are configured as always-on channels are
enabled. Channels that are configured to be enabled by GPIOs are also enabled if the respective
GPIO is asserted.
Fig. 22: RC Delay for Enable taken from VCCA
VCCA regulates at approximately 4.6V when the Enable pin is logic level low and at 5.1V when
Enable is asserted. See Figure 23 for an example.
Fig. 23: Startup Waveform
13/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
Another power-up timing concern can be observed with slowly increasing input voltages. If the
UVLO Fault threshold is set to a value higher than the value of VIN when AVDD has stabilized and
the enable is asserted; the UVLO Fault could assert prior to VIN reaching its final value. Increasing
the value of the resistor in the RC delay will slow down the enable signal and prevent a premature
UVLO Fault.
STANDBY LOW DROP-OUT REGULATOR
This 100mA low drop-out regulator can be programmed as 3.3V or 5V in SET_STBLDO_EN_CONFIG
register. Its output is seen on the LDOOUT Pin. This LDO is fully controllable via the Enable Pin
(configured to turn on as soon as power is applied), a GPIO, and/or I2C communication.
The 5V output setting of the regulator is only available if VIN is above 6.3V, and the 3.3V output
setting is available for the entire VIN range from 4.75 to 25V. The standby LDO should be
bypassed with a minimum of 2.2uF ceramic capacitor.
ENABLING, DISABLING AND RESET
The XRP7713 is enabled via raising the ENABLE Pin high. The chip can then be disabled by
lowering the same ENABLE Pin. There is also the capability for resetting the Chip via an I2C
SOFTRESET Command.
For enabling a specific channel, there are several ways that this can be achieved. The chip can be
configured to enable a channel at start-up as the default configuration residing in the non-volatile
configuration memory of the IC. The channels can also be enabled using GPIO pins and/or an I2C
Bus serial command. The registers that control the channel enable functions are the
SET_EN_CONFIG and SET_CH_EN_I2C.
INTERNAL GATE DRIVERS
The XRP7713 integrates Internal Gate Drivers for all 4 PWM channels. These drivers are optimized
to drive both high-side and low side N-MOSFETs for synchronous operations. Both high side and
low side drivers have the capability of driving 1nF load with 30ns rise and fall time. The drivers
have built-in non-overlapping circuitry to prevent simultaneous conduction of the two MOSFETs.
The built-in non-overlapping feature is disabled when the programmable dead time is selected.
PROGRAMMABLE DEAD TIME
The programmable dead time feature provides customers the flexibility to optimize the system
performance over PWM switching frequency, efficiency and component selections.
There are three registers to control the dead time. The programmable dead time feature is enabled
in the SET_CONTROL_BIT_REG register. If disabled, the built-in dead time control inside the driver
will take over.
The dead time between the turn off of the low side MOSFET and the turn on of high side MOSFET is
controlled by the SET_DT_RISE_CHx. On the other hand, the dead time between the turn off of
high side MOSFET and the turn on of the low side MOSFET is controlled by SET_DT_FALL_CHx. The
actual LSB of the registers is variable depending on the switching frequency.
𝑆𝑆𝑆𝑆𝑆𝑆𝑆𝑆 𝑆𝑆𝑆𝑆𝑆𝑆𝑆𝑆 (𝐿𝐿𝑆𝑆𝑆𝑆) =
1
𝑃𝑃𝑃𝑃𝑃𝑃𝑃𝑃 × 256
14/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
FAULT HANDLING
While the chip is operating there are four different types of fault handling:
•
•
•
•
Under Voltage Lockout (UVLO) monitors the input voltage to the chip, and the chip will
shutdown all channels if the voltage drops to critical levels.
Over Temperature Protection (OTP) monitors the temperature of the chip, and the chip
will shutdown all channels if the temperature rises to critical levels.
Over Voltage Protection (OVP) monitors the voltage of channel and will shutdown the
channel if it surpasses its voltage threshold.
Over Current Protection (OCP) monitors the current of a channel, and will shutdown the
channel if it surpasses its current threshold. The channel will be automatically restarted
after a 200ms delay.
Under Voltage Lockout (UVLO)
The under voltage can be sensed on VIN. The SET_UVLO_WARN_VINx register that sets the under
voltage warning set point condition at 100mV increments. When the warning threshold is reached,
the Host is informed via a GPIO or by reading the READ_WARN_FLAG register.
