KT13892UG, MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ

Freescale Semiconductor
User’s Guide
Document Number: KT13892UG
Rev. 4.0, 8/2014
MC13892 Evaluation Board
Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ
Figure 1. MC13892 Evaluation Boards
Table of Contents
1 Kit Contents / Packing List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2
2 Important Notice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3
3 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4
4 Required Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8
5 Setup Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8
6 Schematics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16
7 Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .20
8 KIT13892VKEVBEJ Board Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .40
9 KIT13892VLEVBEJ Board Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .45
10 KITUSBCOMDGL Board Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .50
11 KIT13892VxEVBEJ Bill of Material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .54
12 KITUSBCOMDGLEVME Bill of Material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .56
13 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .58
14 Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .59
© Freescale Semiconductor, Inc., 2011-2014. All rights reserved.
Kit Contents / Packing List
1
Kit Contents / Packing List
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•
•
KIT13892VxEVBEJ
Kit KITUSBCOMDGLEVME
Cables (8):
• 7x2 Flat Ribbon Cable (GPIO)
• 8x2 Flat Ribbon Cable (SPI)
• 3x2 Flat Ribbon Cable (I2C)
• 1x12 Flat Ribbon Cable (3 each) (Application Peripherals)
• 1x8 Flat Ribbon Cable (Touch Screen)
• USB extension cable
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Important Notice
2
Important Notice
Freescale provides the enclosed product(s) under the following conditions:
This evaluation kit is intended for use of ENGINEERING DEVELOPMENT OR EVALUATION PURPOSES ONLY. It is
provided as a sample IC pre-soldered to a printed circuit board to make it easier to access inputs, outputs, and supply
terminals. This EVB may be used with any development system or other source of I/O signals by simply connecting it
to the host MCU or computer board via off-the-shelf cables. This EVB is not a Reference Design and is not intended to
represent a final design recommendation for any particular application. Final device in an application will be heavily
dependent on proper printed circuit board layout and heat sinking design as well as attention to supply filtering, transient
suppression, and I/O signal quality.
The goods provided may not be complete in terms of required design, marketing, and or manufacturing related
protective considerations, including product safety measures typically found in the end product incorporating the goods.
Due to the open construction of the product, it is the user's responsibility to take any and all appropriate precautions with
regard to electrostatic discharge. In order to minimize risks associated with the customers applications, adequate design
and operating safeguards must be provided by the customer to minimize inherent or procedural hazards. For any safety
concerns, contact Freescale sales and technical support services.
Should this evaluation kit not meet the specifications indicated in the kit, it may be returned within 30 days from the date
of delivery and will be replaced by a new kit.
Freescale reserves the right to make changes without further notice to any products herein. Freescale makes no
warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does
Freescale assume any liability arising out of the application or use of any product or circuit, and specifically disclaims
any and all liability, including without limitation consequential or incidental damages. “Typical” parameters can and do
vary in different applications and actual performance may vary over time. All operating parameters, including “Typical”,
must be validated for each customer application by customer’s technical experts.
Freescale does not convey any license under its patent rights nor the rights of others. Freescale products are not
designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other
applications intended to support or sustain life, or for any other application in which the failure of the Freescale product
could create a situation where personal injury or death may occur. Should the Buyer purchase or use Freescale products
for any such unintended or unauthorized application, the Buyer shall indemnify and hold Freescale and its officers,
employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and
reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such
unintended or unauthorized use, even if such claim alleges that Freescale was negligent regarding the design or
manufacture of the part.Freescale™ and the Freescale logo are trademarks of Freescale Semiconductor, Inc. All other
product or service names are the property of their respective owners. © Freescale Semiconductor, Inc., 2011-2014. All
rights reserved.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Introduction
3
Introduction
KIT13892VXEVBEJ
This EVB shows the functionality of the MC13892JVxx device set up under specific operation parameters.
The MC13892 is a SMARTMOS Power Management Integrated Circuit (PMIC) component for Freescale's i.MX51,
i.MX37, i.MX35, and i.MX27 application processors, targeting netbooks, ebooks, mobile internet devices, smart phones,
personal media players, and personal navigation devices. For evaluation purposes this KIT13892KVXXEVBE comes
with the KITUSBCOMDGLEVME board for communication and control purposes.
KITUSBCOMDGLEVME
This KIT is a USB communication dongle that uses the MC9S08JM8CLC MCU to enable communication between a
PC/laptop with a USB port, and the KIT13892VXEVBEJ, through SPI or I2C terminals.
Beside communication, this board also provides two pins for quick “plug in” identification as well as three GPIO, four
PWM signals, and two ADC. All of these pins can be configured and used as general purpose I/O pins, getting 11 GPIOs
in total, if needed.
These communication signals and GPIOs can be level shifted to 5.0 V, 3.3 V, and 1.8 V, in order to cover most of the
application voltage requirements.
3.1
KIT13892VXEVBEJ Functional Blocks
•
•
•
•
•
•
•
Charger: The charge path can be configured for single or serial path using jumpers J5 and J9 to
enable/disable the M3 transistor. CHRGSE1B pin is driven by the USB dongle MCU through a FET. This
saves the need to specify if the charger connected is a wall or USB charger through hardware.
LED Backlighting: RGB and backlighting LEDs are provided on the board to test these features. Jumpers
(J4, J7, and J3) have been placed to connect or disconnect the backlighting LEDs to their respective
channel.
Power: All the regulators and regulators signals have been connected to J17, J18, and J24 so they can be
loaded and tested from there. They also have their respective test point on the board. Regulators have a
0  resistor that allows the output to be connected to the feedback signal on the board. The feedback
signals are also available on the load connectors, so the feedback point can be connected directly to the
load by removing these resistors. These resistors are populated by default. The DVS feature of the
regulators can be controlled by means of J31/32 and J35/38 jumpers. LDOs that can be used with either
internal or external pass devices (VCAM and VGEN3) can be set for either one of both configurations by
changing the J27 and J30 jumpers positions.
Programmability and Control: The MC13892 can be configured to be controlled by I2C or SPI
communication. In I2C mode, J19 ties the CS pin to VCORE, J20 and J21 connect the pull-up resistors on
MISO and CLK respectively, and J22/23 are intended to set the A0 address at the MOSI pin. The following
pins are connected to the KITUSBCOMDGLEVME, so they can be controlled/monitored through the GUI:
CS, CLK, MISO, MOSI, WDI, INT, RESETB, RESETBMCU, STANDBY, STANDBYSEC, and PWRON1. The
SPIVCC pin can be supplied by SW4 of the MC13892, by placing the J16 jumper, or by the LDO on the
KITUSBCOMDGLEVME through the SPIVCC signals on the J10, J14, and J15 connectors. PUMS and
MODE pins can be configured through the J36/37, J40/41, and J12/13 jumpers on the board.
LICELL: The coin cell holder offers the possibility to keep the RTC running and save the contents of some
registers, even if the device is in Off mode.
USB: The VBUSEN and UID pins can be configured through the J26/28 and J34/39 jumpers. The VBUS of
the KITUSBCOMDGLEVME can be connected to the UVBUS pin of the, by means of the J29 jumper. The
UVBUS pin is also available at J2 for OTG mode.
ADC: The ADC block can be triggered by hardware by using the SW1 push button. The J25 connector
contains all the necessary signals to connect a touch screen panel. The R13 potentiometer is provided in
order to test the ADIN5 input, as well as giving the possibility to bias a battery thermistor connected there.
ADIN6 and ADIN7 have their respective test point in order to connect a specific voltage there and test these
inputs.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Introduction
3.2
KITUSBCOMDGLEVME Functional Blocks
Table 1. SPI Interface.- Pin Header Configuration for SPI Interface at J9
PIN NUMBER
DESCRIPTION
PIN NUMBER
DESCRIPTION
1
GND - Ground
9
SPSCK - SPI Serial Clock
2
ADC1 - Analog-to-Digital Regulator
10
PWM3 - Pulse Width Modulation Signal
3
COMM_V - Communication Voltage
11
MOSI - SPI Master Output Slave Input
4
ADC0 - Analog-to-Digital Regulator
12
PWMSYNC - PWM Synchronization Signal
5
5.0 V - Voltage from USB Port
13
MISO - SPI MAster Input Slave Output
6
PWM0 - Pulse Width Modulation Signal
14
ID1 - Board Identifier 1
7
PWM2 - Pulse Width Modulation Signal
15
SS - Slave Select
8
PWM1 - Pulse Width Modulation Signal
16
ID0 - Board Identifier 0
Table 2. I2C Interface.- Pin Header Configuration for I2C Interface at J7
PIN NUMBER
DESCRIPTION
PIN NUMBER
DESCRIPTION
1
ID0 - Board Identifier 0
4
GND - Ground
2
ID0 - Board Identifier 1
5
SCL - I2C Serial Clock
3
SDA - 12C Serial Data
6
COMM_V - Communication Voltage
Table 3. UART Interface.- Pin Header Configuration for UART Interface at J6
PIN NUMBER
DESCRIPTION
PIN NUMBER
DESCRIPTION
1
ID0 - Board Identifier 0
4
GND - Ground
2
ID0 - Board Identifier 1
5
RXD - Receive Data
3
TXD - Transmit Data
6
GND - Ground
Table 4. GPIO Interface.- Pin Header Configuration for GPIOs Interface at J8
PIN NUMBER
DESCRIPTION
PIN NUMBER
DESCRIPTION
1
ID0 - Board Identifier 0
8
PWM2 - Pulse Width Modulation Signal
2
ID0 - Board Identifier 1
9
PWM1 - Pulse Width Modulation Signal
3
GPIO2 - General Purpose I/O
10
PWM0 - Pulse Width Modulation Signal
4
GPIO1 - General Purpose I/O
11
ADC0 - Analog-to-Digital Regulator
5
GPIO0 - General Purpose I/O
12
ADC1 - Analog-to-Digital Regulator
6
PWMSYNC - PWM Synchronization
Signal
13
GND - Ground
7
PWM3 - Pulse Width Modulation Signal
14
COMM_V - Communication Voltage
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Introduction
Communication voltage selection - This communication board allows the user to select one of the following three
communication voltages through hardware, which are very common on most of the applications:
• 5.0 V - This voltage comes directly from the USB port and can be selected by connecting J3(1-2). This
selection ignores the voltage coming from the LDO, and sets the USB voltage as the maximum level for
communication.
• 3.3 V - This voltage can be selected by connecting J5(1-2) and J3(2-3).This selection configures the
LDO to supply 3.3 V, and set the voltage as the maximum voltage reference of communication.
• 1.8 V - This communication voltage is selected by connecting J5(2-3) and J3(2-3). By connecting these
two jumpers, the LDO supplies 1.8 V, and set this voltage level as the maximum voltage reference of
communication.
3.3
EVBs Operating Parameters
KIT13892VXEVBEJ Board
• Input voltages:
• Battery: 3.7 V
• USB/Wall charger: 5.0 V
• Power supply for backlighting: 9.0 V
• Default output voltages:
• Regulators: SW1 = 1.05 V; SW2 = 1.22 V; SW3 = 1.2 V; SW4 = 1.8 V; 
SWBST = 5.0 V (when a charger is attached, otherwise 0 V).
• Linear regulators: VUSB = 3.3 V; VUSB2 = 2.6 V; VPLL = 1.8 V; VDIG = 1.25 V; VIOHI = 2.775 V;
VGEN1 = 0 V; VGEN2 = 3.15 V; VGEN3 = 0 V; VSD = 0 V; VVIDEO = 0 V; VAUDIO = 0 V; VCAM = 0 V.
• Switching frequency in regulators: 3.1457 MHz (SWBST operates at 2.0 MHz).
• Communication interfaces:
• SPI - Frequency up to 26 MHz
• I2C - Frequency at 400 kHz
• Power control signals - RESETB, RESETBMCU, WDI, INT, STANDBY, STANDBYSEC, CHRGSE1B, and
CS
KITUSBCOMDGLEVME Board
• Power supply = 5.0 V (supplied by computer USB port)
• Communication Interfaces:
• I2C - Frequency up to 3.5 MHz (100 kHz, 400 kHz or 3.5 MHz); 
Voltage Level = Selectable (5.0 V, 3.3 V, or 1.8 V)
• SPI - Frequency up to 4.0 MHz; Voltage Level = Selectable (5.0 V, 3.3 V, or 1.8 V)
• UART - Frequency from 2400 bps to 115200 bps; Voltage Level = 12 V (Typ.)
• USB - Frequency fixed at 12 Mbps; Voltage Level = 5.0 V (Typ.)
• Other Signals:
• Four PWM signals (Adjustable frequency up to 4.0 MHz)
• Open Drain signals with selectable voltage Level (5.0 V, 3.3 V or 1.8 V)
• Three GPIOs (General Purpose I/O pins) Open Drain signals with selectable voltage Level (5.0 V, 3.3 V,
or 1.8 V)
• Two ADCs (10 bits)
• Identifiers - Two ADC signals pulled up to 5.0 V thru 10 kohm resistors. These inputs are designated to
identify the Slave device and automatically OPEN its corresponding Graphical User Interface (GUI).
This feature only applies if a slave board was designed for it.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Introduction
3.4
EVBs Features
KIT13892KVxEVBEJ Board
• Four Layer Board
• Low Noise Design
• Top and bottom Layer component placement
• Three 12 pin connectors (J17, J18, and J24) for regulators, linear regulators, and NMOS power gate
switches accessibility. Review Figures 9 and 10 schematics for connections
• Banana jack connectors (J6-J8 and J1-J2) for battery and charger attachments
• Battery holder for a CR2477 Li-Ion/Li-Pol coin cell
• Several jumper configurations for PMIC mode of operation
• Scattered test points for different measurements
• I2C and SPI communication interface connectors (J10 and J14)
• Power control interface connector (J15)
• Three RGB LEDs for color mixing or general purpose signaling
• 17 white LEDs for backlighting applications. Note that an external Boost regulator voltage needs to be
attached at TP SWLED
• Two green LEDs for RESETB and RESETBMCU signaling
• One red LED for charger attachment signaling
• Four-wire resistive touch screen interface connector (J25)
KITUSBCOMDGLEVME Board
• Four Layer Board
• Low Noise Design
• Top Layer Placement
• UART, I2C, and SPI communication interface connectors (J6, J7, and J9)
• USB type A connector
• Communication Voltage Level Shifting configuration (J3 and J5)
• BDM connector for MCU programming (J2)
• Pull-up resistors for I2C and SPI line communication voltage jumper configurations (J4)
3.5
MC13892 Device Description/Features
•
•
•
•
•
•
•
•
•
•
Battery charger system for wall charging and USB charging
10 bit ADC for monitoring battery and other inputs, plus a coulomb counter support module
Four adjustable output buck regulators for direct supply of the processor core and memory
12 adjustable output LDOs with internal and external pass devices
Boost regulator for supplying RGB LEDs
Serial backlight drivers for displays and keypad, plus RGB LED drivers
Power control logic with processor interface and event detection
Real time clock and crystal oscillator circuitry, with coin cell backup and support for external secure real time
clock, on a companion system processor IC
Touch screen interface
SPI/I2C bus interface for control and register access
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Required Equipment
4
Required Equipment
•
•
•
•
3.7 V Li-Ion battery to be connected at J6-J8
9.0 V, 500 mA power supply to be connected at test point SWLED.
5.0 V, 5.0 A, Adjustable Power Source to be connected at J1-J2
Computer Central Processing Unit (CPU) System Requirements:
• Windows eXPerience (XP)
(Note: The USB drivers for the KITUSBCOMDGLEVME MCU were developed under Windows XP operating
system)
•
•
5
1.0 Gigabyte Random Access Memory
100 Megabyte Hard Disc Drive Available Memory
Setup Configuration
Please refer to the following figures for setting up the connections between the USBCOMDGL, and either the
KIT13892VKEVBEJ or the KIT13892VLEVBEJ, by I2C or SPI communication.
Wall/USB charger
3.7 V
5.0 V
9.0 V
(‐) (+) (+) (‐)
Touch
Screen
USB Cable
KITUSBCOMDGLEVME
LiCell
(Coin Cell)
Battery
(J18, J24, J17)
Cables (Fig. 3, 4, 5, and 6)
Voltages and currents for i.MX processor and application peripherals Figure 1. MC13892 Basic Hardware Setup
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Setup Configuration
Figure 2. SPI Configuration for the MC13892JVL Board alongside the USB Dongle
Figure 3. I2C Configuration for the MC13892JVL Board alongside the USB Dongle
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Setup Configuration
Figure 4. SPI Configuration for the MC13892JVK Board alongside the USB Dongle
Figure 5. I2C Configuration for the MC13892JVK Board alongside the USB Dongle
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Setup Configuration
5.1
KIT13892VxEVBEJ Jumper Location and Configuration
2
1
3
9
8
7
6
5
4
Figure 6. KIT13892VLEVBEJ Default Jumper Location and Configuration
Location
Jumper Reference
Position
1
J40-41
2
2
J7
Shorted
3
J9
Shorted
4
J27
2-3
5
J30
2-3
6
J16
Shorted
7
J22-23
3
8
J33
Shorted
9
J36-37
3
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Setup Configuration
1
2
9
3
8
4
7
6
5
Figure 7. KIT13892VKEVBEJ Default Jumper Location and Configuration
Location
Jumper Reference
Position
1
J40-41
2
2
J36-37
3
3
J33
Shorted
4
J9
Shorted
5
J30
2-3
6
J22-23
3
7
J27
2-3
8
J16
Shorted
9
J7
Shorted
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Setup Configuration
Jumper
Reference
General
Description
J34-J39
USB ID Connection
J26-J28
J31-J32
J35-J38
J40-J41
Position
Open (default) B type plug (USB Host, OTG default master or no device) is attached
1
Grounded: A type plug (USB default slave) is attached
2
Resistor to ground: Non-USB accessory is attached
3
Tied to SWBST: Factory mode
Control VBUSEN pin Open (default) VBUSEN feature not used
DVS1 Control
DVS2 Control
PUMS1 Control
(Controls the power
up default values of
the regulators)
1
Grounded: VBUS supplied from USB cable
2
For future usage
3
Tied to SW4: VBUS supplied from SWBST if VUSBIN and OTGSWBSTEN bits = 1 (OTG mode),
or VUSB supplied from VBUS if VUSBIN = 0 and a valid VBUS is present
Open (default) Dynamic Voltage Scaling feature disabled for SW1
1
Tied to SW4: DVS feature activated. The regulator output voltage will transition to the set point
indicated in the SW1DVS bits on programmed steps
2
For future usage
3
Grounded: DVS feature deactivated and the regulator will be working on the set point indicated by
the SW1 bits
Open (default) Dynamic Voltage Scaling feature disabled for SW2
1
Tied to SW4: DVS feature activated. The regulator output voltage will transition to the set point
indicated in the SW2DVS bits on programmed steps
2
For future usage
3
Grounded: DVS feature deactivated and the regulator will be working on the set point indicated by
the SW2 bits
Open
1
2 (default)
3
J13-J12
J36-J37
Open (default)
PUMS2 Control
(Controls the power
1
up default values and
sequence of the
2
regulators)
3
Control MODE pin
Open
LEDMD String
Control
LEDAD String Control
Grounded (Check MC13892 Data Sheet for further reference on the default values)
Open (Check MC13892 Data Sheet for further reference on the default values)
Tied to VCORE: No usage on version 2.0 A of the device. For future usage
Tied to VCOREDIG: No usage on version 2.0 A of the device. For future usage
Grounded (Check MC13892 Data Sheet for further reference on the default values)
No mode selected, the device will not work
Tied to VCOREDIG: Low Power Boot allowed
Open
(default)
Open
Shorted
LEDKP String Control
Tied to VCOREDIG (Check MC13892 Data Sheet for further reference on the default values)
2
(default)
J7
Tied to VCORE (Check MC13892 Data Sheet for further reference on the default values)
Tied to VCORE: Test mode
Shorted
J4
Open (Check MC13892 Data Sheet for further reference on the default values)
1
3 (default)
J3
Function
Open
Shorted
(default)
Grounded: Normal operation
LEDMD string open. LEDMD pin unconnected
LEDMD string enabled and connected to LEDMD pin
LEDAD string open. LEDAD pin unconnected
LEDAD string enabled and connected to LEDAD pin
LEDKP string open. LEDKP pin unconnected
LEDKP string enabled and connected to LEDKP pin
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Setup Configuration
Jumper
Reference
General
Description
Position
J16
SPIVCC Supply
Open
Shorted
(default)
J19
CS pin Control
MISO Pull-up
CLK Pull-up
UVBUS Supply
VCAMDRV
Open
1-2
2-3 (default)
J30
J5
J9
VGEN3DRV
M3 FET Control 1
M3 FET Control 2
Open
PWRON1 pin Control
MOSI Control
UVBUS pin connected to J14 connector for it to be supplied from the USB cable connected to the
MCU board, or to supply a USB cable in OTG mode
VCAM regulator not used
VCAM regulator configured with external pass device 
(VCAMCONFIG bit needs to be set to 1)
VCAM regulator configured with internal pass device (VCAMCONFIG bit needs to be cleared
VGEN3 regulator not used
VGEN3 regulator configured with external pass device 
(VGEN3CONFIG bit needs to be set to 1)
2-3 (default)
VGEN3 regulator configured with internal pass device 
(VGEN3CONFIG bit needs to be cleared
Open (default) Charge path configured as Serial Path (J9 needs to be shorted)
Shorted
Charge path configured as Single Path (J9 needs to be open)
Open
M3 FET not controlled. Charge path configured as Single Path
Open
Shorted
(default)
J22-J23
Pull-up resistor on CLK pin enabled for I2C communication
1-2
Shorted
(default)
J33
Pull-up resistor on MISO pin enabled for I2C communication
Open (default) UVBUS pin disconnected from J14
Shorted
J27
Tied to VCORE: If this pin is tied to VCORE at startup, the device will be configured for I2C mode.