The SET_UVLO_TARG_VIN1 register that controls the under voltage fault set point condition at
100mV increments. This fault condition will be indicated in the READ_FAULT_WARN register.
When an under voltage fault condition occurs, the fault flag register is set and all of the XRP7713
outputs are shut down. The measured input voltages can be read back using the READ_VIN1
register, and both registers have a resolution of 100mV per LSB. When the UVLO condition clears
(voltage rises above the UVLO Warning Threshold), the chip can be configured to automatically
restart.
VIN
This is a multi-function pin that provides power to both the Standby Linear Regulator and internal
linear regulators to generate VCCA, VDD, and the Standby LDO (LDOUT).
It is also used as a UVLO detection pin. If VIN falls below its user programmed limit, all channels
are shut down.
Temperature Monitoring and Over Temperature Protection (OTP)
•
Reading the junction temperature
This register allows the user to read back the temperature of the IC. The temperature is expressed
in Kelvin with a maximum range of 520K, a minimum of 200K, and an LSB of 5 degrees K. The
temperature can be accessed by reading the READ_VTJ register.
•
Over Temperature Warning
There are also warning and fault flags that get set in the READ_OVV_UVLO_OVT_FLAG register.
The warning threshold is configurable to 5 or 10 Degrees C below the fault threshold. When the
junction temperature reaches 5 or 10 Degrees C below the user defined set point, the overtemperature warning bit [OTPW] gets set in the READ_OVV_UVLO_OVT_FLAG register to warn the
user that the IC might go into an over temperature condition (and shutdown all of the regulators).
•
Over Temperature Fault
If the over temperature condition occurs both the OTP and OTPW bits will be set in the
READ_OVV_UVLO_OVT_FLAG register and the IC will shut down all channels (but I2C will remain
operational). The actual over temperature threshold can be set by the user by using a 7bit
SET_THERMAL_SHDN register with an LSB of 5K.
15/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
If the over temperature fault condition clears, then the IC can be set to restart the chip
automatically. The restart temperature threshold can be set by the SET_THERMAL_RESTART
register.
OUTPUT VOLTAGE SETTING AND MONITORING
The Output Voltage setting is controlled by the SET_VOUT_TARGET_CHx register. This register
allows the user to set the output voltage with a resolution of 50mV for output voltages between 0
and 2.5V and with a resolution of 100mV for output voltages between 2.6V and 5.1V. Output
voltages higher than 5.1V can be achieved by adding an external voltage divider network. The
output voltage of a particular channel can be read back using the READ_VOUTx register.
Output Voltage from 0.9V to 5.1V
Per the equation below, for values between 0.9V and 5.1V the output voltage is equal to the binary
number stored in the SET_VOUT_TARGET_CHx register multiplied by 50mV. When programming an
output voltage from 2.6V to 5.1V, odd binary values should be avoided. As a result, the set
resolution for an output voltage higher than 2.5V is 100mV.
𝑉𝑉𝑂𝑂𝑂𝑂𝑂𝑂 = 𝑆𝑆𝑆𝑆𝑆𝑆_𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉_𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇_𝐶𝐶𝐶𝐶𝐶𝐶 × 50𝑚𝑚𝑚𝑚
Output VOUT Higher Than 5.1V
To set the output voltage higher than 5.1V, the user needs to add an external voltage divider. The
resistors used in the voltage divider should be below 10kΩ. The SET_VOUT_TARGET_CHx register
should be set to 0x32 which is equivalent to an output voltage of 2.5V without the external divider
network. The output voltage regulation in this case might exceed 2% due to extra error from the
resistor divider. R1 and R2 follows the definition below.
Vout>5.1V
R1
Voutx pin
R2
Fig. 24: External divider network for high output voltage
𝑉𝑉𝑂𝑂𝑂𝑂𝑂𝑂 = �
𝑅𝑅1
+ 1� × 𝑆𝑆𝑆𝑆𝑆𝑆_𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉_𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇𝑇_𝐶𝐶𝐶𝐶𝐶𝐶 × 50𝑚𝑚𝑚𝑚
𝑅𝑅2
Output Voltage Lower Than 0.9V
The XRP7713 can be programmed to regulate an output voltage lower than 0.9V. However, in this
case the specification of ±20mV output voltage accuracy is not guaranteed.