Open (default) Pull-up resistor on CLK pin disabled for SPI communication
Shorted
J29
SPIVCC supplied by SW4 (1)
Open (default) Pull-up resistor on MISO pin disabled for SPI communication
Shorted
J21
SPIVCC pin allowed to be supplied through connectors J10, J15, or J14
Open (default) CS pin allowed to be controlled by connector J15. If it is grounded or left open at startup, the
device will be configured on SPI mode.
Shorted
J20
Function
Open
M3 FET controlled by BATTFET pin. Charge path configured as Serial Path
PWRON1 pin can only be controlled through Switch 2
PWRON1 pin can be controlled by either Switch 2 or an MCU board connected to J15 connector
MOSI pin not connected. Not recommended
1
Grounded: A0 address = 0 on I2C communication
2
Tied to VCORE: A0 address = 1 on I2C communication
3 (default)
MOSI pin tied to J14 connector for SPI communication
Notes:
1. Due to the effect the level shifter of the KITUSBCOMDGLEVME produces on SW4, the latter will need a minimum extra load of 10 kOhm to work
properly when it is supplying SPIVCC.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
14
Freescale Semiconductor
Setup Configuration
5.2
KITUSBCOMDGLEVME Jumper Location and Configuration
1
2
Figure 8. KITUSBCOMDGLEVME Default Jumper Location and Configuration
Jumper
Reference
J5
J3
General description
Level shifted
Communication voltage
Level shifting
Communication voltage
enablement
J4
Pull up resistor enablement
for low voltage side
Location
Jumper Reference
Position
1
J5
2-3
2
J3
2-3
Position
Function
1-2
Adjust LDO voltage to 3.3 V
2 – 3 (Default)
Adjust LDO voltage to 1.8 V
1-2
2 – 3 (Default)
Set communication voltage to 5.0 V
Set communication voltage to LDO voltage
1-2
SDA pull-up resistor enable
3-4
SCL pull-up resistor enable
5-6
MISO pull-up resistor enable
7-8
SS pull-up resistor enable
9 - 10
SPSCK pull-up resistor enable
11 - 12
MOSI pull-up resistor enable
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
15
Freescale Semiconductor
A
B
C
D
J22 J23
CS
CLK
3
2
1
CS
VBUSEN
J34 J39
3
2
1
J26 J28
3
2
1
VUSB
3.3V 100mA
but battery must not be placed
UID
5
BT1
HU2477N-LF
LICELL
C52
2.2UF
C47
ACIC_VUSB 2.2UF
VBUSEN
C51
0.1UF
HDR_1X3 HDR_1X3
3
2
1
VCOREDIG
VCORE
VCOREDIG
VCORE
Licell
SPI/I2C
interface
LICELL
VUSB
VINUSB
VBUSEN
UID
UVBUS
J36 J37
3
2
1
J40 J41
3
2
1
HDR_1X3 HDR_1X3
3
2
1
VUSB
100mA
VCOREDIG Reference
Generation
REFCORE
GNDCORE
VCORE
SPIVCC
CS
CLK
MOSI
MISO
GNDSPI
CFM
CFP
Touch
Screen
interface
Battery
Interface &
Protection
HDR_1X3 HDR_1X3
3
2
1
R2
0.1
BATTISNSCC
ADTRIG
TSX1
TSX2
TSY1
TSY2
TSREF_1
TSREF_2
TSREF_3
ADIN5
ADIN6
ADIN7
GNDADC
TPGND13
C57
0.1UF
D9
D1
F2
ACIC_SWBST
G2
E6
UID
UVBUS E1
TPGND10
D7
B8
REFCORE
C35
0.1UF
B9
A9
K2
L2
M2
J2
H2
H4
REFCORE
VCOREDIG
VCOREDIG VCORE
C34
2.2UF
MISO/SDA
VCORE
MISO/SDA
K7
10.0uF K8
SPIVCC
C24
BATTISNS B12
E11
J9
J12
M12
L12
M13
N12
N13
K9
K10
M11
J6
U1
BATTISNS
ADTRIG
ADIN5
ADIN6
ADIN7
2
1
HDR 1X2 TH
J9
M3
NTHS2101P
TPGND3
SW1
1
2
FSMSM
TSREF
R20
R21
560
560
J20
J21
1 HDR 1X2 TH HDR 1X2 TH
2
2
2
1
1
HDR_1X3 HDR_1X3
ACIC_SW4
R35
3
2
200K 1
ACIC_SWBST
GPO1
0.02
R1
ADIN6
ADIN7
3
ACIC_SW4
TSX1
TSX2
TSY1
TSY2
R13 20K
10.0uF
C4
ACIC_SW4
C32
2.2UF
J19
HDR_1X3 HDR_1X3
3
2
1
CLK
HDR 1X2 TH
HDR 1X2 TH VCORE
2
1
C17
2.2UF
1
BATT
TSX1
TSX2
TSY1
TSY2
ADIN5
TSREF
J16
1
BANANA
IN
BANANA
J8
1
Licell base must be populated
VCORE
MOSI/A0
MOSI/A0
SPIVCC
ACIC_SW4
GND
IN
J6
10.0uF
C2
FDZ193P
CHRGISNS
1
IN
Charger
Interface
and Control
2
SW4
FSMSM
1
PWRON3
PWRON2
2
FSMSM
PWRON1
2
18PF
CHRGRAW
4
D12
TPGND1
Q1
2N7002
1
CHRGSE1B_CTRL
BANANA
UVBUS
J2
2.2uF
C3
SW2
1
FSMSM
SW3
1
18PF
32.768KHZ
C61
C62
Y1
IN
FDZ193P
M2 M1
R34
10M
DNP
2
4
2
D7
2
L1
VINGEN3DRV
VGEN3_1
VGEN3_2
VGEN3_3
VGEN2DRV
VGEN2
VGEN1DRV
VGEN1
VSDDRV
VSD
VCAMDRV
VCAM
VINDIG
VDIG
VINPLL
VPLL
VINIOHI
VIOHI
VINAUDIO
VAUDIO
VINUSB2
VUSB2_1
VUSB2_2
VUSB2_3
VVIDEODRV
VVIDEO
SWBSTIN
SWBSTOUT
SWBSTFB
GNDSWBST
SW4IN
SW4OUT
SW4FB
GNDSW4
SW3IN
SW3OUT
SW3FB
GNDSW3
SW2IN
SW2OUT
SW2FB
GNDSW2
SW1IN
SW1OUT
SW1FB
GNDSW1
PWGTDRV1
PWGTDRV2
PUMS2
GPO4
GPO3
GPO2 GPO4
GPO1
GPO3
GPO2
GPO1
STANDBY
INT
WDI
RESETBMCU
RESETB
STANDBYSEC
STBY
INT
R26
200K
200K
C56
C54
C48
C46
RSTB
ACIC_SW4
ACIC_VIOHI
DNP
C40
C38
C43
2.2UF
C58
2.2UF
VCC_BP
VCC_BP
2.2UF
3
R28
R27
D2
LED WHITE
1
D3
51
51
R7
PWRGT_SW1
PWR_GT1_SW1
R9
2.2uH
2.2uH
2.2uH
1.5UH
2
2
2
2
3
Q3
200K
200K
DVS2
DVS2
RSTBMCU
ACIC_SW4
ACIC_VIOHI
2.2UF
ACIC_SW4
J31
HDR_1X3
J32
HDR_1X3
1
D16
D19
LED WHITE
1
LED WHITE
0
0.1UF
C41
C39
0.1UF
C37
0.1UF
C31
0.1UF
C29
TPGND8
C18
22UF
R12
3
Q4
TPGND12
R30
R29
1
1
200K
WDI
D21
2
2
2
2
2
VSW2 ACIC_SW2
2.2UF
SWBST
ACIC_SWBST
TPGND7
VSW4 ACIC_SW4
TPGND6
VSW3 ACIC_SW3
1
R22
R19
1.2/1.25/1.65/1.8V 50mA
1.05/1.25/1.65/1.8V 50mA
2.5/2.6/2.75/3.0V 65/250mA
VPLL
ACIC_VPLL
VDIG
ACIC_VDIG
VCAM
ACIC_VCAM
0.1UF
0
ACIC_SWBSTFB
0
ACIC_SW4FB
0
ACIC_SW3FB
0
1.8/2.9 250mA
1.2/1.5/1.6/1.8/2.7/2.8/3.0/3.15V 350mA
1.2/1.5/2.775/3.15V 200mA
2
2
2
SPIVCC
Size
C
Date:
CON PLUG 12
J24
J18
J15
2
4
6
2
4
6
8
10
12
14
ID1
ID0
0
0
TSX1
TSX2
TSY1
TSY2
TSREF
1
2
3
4
5
6
7
8
ACIC_VDIG
ACIC_VGEN3
ACIC_VPLL
ACIC_VVIDEO
ACIC_VIOHI
ACIC_VAUDIO
CON_1X8
FCP: ___
1
Sheet
1
of
PUBI: ___
SCH-XXXXX PDF: SPF-XXXXX
<PageTitle>
Monday, February 22, 2010
Document Number
FIUO: X
1
Rev
X
CON PLUG 12
J17
TP2
SPIVCC
ID1
WDI
INT
RESETB
RESETBMCU
SPIVCC
1
2
3
4
5
6
7
8
9
10
11
12
J25
ID1
ACIC_VGEN1
ACIC_VGEN2
ACIC_VCAM
2
4
6
8
10
12
14
16
HDR 2X7
1
3
5
7
9
11
13
HDR_2X8
J14
CON PLUG 12
<Title>
ICAP Classification:
Drawing Title:
Page Title:
1
2
3
4
5
6
7
8
9
10
11
12
12
11
10
9
8
7
6
5
4
3
2
1
1
3
5
7
9
11
13
15
J10
HDR_2X3
1
3
5
ID1 R4
ID0 R3
1
ional Trade Commission,
ed here currently are not
United States prior to September
ckages.