OVER-VOLTAGE PROTECTION (OVP)
The Over-Voltage Protection (OVP) SET_OVVP_REGISTER sets the over-voltage condition in
predefined steps per channel. The over-voltage protection is always active even during soft-start
condition. When the over-voltage condition is tripped, the controller will shut down the channel.
When the channel is shut down the controller will then set corresponding OVP Fault bits in the
READ_OVV_UVLO_OVT_FLAG register.
16/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
The VOUT OVP Threshold is 150mV to 300mV above nominal VOUT for a Voltage Target of 2.5V or
less. For the Voltage Target of 2.6V to 5.1V, the VOUT OVP Threshold is 300mV to 600mV.
Once
the
over-voltage
Channel
is
disabled,
the
controller
will
check
the
SET_FAULT_RESP_CONFIG_LB and SET_FAULT_RESP_CONFIG_HB to determine whether there are
any “following” channels that need to be shut down. Any following channel will be disabled when
the channel with the Over Voltage Fault is disabled. The channel(s) will remain disabled, until the
Host takes action to enable the channel(s).
Any of the fault and warning conditions can also be configured to be represented using the general
purpose input output pins (GPIO) to use as an interface with non I2C compatible devices. For
further information on this topic see the “GPIO Pins” Section.
During OVP fault shutdown of the channel, the customer has the option to choose two types of
shutdown for each channel. The first shutdown is ‘passive shutdown’ where the IC merely stops
outputting pulses. The second shutdown is a ‘brute force’ shutdown where the GL remains on as
the channel reaches its discharged voltage. Note that if the ‘brute force’ method is chosen, then GL
will permanently remain high until the channel is re-enabled.
OUTPUT CURRENT SETTING AND MONITORING
XRP7713 utilizes a low side MOSFET Rdson current sensing technique. The voltage drop on Rdson
is measured by dedicated current ADC. The ADC results are compared to a maximum current
threshold and an over-current warning threshold to generate the fault and warning flags.
Maximum Output Current
The maximum output current is set by the SET_VIOUT_MAX_CHx register and
SET_ISENSE_PARAM_CHx register. The SET_VIOUT_MAX_CHx register is an 8 bit register. Bits
[5:0] set the maximum current threshold and bits [7:6] set the over-current warning threshold.
The LSB for the current limit register is 5 mV and the allowed voltage range is between 0 and
315mV. To calculate the maximum current limit, the user needs to provide the MOSFET Rdson. The
maximum current can be calculated as:
𝐼𝐼𝐼𝐼𝐼𝐼𝐼𝐼𝐼𝐼𝐼𝐼𝐼𝐼 =
𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉
𝑅𝑅𝑅𝑅𝑅𝑅𝑅𝑅𝑅𝑅 × 𝐾𝐾𝐾𝐾
Where Kt is the temperature coefficient of the MOSFET Rdson; Vsense is the voltage across Rdson;
IOUTMAX is the maximum output current.
Over-Current Warning
The XRP7713 also offers an Over-Current warning flag. This warning flag resides in the
READ_OVC_FLAG register. The warning flag bit will be set when the output current gets to within a
specified value of the output current limit threshold enabling the host to reduce power
consumption. The SET_VIOUT_MAX_CHx register allows the warning flag threshold to be set 10mV,
20mV, 30mV or 40mV below VIOUT_MAX. The warning flag will be automatically cleared when the
current drops below the warning threshold.
Over-Current Fault Handling
When an over-current condition occurs, PWM drivers in the corresponding channels are disabled.
After a 200ms timeout, the controller is re-powered and soft-start is initiated. When the overcurrent condition is reached the controller will check the SET_FAULT_RESP_CONFIG_LB and
SET_FAULT_RESP_CONFIG_HB to determine whether there are any “following” channels that need
to be similarly restarted. The controller will also set the fault flags in READ_OVC_FAULT_WARN
register.
17/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
Typically the over-current fault threshold would be set to 130-140% of the maximum desirable
output current. This will help avoid any over-current conditions caused by transients that would
shut down the output channel.
CHIP OPERATION AND CONFIGURATION
SOFT-START
The SET_SS_RISE_CHx register is a 16 bit register which specifies the soft-start delay and the
ramp characteristics for a specific channel. This register allows the customer to program the
channel with a 250µs step resolution and up to a maximum 16ms delay.
Bits [15:10] specify the delay after enabling a channel but before outputting pulses; where each bit
represents 250µs steps. Bits [9:0] specify the rise time of the channel; these 10 bits define the
number of microseconds for each 50mV increment to reach the target voltage.
Enable
Signal
Vout
RISE TIME
DELAY
Bit [10:15]
Bit [0:9]
SS_RISE_CHx
REGISTER
Fig. 25: Channel Power Up Sequence
18/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
SOFT-STOP
The SET_PD_FALL_CHx register is a 16 bit register. This register specifies the soft-stop delay and
ramp (fall-time) characteristics for when the chip receives a channel disable indication from the
Host to shutdown the channel.
Bits [15:10] specify the delay after disabling a channel but before starting the shutdown of the
channel; where each bit represents 250µs steps. Bits [9:0] specify the fall time of the channel;
these 10 bits define the number of microseconds for each 50mV increment to reach the discharge
threshold.
Enable
Signal
Vout
Fall Time
DELAY
Bit [0:9]
Bit [10:15]
PD_DELAY_CHx
REGISTER
Fig. 26: Channel Soft-Stop Sequence
POWER GOOD FLAG
The XRP7713 allows the user to set the upper and lower bound for a power good signal per
channel.
The
SET_PWRG_TARG_MAX_CHx
register
sets
the
upper
bound,
the
SET_PWRG_TARG_MIN_CHx register sets the lower bound. Each register has a 20mV LSB
resolution. When the output voltage is within bounds the power good signal is asserted high.
Typically the upper bound should be lower than the over-voltage threshold. In addition, the power
good signal can be delayed by a programmable amount set in the SET_PWRGD_DLY_CHx register.
The power good delay is only set after the soft-start period is finished. If the channel has a precharged condition that falls into the power good region, a power good flag is not set until the softstart is finished.
PWM SWITCHING FREQUENCY
The PWM switching frequency is set by choosing the corresponding oscillator frequency and clock
divider ratio in the SET_SW_FREQUENCY register. Bits [6:4] set the oscillator frequency and bits
[2:0] set the clock divider. The tables below summarize the available Main Oscillator and PWM
switching frequency settings in the XRP7713.
Main Oscillator Frequency
SET_SW_FREQUENCY[6:4]
000
Main Oscillator Frequency
Ts
48MHz
20.8ns
001
010
011
100
44.8MHz 41.6MHz 38.4MHz 35.2MHz
22.3ns
24ns
26ns
28.4ns
19/30
101
110
111
32MHz
31.25ns
28.8Mhz
34.7ns
25.6MHz
39ns
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
PWM Switching Frequency
SET_SW_FREQUENCY[6:4]
SET_SW_FREQUENCY[2:0]
000
001
010
011
100
101
110
111
000
001
010
011
100
101
110
111
NA
1.5MHz
1.0MHz
750KHz
600KHZ
500KHz
429KHZ
375KHz
NA
1.4MHz
933KHz
700KHz
560KHz
467KHZ
400KHZ
350KHz
NA
1.3MHz
867KHz
650KHz
520KHz
433KHz
370KHz
325KHz
NA
1.2MHz
800KHz
600KHz
480KHz
400KHz
343KHz
300KHz
NA
1.1MHz
733KHz
550KHz
440KHz
367KHz
314KHz
NA
NA
1.0MHz
667KHz
500KHz
400KHz
333KHz
NA
NA
NA
900KHz
600KHz
450KHz
360KHz
300KHz
NA
NA
NA
800KHz
533KHz
400KHz
320KHz
NA
NA
NA
There are a number of options that could result in similar PWM switching frequency as shown
above. In general, the chip consumes less power at lower oscillator frequency. When
synchronization of the Main Oscillator Frequency to an external system clock is desired, the user
must choose the oscillator frequency to be within ±5% of the external clock frequency. A higher
Main Oscillator frequency will not improve accuracy or any performance efficiency.
Note: It is the intention of the synchronization feature to sync to a system clock or to another
compatible MaxLinear device, not the switching frequency.