PWR_GT2_SW4
ACIC_SW4FB
ACIC_SW4
ACIC_VSRTC
ACIC_SWBSTFB
ACIC_SWBST
ACIC_VSD
ACIC_VUSB
ACIC_VUSB2
ACIC_SW3
ACIC_SW3FB
PWR_GT1_SW3
ACIC_SW2
ACIC_SW2FB
PWR_GT1_SW2
ACIC_SW1
ACIC_SW1FB
PWR_GT1_SW1
UVBUS
TP1
ID0
ID0
STANDBY
STANDBYSEC
CLK
MOSI/A0
MISO/SDA
CS
HDR 1X2 TH
J33
PWRON1
J29
HDR 1X2 TH
Q13
2N7002
Q12
2N7002
MISO/SDA
CLK
CS
CHRGSE1B_CTRL
1
Because of an order from the United States Internat
BGA-packaged product lines and part numbers indicat
available from Freescale for import or sale in the
2010: MC13892VK and MC13892VL in 139, 186 MAPBGA pa
Q11
NSS12100UW3
VGEN3
ACIC_VGEN3
C63
2.2UF
VGEN2
ACIC_VGEN2
C55
VGEN1
ACIC_VGEN1
0
ACIC_SW2FB
1.8/2.0/2.6/2.7/2.8/2.9/3.0/3.15 250mA
2.775V 100mA
VIOHI
ACIC_VIOHI
ACIC_VSD
2.3/2.5/2.775/3.0V 150mA
VAUDIO
ACIC_VAUDIO
VSD
2.40/2.60/2.70/2.775V 50mA
VUSB2
ACIC_VUSB2
0.1UF
VCC_BP
0.1UF
C53
Q8
C49
NSS12100UW3
2.2UF
0.1UF
C19
0.1UF
C14
0.1UF
R18
C11
0.1UF
R17
R15
1
1
LED_GREEN
D24
RESETBMCU
200
R31
1
D25
LED_GREEN
RESETB
200
R32
ACIC_SW1FB
BATT
BATT
2.7/2.775/2.5/2.6V 250/350mA
C26
0.1UF
C22
0.1UF
2
MGSF1N02LT1G
VSW1 ACIC_SW1
TPGND5
ACIC_SWLED
PWR_GT2_SW4 PWRGT_SW4
LED WHITE
2 1
3
Q5
D18
LED WHITE
2 1
LED WHITE
2 1
D11
LED WHITE
2 1
2
NSS12100UW3
Q6
VVIDEO
ACIC_VVIDEO
C42
J30
HDR_1X3
SPIVCC
0
C64
VCC_BP
10UF
10UF
10UF
TPGND4
R14
VCC_BP
C66
C21
ACIC_VIOHI
200K
DNP
ACIC_SW4
D20
LED WHITE
2 1
2
MGSF1N02LT1G
C16
C13
C10
22UF
2.2UF
D17
LED WHITE
2 1
LED WHITE
2 1
D10
LED WHITE
1
D9
D6
LED WHITE
2 1
D8
D5
LED WHITE
2 1
PWR_GT1_SW3PWRGT_SW3
ACIC_SW4
Q10
NSS12100UW3
VCC_BP
C65
J35
HDR_1X3
J38
HDR_1X3
1
0.1UF
0.1UF
Q7
C45
NSS12100UW3
VCC_BP
Q9
NSS12100UW3
VCC_BP
C50
DVS1
1
1
D22
LED WHITE
2
MGSF1N02LT1G
ACIC_SW3
2.2UF
C25
1
D4
LED WHITE
21
PWR_GT1_SW2 PWRGT_SW2
4.7uF
J27
HDR_1X3
TPGND11
TPGND9
C27
10.0uF
R11
0
ACIC_SW2
2
MGSF1N02LT1G
51
LED WHITE
2 1
R6
VCC_BP C23
2
1
DNP
DVS1
C59
0.1UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
C30
2.2UF
VCC_BP
C36
C67
2.2UF
VCC_BP
C33
C44
L6
2.2uH
D23
L5
L3
L4
L2
2
J7
HDR 1X2 TH
MBR120LSFT1G
ACIC_SWBSTFB
VCC_BP
C28
MC13892
N3
M1
N1
N2
N4
M3
M10
N11
C2
D2
M6
K6
M9
M8
C1
E2
N10
N9
N7
N8
A3
A1
A2
B1
K12
L13
2
1
1
VCC_BP
1
1
1
3VCORE
2VCOREDIG
1
VCC_BP
J1
C20
4.7uF
K1
G4
ACIC_SW4FB
L1
A4
B4
D4
A5
D1
R10
0
VCC_BP
H1
C15
4.7uF
G1
F4
ACIC_SW3FB
F1
CLK32KMCU
CLK32K R33
STBYSEC
J12 J13
3
Q2
ACIC_SW1
HDR_1X3 HDR_1X3
3
2
1
R8
1.0M
DNP
10.0uF
C8
10.0uF
3
1
LED WHITE
J4
HDR 1X2 TH
K4
M7
VCC_BP
G13
C9
4.7uF
F13
H10
ACIC_SW1FB
E13
VCC_BP
H13
C12
4.7uF
J13
J10
ACIC_SW2FB
K13
E7
10.0uF
VGEN3
50mA
VGEN2
350mA
VGEN1
200mA
VSD
250mA
VCAM
250mA
VDIG
50mA
VPLL
50mA
VVIOHI
100mA
VAUDIO
150mA
VUSB2
50mA
VVIDEO
350mA
SWBST
350mA
Boost
SW4
800mA
Buck
SW3
800mA
Buck
SW2
800mA
Buck
SW1
1050mA
Buck
Tri-Color
LED Drive
CLK32KMCU
CLK32K
C60
2.2UF
Backlight
LED Drive
TPGND2
D15
BLUE
C7
C6
R5
1.0M
J3
HDR 1X2 TH
C1
4.7uF
ACIC_SWLED
SWLED
VCC_BP ACIC_SWBST
C5
VCC_BP
10.0uF
MBR140SFT
1
DNP
1
VCC_BP
3.3uH
DNP
1
2
GND Charger
BANANA
J1
3
2
J5
HDR 1X2 TH
1
2
8
7
6
3
2
1
4
Battery
2
LED_ORANGE
1
2D13
BATT
2
1
5
A10
BATT
B1
B2
A2
B10
BP
1
2
VCC_BP =3.6V
VCC_BP
BPSNS
D10
BATTFET
C13
BATTISNS
C1
C2
A1
C12
CHRGISNS
LED_GREEN
1
2D14
1
C2
C1
A1
1
2
1
A2
B2
B1
B11
CHRGCTRL1
A12
A13
B13
CHRGCTRL2_1
CHRGCTRL2_2
CHRGCTRL2_3
1
2
B7
E4
B5
E5
LED_ORANGE
2
1
CHRGRAW
E9
D8
E8
CHRGLED
CHRGSE1B
GNDCHRG
D12
XTAL1
N6
GNDSUB1
GNDSUB2
GNDSUB3
GNDSUB4
GNDSUB5
GNDSUB6
GNDSUB7
GNDSUB8
GNDSUB9
F6
F7
F8
G6
G7
G8
H6
H7
H8
1
BP
ACIC_VSRTC
A11
XTAL2
GNDRTC
GNDCTRL
MODE
PUMS1
PWRON1
PWRON2
PWRON3
N5
M5
H9
A8
G9
D13
E10
J8
RESETB
STANDBYSEC
F12
H12
STANDBY
INT
WDI
RESETBMCU
J5
E12
G10
F11
1
A7
D5
F5
B6
A6
NC
LEDMD
LEDAD
LEDKP
GNDSWLED
CLK32K
CLK32KMCU
VSRTC
K5
J4
M4
2
3
2
3
LEDR
LEDG
LEDB
GNDLED
GPO1
GPO2
GPO3
GPO4
B2
F10
F9
G12
DVS2
DVS1
GNDREG3
GNDREG2
GNDREG1
B3
D6
H5
G5
J7
2
3
2
3
1
3
2
1
3
2
1
2
3
1
2
3
3
2
1
3
2
1
2
3
1
2
3
1
3
2
3
2
16
2
1
A
B
C
D
6
2
1
5
Schematics
Schematics
Figure 9. KIT13892VKEVBEJ Schematic (7.0x7.0)
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
Freescale Semiconductor
A
B
C
D
HDR 1X2 TH
1
C17
2.2UF
J22 J23
3
2
1
TP30
C32
2.2UF
3
2
1
C34
2.2UF
TP31
TP29
MISO/SDA
J26 J28
3
2
1
TP38
but battery must not be placed
TP44
5
VCOREDIG
M8
B6
UID
UVBUS E1
VCOREDIG
VCORE
VCOREDIG
VCORE
Licell
SPI/I2C
interface
Touch
Screen
interface
LICELL
VUSB
VINUSB
VBUSEN
UID
UVBUS
J36 J37
3
2
1
J40 J41
3
2
1
HDR_1X3 HDR_1X3
3
2
1
10.0uF
VUSB
100mA
FDZ193P
BANANA
CHRGISNS
Y1
R34 10M
1
Charger
Interface
and Control
2
PWRON3
PWRON2
2
SW4
FSMSM
1
FSMSM
PWRON1
18PF
4
D12
TPGND1
Q1
2N7002
1
CHRGSE1B_CTRL
TP2
BANANA
UVBUS
J2
2.2uF
C3
2
18PF
32.768KHZ
C61
C62
2
IN
FDZ193P
M2 M1
IN
SW2
1
FSMSM
SW3
1
DNP
J1
4
2
VGEN3
50mA
VGEN2
350mA
VGEN1
200mA
VSD
250mA
VCAM
250mA
VDIG
50mA
VPLL
50mA
VVIOHI
100mA
VAUDIO
150mA
VUSB2
50mA
VVIDEO
350mA
SWBST
350mA
Boost
SW4
800mA
Buck
SW3
800mA
Buck
SW2
800mA
Buck
SW1
1050mA
Buck
Tri-Color
LED Drive
VINGEN3DRV
VGEN3
TP56
TP57
TP58
TP59
GPO4
GPO3
GPO2
GPO1
STANDBY
INT
WDI
RESETBMCU
TP55
TP54
TP49
STANDBYSEC
TP50
RESETB
TP48 CLK32K
CLK32KMCU
VGEN2DRV
VGEN2
VGEN1DRV
VGEN1
VSDDRV
VSD
VCAMDRV
VCAM
VINDIG
VDIG
VINPLL
VPLL
VINIOHI
VIOHI
VINAUDIO
VAUDIO
VINUSB2
VUSB2
VVIDEODRV
VVIDEO
SWBSTIN
SWBSTOUT
SWBSTFB
GNDSWBST
SW4IN_1
SW4IN_2
SW4OUT
SW4FB
GNDSW4_1
GNDSW4_2
SW3IN_1
SW3IN_2
SW3OUT
SW3FB
GNDSW3_1
GNDSW3_2
SW2IN_1
SW2IN_2
SW2OUT
SW2FB
GNDSW2_1
GNDSW2_2
SW1IN_1
SW1IN_2
SW1OUT
SW1FB
GNDSW1_1
GNDSW1_2
PWGTDRV1
PWGTDRV2
ACIC_SW1FB
VCC_BP
C9
R26
R33
DNP
1
2.2uH
L6
2.2uH
2.2uH
2.2uH
1.5UH
2
2
2
2
3
Q3
D23
C44
C43
C40
C38
C56
C54
C48
C46
2.2UF
C58
2.2UF
VCC_BP
VCC_BP
200K
TP51
ACIC_SW4
ACIC_VIOHI
3
R28
R27
DNP
TP47
C59
0.1UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
2.2UF
200K
1
2.2UF
DVS2
TP52
ACIC_SW4
51
R9
3
Q4
1
1
1
C41
C45
0.1UF
R30
1
2.2UF
0.1UF
1
200K
TP53
D18
ACIC_SW1
2.2UF
TPGND7
TP23
C19
0.1UF
C22
0.1UF ACIC_SWBST
R22
TP22 ACIC_SW4
TPGND6
TP19 ACIC_SW3
TPGND5
ACIC_SWLED
2
MGSF1N02LT1G
TP14 ACIC_SW2
TP9
2
2
2
2
2
PWR_GT2_SW4 TP8
LED WHITE
2 1
D21
LED WHITE
2 1
3
Q5
D11
LED WHITE
2 1
LED WHITE
2 1
2
R19
R18
C14
0.1UF
R17
0
2.2UF
1
ACIC_SW4FB
ACIC_SW3FB
0.1UF
2
Q11
NSS12100UW3
TP45
ACIC_VGEN3
C63
2.2UF
TP43
ACIC_VGEN2
C55
1.8/2.9 250mA
1.2/1.5/1.6/1.8/2.7/2.8/3.0/3.15V 350mA
1.2/1.5/2.775/3.15V 200mA
2.5/2.6/2.75/3.0V 65/250mA
TP39
ACIC_VCAM
TP42
ACIC_VGEN1
1.05/1.25/1.65/1.8V 50mA
TP37
ACIC_VDIG
1
D24
1
2
2
CS
CHRGSE1B_CTRL
STANDBY
STANDBYSEC
Date:
Size
C
CON PLUG 12
J24
J18
15
13
11
9
7
5
3
1
2
4
6
8
10
12
14
2
4
6
0
0
FIUO: X
GNDSUB5_1
GNDSUB5_2
GNDSUB5_3
GNDSUB5_4
GNDSUB5_5
GNDSUB5_6
GNDSUB6_1
GNDSUB6_2
GNDSUB6_3
GNDSUB6_4
GNDSUB6_5
GNDSUB6_6
GNDSUB6_7
GNDSUB7_1
GNDSUB7_2
GNDSUB7_3
GNDSUB7_4
GNDSUB7_5
GNDSUB7_6
GNDSUB8_1
GNDSUB8_2
GNDSUB8_3
GNDSUB8_4
GNDSUB8_5
TSX1
TSX2
TSY1
TSY2
TSREF
Wednesday, June 03, 2009
1
Sheet
3
SCH-26046 PDF: SPF-26046
MC13892VL INTERFACE
SPIVCC
H9
H10
H12
J5
J6
J7
J8
J9
J10
K4
K5
K6
K7
K8
K10
L4
L5
L6
L10
P5
P7
P8
P9
P10
of
3
Rev
X3
CON PLUG 12
J17
CON_1X8
J25
1
2
3
4
5
6
7
8
9
10
11
12
ID0
ID1
WDI
INT
RESETB
RESETBMCU
TP11
SPIVCC
ID1
ID1
PUBI: ___
1
2
3
4
5
6
7
8
ACIC_VDIG
ACIC_VGEN3
ACIC_VPLL
ACIC_VVIDEO
ACIC_VIOHI
ACIC_VAUDIO
ACIC_VGEN1
ACIC_VGEN2
ACIC_VCAM
J14
HDR_2X8
16
14
12
10
8
6
4
2
HDR 2X7
1
3
5
7
9
11
13
J15
MC13892VL EVB
FCP: ___
MC13892_BGA186
GNDSUB4_1
GNDSUB4_2
GNDSUB4_3
GNDSUB4_4
GNDSUB4_5
GNDSUB4_6
GNDSUB4_7
GNDSUB4_8
GNDSUB3_1
GNDSUB3_2
GNDSUB3_3
GNDSUB3_4
GNDSUB3_5
GNDSUB3_6
GNDSUB3_7
GNDSUB3_8
GNDSUB3_9
GNDSUB2_1
GNDSUB2_2
GNDSUB2_3
GNDSUB2_4
GNDSUB2_5
GNDSUB2_6
GNDSUB2_7
J10
HDR_2X3
1
3
5
ID1 R4
ID0 R3
1
CON PLUG 12
GNDSUB1_1
GNDSUB1_2
GNDSUB1_3
GNDSUB1_4
GNDSUB1_5
GNDSUB1_6
GNDSUB1_7
GNDSUB1_8
U1B
1
2
3
4
5
6
7
8
9
10
11
12
12
11
10
9
8
7
6
5
4
3
2
1
SPIVCC
Document Number
Page Title:
ICAP Classification:
Drawing Title:
G9
G10
G11
H3
H5
H6
H7
H8
F7
F8
F9
F10
G4
G5
G6
G7
G8
E7
E8
E9
E10
F4
F5
F6
A6
B3
B4
D3
D4
E4
E5
E6
PWR_GT2_SW4
ACIC_SW4FB
ACIC_SW4
ACIC_VSRTC
ACIC_SWBSTFB
ACIC_SWBST
ACIC_VSD
ACIC_VUSB
ACIC_VUSB2
ACIC_SW3
ACIC_SW3FB
PWR_GT1_SW3
ACIC_SW2
ACIC_SW2FB
PWR_GT1_SW2
ACIC_SW1
ACIC_SW1FB
PWR_GT1_SW1
UVBUS
J29
CS
HDR 1X2 TH MISO/SDA
MOSI
CLK
PWRON1
ID0
ID0
Q13
2N7002
Q12
2N7002
MISO/SDA
CLK
HDR 1X2 TH
J33
TP10
1
LED_GREEN
ACIC_SW2FB
1.8/2.0/2.6/2.7/2.8/2.9/3.0/3.15 250mA
1.2/1.25/1.65/1.8V 50mA
TP35
ACIC_VPLL
D25
RESETB
ACIC_SW1FB
TP40
ACIC_VSD
2.775V 100mA
TP34
ACIC_VIOHI
0.1UF
VCC_BP
C53
0.1UF
C49
Q8
NSS12100UW3
C66
0.1UF
2.3/2.5/2.775/3.0V 150mA
TP33
ACIC_VAUDIO
TP28
ACIC_VUSB2
0
0
0
0
1
LED_GREEN
RESETBMCU
200
R31
200
R32
ACIC_SWBSTFB
C11
0.1UF
R15
BATT
BATT
2.7/2.775/2.5/2.6V 250/350mA
C26
0.1UF
NSS12100UW3
TP26
Q6
2.40/2.60/2.70/2.775V 50mA
ACIC_VVIDEO
C42
J30
HDR_1X3
SPIVCC
0
VCC_BP
C64
10UF
10UF
10UF
TPGND4
R14
VCC_BP
ACIC_VIOHI
200K
LED WHITE
2 1
D20
LED WHITE
2 1
D17
2
MGSF1N02LT1G
C16
C13
C10
22UF
Q10
NSS12100UW3
ACIC_SW4
DNP
C39
D10
LED WHITE
2 1
LED WHITE
1
D9
D6
LED WHITE
2 1
D8
D5
LED WHITE
2 1
PWR_GT1_SW3TP7 ACIC_SW4
C21
C29
0.1UF
TPGND12
R29
0
0.1UF
Q7
NSS12100UW3
1
D19
LED WHITE
C37
0.1UF
VCC_BP
C65
D16
LED WHITE
C31
0.1UF
D22
LED WHITE
TPGND8
C18
22UF
R12
J38
HDR_1X3
J35
HDR_1X3
TP46
ACIC_SW4
J32
HDR_1X3
J31
HDR_1X3
51
R7
VCC_BP
Q9
NSS12100UW3
VCC_BP
C50
ACIC_VIOHI
200K
J27
HDR_1X3
51
R6
D4
LED WHITE
21
2
MGSF1N02LT1G
ACIC_SW3
2.2UF
C25
2.2UF
TPGND11
C36
DVS1
1
C27
TPGND9
D3
LED WHITE
2 1
PWR_GT1_SW2 TP6
4.7uF
R11
0
ACIC_SW2
2
MGSF1N02LT1G
TP5
PWR_GT1_SW1
VCC_BP
2
C23
L5
L3
L4
L2
2.2UF
VCC_BP
C33
C30
2.2UF
VCC_BP C67
VCC_BP
C28
200K
1
1
1
1
4.7uF
D2
LED WHITE
1
1 10.0uF
ACIC_SWBSTFB2
MBR120LSFT1G
VCC_BP
MC13892_BGA186
M2
N1
P4
N3
M10
M11
B1
C1
M7
L7
P11
L9
E3
D2
N10
N9
L8
N7
A3
A2
K12
L13
A5
A4
C3
D5
ACIC_SW4FB
4.7uF
H1VCC_BP
H2
C15
4.7uF
F1
G3
ACIC_SW3FB
G1
G2
VCC_BP
C20
R10
0
2
J7
HDR 1X2 TH
3VCORE
2VCOREDIG
1
3
Q2
ACIC_SW1
J13VCC_BP
J14
C12
4.7uF
L14
J12
ACIC_SW2FB
K13
K14
J1
J2
L1
J3
K1
K2
D1
LED WHITE
J4
HDR 1X2 TH
J12 J13
R8
1.0M
3
1
HDR_1X3 HDR_1X3
3
2
1
10.0uF
C8
H13
H14
F14
G12
G13
G14
P3
N8
C8
10.0uF
PUMS2
TPGND2
D15
BLUE
C7
10.0uF
C6
R5
1.0M
J3
HDR 1X2 TH
TP3 ACIC_SWLED
C1
4.7uF
VCC_BP ACIC_SWBST
C5
VCC_BP
10.0uF
C60
2.2UF
Backlight
LED Drive
1
MBR140SFT
1
3.3uH
D7
2
L1
VCC_BP
1
2
GND Charger
3
2
C2
Battery
Interface &
Protection
HDR_1X3 HDR_1X3
3
2
1
B14
VCOREDIG Reference
Generation
REFCORE
GNDCORE
VCORE
SPIVCC
CS
CLK
MOSI
MISO
GNDSPI
CFM
CFP
TPGND13
C57
0.1UF
C10
D1
R2
0.1
BATTISNSCC
ADTRIG
TSX1
TSX2
TSY1
TSY2
TSREF_1
ADIN5
ADIN6
ADIN7
GNDADC
TPGND10
B8
B9
C9
A9
K3
L2
M1
N2
P2
L3
F2
ACIC_SWBST
F3
C35
0.1UF
REFCORE
C52
2.2UF
BT1
HU2477N-LF
C51
0.1UF
C24
10.0uF M9
SPIVCC
VCORE
C47
3.3V 100mA ACIC_VUSB 2.2UF
Licell base must be populated
TP41
HDR_1X3 HDR_1X3
3
2
1
TP32
R20
R21
560
560
J20
J21
1 HDR 1X2 TH HDR 1X2 TH
2
2
2
1
1
BATTISNS B13
D13
M12
M13
M14
L11
N14
N12
P13
N13
N11
U1A
BATTISNS
ADTRIG
ADIN5
ADIN6
ADIN7
2
1
HDR 1X2 TH
J9
M3
NTHS2101P
TPGND3
SW1
1
2
FSMSM
TSREF
ACIC_SW4
HDR_1X3 HDR_1X3 TP36
ACIC_SW4
R35
3
2
200K 1
ACIC_SWBST
0.02
R1
TP13
TP15
GPO1
TSX1
TSX2
TSY1
TSY2
3
10.0uF
C4
ACIC_SW4
TP16
TP17
TP18
TP20
J34 J39
J19
BATT
R13 20K
TP12
1
TP21
HDR_1X3 HDR_1X3
3
2
1
VBUSEN
MOSI
VCORE
TP27
IN
BANANA
HDR 1X2 TH VCORE
2
1
J16
1
BANANA
J8
IN
J6
TP24 CS
TP25 CLK
SPIVCC
ACIC_SW4
GND
Battery
2
1
2
8
7
6
3
2
1
4
1
2
1
A2
B2
B1
TP4
2
1
5
A10
BATT
B1
B2
A2
B11
BP
LED_ORANGE
1
2D13
J5
HDR 1X2 TH
BPSNS
C11
BATTFET
C12
XTAL1
N6
BATTISNS
C1
C2
A1
A13
CHRGISNS
LED_GREEN
1
2D14
1
C2
C1
A1
A12
CHRGCTRL2
D9
CHRGCTRL1
LED_ORANGE
2
1
CHRGRAW
D10
B10
B12
CHRGLED
CHRGSE1B
GNDCHRG
1
2
VCC_BP =3.6V
TP1
VCC_BP
ACIC_VSRTC
A11
XTAL2
GNDRTC
GNDCTRL
MODE
PUMS1
PWRON1
PWRON2
PWRON3
N5
P6
F11
A8
C14
D11
E11
D12
RESETB
STANDBYSEC
F13
L12
STANDBY
INT
WDI
RESETBMCU
M6
E13
F12
E14
A7
D7
C7
C6
D8
SWLEDOUT
LEDMD
LEDAD
LEDKP
GNDSWLED
CLK32K
CLK32KMCU
VSRTC
M4
M3
M5
1
1
2
B5
C5
C4
D6
LEDR
LEDG
LEDB
GNDLED
GPO1
GPO2
GPO3
GPO4
B2
E12
C13
D14
GPO1
GPO2
GPO3
GPO4
2
3
1
1
3
2
1
3
2
1
DVS2
DVS1
GNDREG3
GNDREG2
GNDREG1
C2
B7
N4
E2
P12
2
3