PWM SWITCHING FREQUENCY CONSIDERATIONS
There are several considerations when choosing the PWM switching frequency.
Minimum On Time
Minimum on time determines the minimum duty cycle at the specific switching frequency. The
minimum on time for the XRP7713 is 40ns.
𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀 𝐷𝐷𝐷𝐷𝐷𝐷𝐷𝐷 𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶% = 𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀 𝑜𝑜𝑜𝑜𝑜𝑜𝑜𝑜𝑜𝑜𝑜𝑜 × 𝑃𝑃𝑃𝑃𝑃𝑃 𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹 × 100
As an example the minimum duty cycle is 4% for 1MHz PWM frequency. This is important since the
minimum on time dictates the maximum conversion ratio that the PWM controller can achieve.
Maximum Duty Cycle
𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀𝑀 𝐷𝐷𝐷𝐷𝐷𝐷𝐷𝐷 𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶% >
𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉
𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉
The maximum duty cycle is dictated by the minimum required time to sample the current when the
low side MOSFET is on, this depends on the frequency of the main oscillator and the selected PWM
frequency. It is best to choose the highest main oscillator frequency available for any specific PWM
frequency. The maximum duty cycle for each PWM frequency is shown in the table below:
Main Oscillator Frequency
Maximum Duty Cycle
48MHz
78%
86%
84%
89%
88%
88%
86%
1.5MHz
1.0MHz
750KHz
600KHZ
500KHz
429KHZ
375KHz
44.8MHz 41.6MHz 38.4MHz 35.2MHz
32MHz
28.8Mhz
25.6MHz
1.4MHz
933KHz
700KHz
560KHz
467KHZ
400KHZ
350KHz
1.0MHz
667KHz
500KHz
400KHz
333KHz
NA
NA
900KHz
600KHz
450KHz
360KHz
300KHz
NA
NA
800KHz
533KHz
400KHz
320KHz
NA
NA
NA
1.3MHz
867KHz
650KHz
520KHz
433KHz
370KHz
325KHz
1.2MHz
800KHz
600KHz
480KHz
400KHz
343KHz
300KHz
1.1MHz
733KHz
550KHz
440KHz
367KHz
314KHz
NA
Table 1: PWM Frequency
20/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
The maximum duty cycle obtained from the table above is programmed by the PowerArchitectTM
software into each of the channels using the SET_DUTY_LIMITER_CHx register. This ensures that
under all conditions (including faults), there will always be sufficient sampling time to measure the
output current. When the duty cycle limit is reached, the output voltage will no longer regulate and
will be clamped based on the maximum duty cycle limit setting.
It is possible for the user to program SET_DUTY_LIMITER_CHx register to a higher value, but the
OCP Fault and OCP WARN flags should then be ignored.
Efficiency
The PWM Switching frequency plays an important role on overall power conversion efficiency. As
the switching frequency increase, the switching losses also increase. Please see the APPLICATION
INFORMATION, Typical Performance Data for further examples.
Component Selection and Frequency
Typically the components become smaller as the frequency increases, as long as the ripple
requirements remain constant. At higher frequency the inductor can be smaller in value and have a
smaller footprint while still maintaining the same current rating.
FREQUENCY SYNCHRONIZATION FUNCTION AND EXTERNAL CLOCK
The user of the XRP7713 can choose to use an external source as the primary clock for the
XRP7713. This function can be configured using the SET_SYNC_MODE_CONFIG register. This
register sets the operation of the XRP7713 when an external clock is required. By selecting the
appropriate bit combination the user can configure the IC to function as a master or a slave when
two or more XRP7713s are used to convert power in a system. Automatic clock selection is also
provided to allow operation even if the external clock fails by switching the IC back to an internal
clock.
External Clock Synchronization
Even when configured to use an external clock, the chip initially powers up with its internal clock.
The user can set the percent target that the frequency detector will use when comparing the
internal clock with the clock frequency input on the GPIO pin. If the external clock frequency is
detected to be within the window specified by the user, then a switchover will occur to the external
clock. If the IC does not find a clock in the specified frequency target range then the external clock
will not be used and the IC will run on the internal clock that was specified by the user. If the
external clock fails the user can chose to have the internal clock take over, using the automatic
switch back mode in the SET_SYNC_MODE_CONFIG register.
CLK_IN
GPIO1
XRP7713
Configured for
external clock use
Fig. 27:XRP7713 Configured For External Clock Use
21/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
Synchronized Operation as a Master and Slave Unit
Two XRP7713s can be synchronized together. This Master-Slave configuration is described below.
•
Master
When the XRP7713 powers up as a master unit after the internal configuration memory is loaded
the unit will send CLK_OUT and SYNC_OUT signals to the slave on the preconfigured GPIO pins.
•
Slave
When powering in sync mode the slave unit will initially power up with its internal clock to transfer
the configuration memory. Once this transfer occurs, then the unit is set to function as a slave unit.
In turn the unit will take the external clock provided by the master to run as its main internal clock.
GPIO1 CLK_OUT
GPIO2
CLK_IN
SYNC_OUT
GPIO1
SYNC_IN
XRP7713
configured
as a master
GPIO2
XRP7713
configured
as a slave
Fig. 28: Master/Slave Configuration of the XRP7713
External Clock Synchronization Master Slave combination
When an external clock is used, the user will need to setup the master to also have an external
clock in function. All of the same rules apply as in the External clock synchronization, Synchronized
operation as a Slave unit section of this document. There are two ways of synchronizing this,
either the external clock going to both Master/Slave CLK_IN, or CLK_IN can go to the Master, and
the Master can synchronize SYNC_OUT and CLK_OUT to the Slave.
CLK_IN
CLK_IN
GPIO1
GPIO1
GPIO2
SYNC_OUT
XRP7713
Configured as a
master with
external clock sync
SYNC_IN
GPIO2
XRP7713
configured
as slave
Fig. 29: External Clock Synchronization Master Slave Combination
22/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
CLK_IN
GPIO3
GPIO1
GPIO2
CLK_IN
CLK_OUT
GPIO1
SYNC_OUT
SYNC_IN
XRP7713
Configured as a
master with
external clock sync
GPIO2
XRP7713
configured
as slave
Fig. 30: Alternative External clock synchronization Master Slave combination
PHASE SHIFT
Each switching channel is configured to run with a phase shift of 90 degrees.
GPIO PINS
The General Purpose Input Output (GPIO) Pins are the basic interface between the XRP7713 and
the system. Although all of the stored data within the IC can be read back using the I2C bus it is
sometimes convenient to have some of those internal register to be displayed and or controlled by
a single data pin. Besides simple input output functions the GPIO pins can be configured to serve
as external clock inputs. These pins can be programmed using OTP bits or can be programmed
using the I2C bus. This GPIO_CONFIG register allows the user close to 100 different configuration
functions that the GPIO can be programmed to do.
NOTE: the GPIO Pins (and all I/Os) should NOT be driven without a 10K resistor when VIN is not
being applied to the IC.
GPIO Pins Polarity
The polarity of the GPIO pin can be set by using the GPIO_ACT_POL register. This register allows
any GPIO pin whether configured as an input or output to change polarity. Bits [5:0] are used to
set the polarity of GPIO 1 though 5. If the IC operates in I2C mode, then the commands for Bits
[5:4] are ignored.
Supply Rail Enable
Each GPIO can be configured to enable a specific power rail for the system. The GPIOx_CFG
register allows a GPIO to enable/disable any of the following rails controlled by the chip:
•
•
•
A single buck power controller
The Standby LDO
Any mix of the Standby LDO and power controller(s)
When the configured GPIO is asserted externally, the corresponding rails will be enabled, and they
will be similarly disabled when the GPIO is de-asserted. This supply enabling/disabling can also be
controlled through the I2C interface.
Power Good Indicator
The GPIO pins can be configured as Power Good indicators for one or more rails. The GPIO pin is
asserted when all rails configured for this specific IO are within specified limits for regulation. This
information can also be found in the READ_PWRGD_SS_FLAG status register.
23/30
Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
Fault and Warning Indication
The GPIOs can be configured to signal Fault or Warning conditions when they occur in the chip.
Each GPIO can be configured to signal one of the following:
•
•
•
•
•
•
OCP Fault on Channel 1 - 3
OCP Warning on Channel 1 - 3
OVP Fault on Channel 1 – 3
UVLO Fault on VIN
UVLO Warning on VIN
Over Temperature Fault or Warning
I2C COMMUNICATION
The I2C communication is standard 2-wire communication available between the Host and the IC.