2
3
1
2
3
3
2
1
3
2
1
2
3
2
3
2
3
1
2
3
1
3
2
3
2
2
1
17
2
1
5
A
B
C
D
Schematics
Figure 10. KIT13892VLEVBEJ Schematic (12x12)
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
Freescale Semiconductor
Schematics
USB_PWR
+ C4
USB_PWR C1
0.47UF
C5
TP1
0.10UF
1
1
13
17
22
R18
1.50K
DNP
MC9S08JM8CLCE
VUSB33
1
G
J1
D+ D-
SDA
SCL
EXTAL_JM60
XTAL_JM60
BKGD_JM60
GPIO0
GPIO1
GPIO2
ADC0
ADC1
ID0
ID1
C33
C35
C34
C36
0.10UF
0.10UF
0.10UF
0.10UF
ID0
TxD
RxD
ID1
GND
GND
0.10UF
ID0
SDA_VT
SCL_VT
2
4
6
1
3
5
ID1
GND
LDO_V
( COMM_V )
J8
ID0
GPIO2_VT
GPIO0_VT
PWM3_VT
PWM1_VT
ADC0
GND
GND2 I/O3
3
EXTAL_JM60
C40
1
1
R25
4.70K
2
12 MHz
R26
4.70K
J2
C11
22PF
BKGD_JM60
1
3
5
2
4
6
0.10UF
PWM PORT
HDR_2X7
RST_JM60
USB_PWR
HDR_2X8
/SS_VT
MISO_VT
MOSI_VT
SPSCK_VT
PWM2_VT
USB_PWR
( COMM_V ) LDO_V
GND
16
14
12
10
8
6
4
2
15
13
11
9
7
5
3
1
ID0
ID1
PWMSYNC_VT
PWM3_VT
PWM1_VT
PWM0_VT
ADC0
ADC1
J9
FIDDUCIALS
FID1
FID
100 Mil Mask
ID1
GPIO1_VT
PWMSYNC_VT
PWM2_VT
PWM0_VT
ADC1
LDO_V
C39
( COMM_V )
0.10UF
GND
HDR 2X3
GPIO PORT
2
4
6
8
10
12
14
1
3
5
7
9
11
13
FID2
FID
100 Mil Mask
LDO REGULATOR
USB_PWR
J3
ADC PORT
U8
LDO_OUT
IDENTIFIERS
TxD
RxD
UART PORT
FID3
FID
100 Mil Mask
C22
470PF
SPI PORT
I2C PORT
C21
1.0UF
R1
R27
12.0K
1
IN
3
EN
4
ADJ
2
3
2
1
ID1
ID0
OUT
5LDO_OUT
3
2
1
GND 2
SDA_VT
SCL_VT
USBDP
HDR 2X3
XTAL_JM60
MISO_VT
MOSI_VT
SPSCK_VT
/SS_VT
2
C37
HDR 2X3
J7
USB_PWR
4GND
2
1
2
4
6
1
3
5
0.10UF
Y1
ADC0
ADC1
USBDN
33
J6
1
I/O1 GND4
PWM0_VT
PWM1_VT
PWM2_VT
PWM3_VT
2
R17
CONNECTORS
1.0M
1
GPIO0_VT
GPIO1_VT
GPIO2_VT
33
1
V
DD+
G
L2
HI1812V101R-10
BDM Programmer
C10
22PF
R16
S1
A1
A2
A3
A4
GND
R21
2
L1
HI1812V101R-10
GND
1
32
31
29
28
27
26
25
24
21
20
19
18
C38
Crystal
V
2
S2
PTC1/SDA
PTC0/SCL
PTG5/EXTAL
PTG4/XTAL
BKGD/MS
PTG3/KBIP7
PTG2/KBIP6
PTD2/KBIP2/ACMP0
PTD1/ADP9/ACMPPTD0/ADP8/ACMP+
PTB5/KBIP5/ADP5
PTB4/KBIP4/ADP4
VSS
VSSAD/VREFL
VSSOSC
R20
1.50K
DNP
IRQ/TPMCLK
RESET
PTF4/TPM2CH0
PTF5/TPM2CH1
PTE0/TXD1
PTE1/RXD1
PTE2/TPM1CH0
PTE3/TPM1CH1
PTE4/MISO1
PTE5/MOSI1
PTE6/SPSCK1
PTE7/SS1
USBDN
USBDP
USB_TYPE_A
GND
14
23
30
0.10UF
1
2
3
4
5
6
7
8
9
10
11
12
15
16
2
D1
HSMG-C170
2
PWMSYNC
RST_JM60
PWM3
PWM2
TxD_JM
RxD_JM
PWM1
PWM0
MISO
MOSI
SPSCK
/SS
USBDN
USBDP
C8
1
F1
0.5A
USB_PWR
VDD
VUSB33
VDDAD/VREFH
U1
R1
270.0
USB_PWR
4.7UF
2
C3
10UF
1
+
0.10UF
USB Connector Type A
MAIN IC
MC9S08JM8CLC
VUSB33
USB_PWR
C2
2
USB_PWR
GND
C23
2.2uF
DNP
MIC5205
IDENTIFIERS
R2
USB_PWR
( COMM_V )
LDO_V
+
C24
2.2UF
J5
USB_PWR
R30
5.36K
USER INTERFACE SIGNALS
R28
10.0K
R31
20K
or MIC5235 (Ceramic Cap)
R29
10.0K
VOUT = 1.242 X ( (R2/R1) + 1)
ID0
ID1
R2 = ((VOUT/1.242) -1) X R1
J5 (1-2) for 3.3V
J5 (2-3) for 1.8V
Figure 11. KITUSBCOMDGL Schematic
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Schematics
6PWM1_VT
5PWM2_VT
4PWM3_VT
3PWMSYNC_VT
2GPIO0_VT
1GPIO1_VT
VOLTAGE TRANSLATORS
ADC1
S1
SREF
GND
GREF
DREF
D1
EXP
C9
D4
D2
D3
D7
D5
D6
0.10UF
C14
0.10UF
R24
220K
U6
1
MOSI_VT 2
MISO_VT 3
GND
4
GTL2002DC
SREF
S1
S2
GND
D10
D8
D9
D13
D11
D12
C19
GREF4
DREF4
MOSI
MISO
8
7
6
5
GREF
DREF
D1
D2
0.10UF
SCL_VT
SDA_VT
ID1
GTL2002DC
0.10UF
D14
D15
D17
D18
PWM0_VT
GREF3
DREF3
/SS
SPSCK
8
7
6
5
GREF
DREF
D1
D2
PWM1_VT
GREF
DREF
D1
D2
SREF
S1
S2
GND
ID0
SREF
S1
S2
GND
ADC0
1
/SS_VT
2
SPSCK_VT3
GND
4
C16
GREF2
DREF2
SCL
SDA
8
7
6
5
D19
USB_PWR
U4
U5
1
2
3
4
D16
PWMSYNC_VT
R22
220K
I2C
MISO_VT
( COMM_V )
SCL_VT
SDA_VT
GND
R23
220K
SPI
PWM3_VT
USB_PWR
( COMM_V )
MOSI_VT
LDO_V
USB_PWR
LDO_V
PWM2_VT
PWM1
PWM2
PWM3
PWMSYNC
GPIO0
GPIO1
13
14
15
16
17
18
D7
D6
D5
D4
D3
D2
S8
S9
S10
D10
D9
D8
R19
220K
24 GPIO2_VT
23
22
21 GREF1
20 DREF1
19 GPIO2
25
/SS_VT
PWM0_VT 7
8
9
10
11
PWM0
12
SPSCK_VT
( COMM_V )
U2
GTL2010BS
S7
S6
S5
S4
S3
S2
GPIOs
ESD PROTECTION
LDO_V USB_PWR
USB_PWR
R14
2.2K
GPIO1
GPIO2
R13
2.2K
R15
2.2K
GPIO0
R12
2.2K
R11
2.2K
PWM0
PWM1
R10
2.2K
PWMSYNC
R9
2.2K
PWM2
R8
2.2K
R7
2.2K
PWM3
C6
R6
2.2K
R5
2.2K
/SS
MOSI
SDA
SCL
R4
2.2K
SPSCK
R3
2.2K
MISO
R2
2.2K
GPIO0_VT
GPIO2_VT
PULL-UP Resistors HIGH VOLTAGE SIDE ( 5.0 V )
GPIO1_VT
GTL2002DC
C7
10PF
10PF
PULL-UP RES LOW VOLTAGE SIDE
(LDO_V = 5.0 V, 3.3 V or 1.8 V)
UART CIRCUIT
USB_PWR
LDO_V
( COMM_V )
J4
HDR_2X6
1
3
1
3
5
7
9
11
C15
0.10UF
C2+
C2-
TxD_JM
11
10
T1IN
T2IN
RxD_JM
12
9
R1OUT
R2OUT
V+
2
V-
6
T1OUT
T2OUT
14
7
TxD
R1IN
R2IN
13
8
RxD
C17
0.10UF
C26
10PF
C27
10PF
15
MISO_LVPU
MOSI_LVPU
SPSCK_LVPU
R36
2.2K
MAX232ACSE+
R37
2.2K
MISO_VT
/SS_VT
SCL_VT
SDA_VT
R35
2.2K
R34
2.2K
SPSCK_VT
R33
2.2K
MOSI_VT
R32
2.2K
/SS_LVPU
SCL_LVPU
SDA_LVPU
GND
SDA_LVPU
SCL_LVPU
MISO_LVPU
/SS_LVPU
SPSCK_LVPU
MOSI_LVPU
C1+
C1-
4
5
C18
0.10UF
C13
0.10UF
VCC
2
4
6
8
10
12
U3
16
C12
0.10UF
C28
C29
C30
C31
10PF
DNP
10PF
DNP
10PF
DNP
10PF
DNP
For 3.3 V and 1.8 V, J5 (2-3) Connected
For 5.0 V, J5(1-2) Connected
Figure 12. KITUSBCOMDGL Schematic
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
7
Software
7.1
Installing the MC13892 GUI.
The Setup installer will be provided as the MC13892 Installer.exe file.
1.
Double-Click to the executable file. The installer shall run immediately and will look like as depicted in
Figure 13.
Figure 13. License Agreement
2.
3.
4.
Press the “I Agree” button to continue with the installation process.
Figure 14 shows the application components and the device drivers for the USB Dongle. There is no
reason for users to uncheck the options to install the files.
All these files need to be installed for the proper run of the MC13892 Installer.exe application.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
Figure 14. Choose Component Window
5.
6.
Figure 15. Choose Install Location
Before the installer runs, all needed files are stored in the C:/Program Files/MC13892 folder.
Once the destination folder is selected, click “Install”. The installation of the necessary drivers begins
(Figure 16).
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
7.
Figure 16. Software Install Window
Following the correct installation of the GUI and device drivers, the KIT13892VxEVBEJ board is ready to