The communication has the option of enabling Packet Error Checking in order to deal with noisy
environments where bit-errors could occur in the communication. This packet error checking is a
CRC-8 code appended to all communication between the Host and the IC.
Each XRP7713 in an I2C -bus system is activated by sending a valid address to the device. The
address always has to be sent as the first byte after the start condition in the I2C -bus protocol
MSB
6
LSB
5
4
3
2
1
0
R/W
Fig. 32: Alignment of I2C address in 8 bit byte
There is one address byte required since 7-bit addresses are used. The last bit of the address byte
is the read/write-bit and should always be set according to the required operation. This 7-bit I2C
address is stored in the NVM. One can program a blank device with the 7-bit Slave address or
select one of the preprogrammed options. The 7-bit address plus the R/W bit create an 8-bit data
value that is sent on the bus.
The XRP7713ILB-0X10-F has an I2C address of 0x10. The internal registers are written by sending
a data value of 0x20 and read by sending a data value of 0x21. This reflects the address being
shifted one bit to the left and the least significant bit being set to reflect a read or write operation
in order to stuff the byte correctly.
The second byte sent to the XRP7713 is the location of a specific register.
Using GPIO3 to select I2C Address
GPIO3 may be used to change the LSB of the 7-bit address. This option can be enabled within the
PowerArchitectTM software by checking the “Use GPIO3 to control LSB of I2C address” box at the
top right of the “Digital Design” tab. More about the use of this option and other methods of
changing the default I2C address of the part are available in ANP-31 “PowerXR Configuration and
Programming”.
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Three Channel Digital PWM Step Controller
EXTERNAL COMPONENT SELECTION
Inductor Selection
Select the Inductor for inductance L and saturation current Isat. Select an inductor with Isat higher
than the programmed over current limit. Calculate inductance from:
Where:
𝐿𝐿 =
(𝑉𝑉𝑉𝑉𝑉𝑉 − 𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉) × 𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉 1
1
× ×
𝑓𝑓𝑓𝑓 𝐼𝐼𝐼𝐼𝐼𝐼𝑝𝑝
𝑉𝑉𝑉𝑉𝑉𝑉
Vin is the converter input voltage
Vout is the converter output voltage
fs is the switching frequency
Irip is the inductor peak-to-peak current ripple (nominally set to 30% of Iout)
Keep in mind that a higher Irip results in a smaller inductance value which has the advantages of
smaller size, lower DC equivalent resistance (DCR), and allows the use of a lower output
capacitance to meet a given step load transient. A higher Irip, however, increases the output
voltage ripple, requires higher saturation current limit, and increases critical conduction. Notice
that this critical conduction current is half of Irip.
Capacitor Selection
•
Output Capacitor Selection
Select the output capacitor for voltage rating, capacitance and Equivalent Series Resistance (ESR).
Nominally the voltage rating is selected to be at least twice as large as the output voltage. Select
the capacitance to satisfy the specification for output voltage overshoot/undershoot caused by the
current step load. A sudden decrease in the load current forces the energy surplus in the inductor
to be absorbed by Cout. This causes an overshoot in output voltage that is corrected by power
switch reduced duty cycle. Use the following equation to calculate Cout:
𝐶𝐶 = 𝐿𝐿 ×
Where:
(𝐼𝐼2 − 𝐼𝐼1 )2
𝑉𝑉𝑂𝑂𝑂𝑂 2 − 𝑉𝑉𝑂𝑂𝑂𝑂𝑂𝑂 2
L is the output inductance
I2 is the step load high current
I1 is the step load low current
Vos is output voltage including the overshoot
Vout is the steady state output voltage
Or it can be expressed approximately by
𝐶𝐶 = 𝐿𝐿 ×
(𝐼𝐼2 − 𝐼𝐼1 )2
2 × 𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉 − ∆𝑉𝑉
Here, ∆V = Vos − Vout is the overshoot voltage deviation.