receive and send commands to the MC13892 Installer.exe application thru the KITUSBCOMDGLEVME
board. To finish the installation process, select the “Close” button (Figure 17).
Figure 17. Installation Complete Window
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
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7.2
Controlling the Hardware from the Graphical User interface
To interface the KITUSBCOMDGLEVME with KIT13892VxEVBEJ, the following connections should be made:
KITUSBCOMDGLEVME
Connector
KIT13892Vx EVBEJ
Connector
J8
J15
For Control signals: WDI, INT, RESETB, RESETBMCU, STANDBY, STANDBYSEC,
CHRGSE1B, CS, and PWRON1.
J9
J14
If SPI communication is desired.
J7
J10
If I2C communication is desired.
Function
After plugging the KITUSBCOMDGLEVME to the USB port of the PC/Laptop, open the MC13892 Graphical User
Interface program and click “Open USB Communications” on the main window (See Figure 18).
Figure 18. Main Screen of the MC13892 Graphical User Interface Program
A window will appear on which the desired type of communication must be chosen (See Figure 19).
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
Figure 19. Communication Type Selection Window for the SPI
Figure 20. Communication Type Selection Window for SCI
After selecting the communication type, go to the “Board Validation” tab (reference Figure 31 {5}) and set the WDI pin
high, toggle the PWRON1 button to ON, and the MC13892 will turn on. If the I2C mode is selected (Figure 20), the user
must select the I2C address to operate the MC13892 device, depending on the status of the A0 (MOSI) pin. At this point
the user can start configuring the rest of the tabs to test all the MC13892 features.
The structure of the GUI is divided in different tabs, which control different blocks of the MC13892. Each one of these
tabs controls a specific register and block of the device. From this point forward, this document will refer to specific parts
of the figures with a number in parenthesis, i.e. (1). Refer to the figure following each paragraph, to locate the referred
section.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
On the example (Figure 22), the “Power” tab has been selected (1); this tab controls the registers for the Linear
Regulators, Backlight, and RGB LED blocks. On the Buck Regulators 1 and 2/PLL sub tab (2), all the functions of these
two regulators and the PLL frequency can be changed.
The window shows the value of the register and how it changes, depending on command (3). Remember that a SPI
command consists of a Read/Write bit, six Address bits, and 24 Data bits (Figure 21).
Figure 21. Register Value Changes with Commands
After the registers have been configured on the selected tab, the “Send Command” button (4) must be selected for the
information to be sent and the registers to be written*. The button will send commands only when an open USB
communication has being established. In the current operation mode proposed earlier (Enabled Without communication
opened), these bytes will not be sent to the board. When the command has been sent, the “Command Status” bar (5)
will read “Done!”. At this point, the next command can be assembled.
When a USB communication has being established, every time a tab is being selected, the GUI will request data from
the MC13892 device and update the current tab with the received data from the board.
3
Figure 22. Writing and Reading Commands thru the Software Program
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
7.3
Power Tab
Figure 23. Linear Regulator Configuration Screen
The POWER tab includes all the controls to configure the set point of all the LDOs and regulators (1), as well as
enable/disable them (2), configure the operation mode (3), and in the case of VGEN3 and VCAM, configure them to
work with their internal or external pass device (4).
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
Figure 24. Regulators Configuration Tab Screen
In the case of the regulators, the configuration features include for example, other than the normal mode set point, the
standby set point (1), the operating mode in normal and standby modes (2), whether they will be enabled or disabled in
Memory Hold and User Off modes (3), and in the case of regulators 1 and 2, the Dynamic Voltage Scaling (DVS settings)
and the Regulator Increment/Decrement set point (SIDMIN, SIDMAX) (4 and 5 respectively).
The PLL frequency can also be configured on this tab (6).
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
Figure 25. White LED Backlighting Configuration Tab Screen
The Backlight and Tri-color LED sub-tabs include the controls to configure the Ramp and High Current Mode of the LED
drivers (1), and combo boxes to set the duty cycle and current setting of the PWM drivers (2). The Continuously On/Off
buttons (3) set the duty cycle of the corresponding PWM controller to 32/32 or 0/32 respectively.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
7.4
Charger/Power Control Tab
Figure 26. Battery Charger Configuration Tab Screen
The charger settings can be configured on the Charger sub-tab: The charger Voltage and Current (1), Power Limiter
settings (2), Trickle LED (3), and bits for Software Controlled Charging configuration (4).
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
7.5
ADC and Coulomb Counter Tabs
Figure 27. ADC Configuration Tab Screen
The MC13892 Graphical User Interface can control the ADC module in an automatic or manual method. For automatic
mode, the ADC tab has two special buttons:
• Read ADC Channel (Single Mode) (1)
• Read ADC Channels (Multi Mode) (2)
Both buttons enable and trigger the ADC before starting the conversions.
The Single mode performs eight readings of the same channel [the channel has to be selected on the Channel Selection
1 combo box (6)], and shows the results on the Read Out Value text boxes (3).