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Three Channel Digital PWM Step Controller
Select ESR such that output voltage ripple (Vrip) specification is met. There are two components in
Vrip. First component arises from the charge transferred to and from Cout during each cycle. The
second component of Vrip is due to the inductor ripple current flowing through the output
capacitor’s ESR. It can be calculated for Vrip:
Where:
𝑉𝑉𝑉𝑉𝑉𝑉𝑉𝑉 = 𝐼𝐼𝐼𝐼𝐼𝐼𝐼𝐼 × �𝐸𝐸𝐸𝐸𝐸𝐸2 + �
2
1
�
8 × 𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶 × 𝑓𝑓𝑓𝑓
Irip is the inductor ripple current
fs is the switching frequency
Cout is the output capacitance
Note that a smaller inductor results in a higher Irip, therefore requiring a larger Cout and/or lower
ESR in order to meet Vrip. With the current generation of ultra-low ESR ceramic capacitors it is
common to operate with Irip ≥ 30% of Iout.
When trying to optimize control loop bandwidth, particularly at switching frequencies below
600kHz, an effective ESR in the range of 7 to 20mohm can help significantly. The Digital Power
Studio design tool is used to verify what will work best in your application.
•
Input Capacitor Selection
Select the input capacitor for Voltage, Capacitance, ripple current, ESR and ESL. Voltage rating is
nominally selected to be at least twice the input voltage. The RMS value of input capacitor current,
assuming a low inductor ripple current, can be approximated as:
Where:
𝐼𝐼𝐼𝐼𝐼𝐼 = 𝐼𝐼𝐼𝐼𝐼𝐼𝐼𝐼 × �𝐷𝐷 × (1 − 𝐷𝐷)
Iin is the RMS input current
Iout is the DC output current
D is the duty cycle
In general, the total input voltage ripple should be kept below 1.5% of VIN. The input voltage
ripple also has two major components: the voltage drop on the main capacitor ∆VCin and the
voltage drop due to ESR - ∆VESR . The contribution to Input voltage ripple by each term can be
calculated from:
∆VCin =
I outVout (Vin − Vout )
f s C inVin2
∆VESR = ESR ⋅ ( I out + 0.5 I rip )
Total input voltage ripple is the sum of the above:
∆VTot = ∆VCin + ∆VESR
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XRP7713
Three Channel Digital PWM Step Controller
Power MOSFETs Selection
Selecting MOSFETs with lower Rdson reduces conduction losses at the expense of increased
switching losses. Conduction losses are expressed by the two following equations.
High Side MOSFET Conducted Loss:
Pcond = I out ⋅ Rdson ⋅
2
Vout
Vin
Low Side MOSFET Conducted Loss:
V
2
Pcond = I out ⋅ Rdson ⋅ 1 − out
Vin
The MOSFET’s junction temperature can be estimated from:
T j = 2 Pcond Rthja + Tambient
This assumes that the switching loss is the same as the conduction loss. Rthja is the total MOSFET
thermal resistance from junction to ambient.
LAYOUT GUIDELINES
Refer to application note ANP-32 “Practical Layout Guidelines for PowerXR Designs”.
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XRP7713
Three Channel Digital PWM Step Controller
MECHANICAL DIMENSIONS
TQFN32 5 x 5
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Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
RECOMMENDED LAND PATTERN AND STENCIL
TQFN32 5 x 5
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Rev. 1.1.1
XRP7713
Three Channel Digital PWM Step Controller
REVISION HISTORY
Revision
1.0.0
1.0.3
Date
Description
February 2010 Initial Release
March 2010
Updated Diagrams
1.1.0
09/30/2010
Added references to PowerArchitect™. Revised θJA, Revised I2C Communication section.
Added “Power-Up and Sequencing Requirements”. Changed schematics to include EN
pin sequencing. Corrected conditions for LDO OUTPUT voltage at 5V. Added EN Pin
threshold specification. Changed input voltage operating range. Added GPIO3 I2C
address selection. Other minor modifications to wording. Added ESD rating. Added
Negative LX transient specification.
1.1.1
12/07/2010
Package drawing updated in revision 1.1.0 for legibility was incorrect. In particular, D2
and E2. This has been corrected
1.1.2
09/27/2018
Update to MaxLinear logo. Update format and Ordering Information. Change PGND1-3
to GL_RTN1-3. Corrected figure numbers. Updated Power Up and Sequencing
Requirements section including Figure 23 and capacitance value.
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