The Multi mode performs one reading of each one of the eight ADC channels, and returns eight different results shown
on the text boxes. This ADC mode automatically sets and clears specific ADC register bits to complete the readings of
all channels.
In the case of channels 6 and 7, which can be configured to read different parameters, the returned results will depend
on the LICELLCON (4) and ADIN7SEL bits (5) configuration.
The tab also includes all the necessary bit controls to manually use the ADC module (6). As an example, follow these
steps. Remember to select the “Send Command” button after each step to execute the command:
• Set the “Enable the AD Regulator” button to ON
• Set the ADCCAL bit to calibrate the ADC
• Select the channels to be read with the Channel Selection 1 and 2 combo boxes, then set the RAND
bit, if a single channel is to be read, or clear it if a multiple channel read is desired
• Move the “Select Trigger” switch to the ASC position and click the “Send Command” button
• The result of the conversions will be available on the ADC2 register (6), which can be read by clicking
the “Read ADCs” button (7). The format of the reading can be changed with the “Register Format
Display” controls (8)
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
Figure 28. Coulomb Counter Configuration Tab Screen
On the Coulomb Counter tab, a function called “Initialize CC Counter Automatically” (1) performs the following sequence
of commands:
• Start the Coulomb Counter
• Reset the Coulomb Counter
• Set the CCDITHER bit, which applies a dithering to the A to D regulator to avoid any error in the
measurement, due to repetitive events
• Set the CCCALA bit, which calibrates the Coulomb Counter
• Set ONEC Value for Coulomb Counter accuracy
• Clear CCCALA bit
This module can also be manually controlled through the CC Setting section bits (2).
The CC Counter section (3) displays the value in decimal of the module counter in the MC13892 device. Every time user
reads the counter value, this section will display the current value in the MC13892 register.
7.5.1
Sampling Periodicity (4)
The sampling periodicity section in the coulomb counter tab allows the user to retrieve the CC counter value from
MC13892 device at certain rate. The field called “Sampling Interval” lets the user request data from the Coulomb Counter
in milliseconds.
Once the “Start” button is pressed, the application automatically starts collecting data from the CC Counter and displays
it in the graph section.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
7.5.2
Plot Settings (5)
The plot setting section manages the general settings of the graphical section in the CC Counter tab. The “Line Style”
option tells the graph to display data using different painting styles such as solid, dash, and dot type lines.
The “Display Mode” has two different options indicating how data will be displayed and saved into the graph tool. The
“Pan” mode will scroll the data continuously across the screen like a standard Strip Chart. The “Wrap mode” allows the
data to remain static on the screen, while a line moves across the plot area, and everything behind the line is repainted
with the new data.
The “Plot XSpan” option sets the viewable extents of the X-Axis. When you are using the X-Axis to display Time, setting
XSpan = 1 is equivalent to setting it to 24 hours. For instance, if you want to display five seconds of data on the viewable
area, you would set XSpan = 0.00005787037037037 (1/24/60/60*5).
The button called “Line Color” lets the user change the color of the printing line in the graph. In the same row, the button
called “Print”, allows the user to print the currently displayed data in the graph.
7.5.3
XY Coordinates (6)
This section shows the exact position of the cursor in the graph area. The user is able to select any point in the graph,
and the XY Coordinates box will display the coordinates of the selected point.
7.5.4
Plot Band Track (7)
This option lets the user create a bound area between the delimited low and high sections in the graph. For instance, if
the user needs to check a specific area in the graph between 0 and 50 (shown in Figure 28), they need to set the
boundaries in the “Track Start” and “Track Stop” components accordingly, to create a delimited band.
7.6
RTC Tab
Figure 29. Real Time Clock Configuration Screen
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
The digital clock control (1) shows the current time of the RTC register of the MC13892. It is important to enable the RTC
(2) and click on the “Send Command” button for it to begin. The time can be changed at any moment using the control
text boxes (3). This tab also includes the RTC calibration controls (4).
If the “Start Read RTC” button (5) is enabled, the RTC will automatically refresh each second. This way its accuracy can
be corroborated. It is important to mention that while the RTC is being automatically refreshed, the rest of the commands
will be disabled.
As a special feature, a “Current PC Time” button (6) is available. This button reads the value of the computer clock, which
can be sent later to the RTC time register by clicking the “Send Command” button. The “Use Current PC Day”, “Use
current PC Time as Alarm”, and “Use current PC Day as Alarm” buttons will similarly set the corresponding time or day
on their respective blocks.
7.7
GPO/Sense and USB Control Tabs
The GPO/Sense tab contains the controls for the GPO pins, and allows them to turn on and off, and configure their
standby mode setting, as well as the ADC input control for GPO4. This tab also controls the Power Gating feature of the
MC13892, and senses the state of the PUMS, MODE, CHRGSE1B pins, and whether the charger is configured in Single
or Serial mode.
The USB Control tab, as its name indicates, contains all the controls of the bits that configure the USB block of the
MC13892, including the enable bit of the VUSB regulator and the bits for OTG mode control.
7.8
Interrupts Tab
This tab contains a list of all the interrupt bits of the MC13892, their masks, and sense bits. For an interrupt bit to be
reflected on the INT pin, its corresponding mask must be set to Off, and the “Send Command” button must be selected.
The INT pin status can be read in the bottom right section of the Board Validation tab. Its status can be refreshed by
clicking on the “Read Pin Status” button on top of the window. Note that the Interrupts tab indicates if the bits contained
in each column are Read or Read/Write (1), signaling that the read only bits cannot be modified through the interrupt
status tab.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
Figure 30. Interrupts Status Tab Screen
7.9
Board Validation and Scripts Tabs
These are two special tabs that control the overall functionality of the device, instead of a specific block like the rest of
the tabs.
The “Register” combo box (1) contains a list of all the MC13892 registers, in which contents will be shown on the “Bytes”
buttons (2) when they are selected in the combo box. The user can manually modify the contents of the registers by
clicking on the buttons and sending the command with the “Send Command” button. The command to be sent will be
shown in the “Command Assembled” text box (3).
A specific register can be read in the “Auxiliary Read Bytes” section (4) using the “Register” combo box placed there.
The value of the register to be read will be shown in the “Bytes” text boxed on that section. This way, the user can (for
example) check the result of an ADC conversion on the ADC2 register. They configure and trigger the ADC on the rest
of the ADC registers using sections (1) and (2). The main purpose of the Auxiliary Read Bytes section is to read the
contents from the MC13892, but not to write the registers.
In section (5), the CS, CHRGESE1B, STANDBY, STANDBYSEC, WDI, and PWRON1 pins can be controlled by clicking
their respective buttons.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
Figure 31. Board Validation Configuration Screen
7.9.1
Writing and Running a Script
Figure 32. Script Writing Configuration Command Section
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
A complete list of commands can be saved in a file to be run in series as a script. This is done with the “Board Validation”
and “Scripts” tabs. To accomplish this, first click on the “Normal Mode” button (1) in Figure 31. After clicking it, it will show
that the tab is working in “Script Mode”, in which the “Send Command” button is disabled and the commands assembled
are only intended to be saved into a file. A Read/Write button will appear (2). This button is to indicate if the assembled
command is to read or write to a specific register.
Script writing steps to write a script are listed by the following:
1.
Click the “Normal Mode” button (1) to go into Script Mode
2.
Select the register to be read/written in the “Register” combo box right above the “Normal Mode” button
3.
Specify if it will be a Read or Write command with the Read/Write button
4.
Configure the data bits using the “Bytes” buttons on the right of the Read/Write button
5.
Select the Command Iterations, Limits and Delay in section (3) of the window
– Command Iterations indicate the number of times the command will be repeated
– Command Limits is for Read commands. The user can set the limits that indicate if the read of a register is
valid or not (as a decimal number). When the script runs, a write command will compare the read value with
these limits and show if the command passed or failed. This is useful for example for ADC readings
– The Command Delay box is to specify a determined delay after the command is executed. It is given in
milliseconds
6.
Click on the “Create Command” button on section (4) of the window. The command will be saved with the
characteristics specified on section (3)
7.
The software gives the possibility to iterate a bunch of commands that are saved in a group. To do this,
after creating a bunch of commands and selecting the number of group iterations, click on the “Create
Group” button, and all the commands will be saved under that specific group. After saving the commands
into a group, they will be removed from the command list and a new group will begin. A specific name can
be assigned to a group with the “Assign Name to Group” check box. All scripts must have at least one
group in order to save them and all the commands must belong to a group, even if the group consists of a
single command.
8.
After all the commands and groups have been created and saved, click on the “Save Script” button to save
the file
The “Delete Command” button shows a list of all the created commands. The user can select a specific one and delete it.
The “Delete All Groups” button deletes all the created groups from the RAM memory.
The “New Script” button removes all the commands and groups from the RAM memory after they have been saved to
disk, to start a new script file.
7.9.2
Special RTC Commands and GPIO Commands
When running in Script Mode, special commands are added at the end of the list in the “Register” combo box. These
commands are:
RTC Set Time of Computer Clock: Takes the value of the computer clock and writes it in the RTC time register.
RTC Time Compare Between Computer Clock and MC13892: Compares the value of the MC13892 RTC with the time
of the computer clock.
GPIO “x” Write High/Low State: Where “x” represents CS, CHRGSE1B, STANDBY, STANDBYSEC, WDI, and
PWRON1. These commands simply configure the state of the listed pins.
GPIO “x” Read State: Where “x” represents CS, CHRGSE1B, STANDBY, WDI, STANDBYSEC, PWRON1, RESETB,
RESETBMCU, and INT. These commands read the state of the listed pins.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
7.10
Running a Script
Once the script has been saved, the “Scripts” tab has all the controls to run it. In the “Control Panel” section (1), click on
the “Read Script File” button and load the script. A list of all the commands of the loaded script will appear in the
“Command” window (2). A summarized view of the script can be selected with the “Collapse Command Nodes” option
on the Control Panel. After the script has been loaded, click on the “Start” button on the Control Panel, and all the
commands will be executed.
The “Input and Output Monitor Terminal” (3) will show a detailed list of all the commands sent and received, and whether
they passed or failed, according to the limits set when created. The log on this window can be saved after the script has
finished by going to the Script – Save Log Into RTF File menu at the top of the screen.
The “Compare Read Values” (4) also shows if the command currently being executed passes or fails a comparison to
the limits.
Figure 33. Script Configuration Tab Screen
7.11
Brief Example: Writing a Quick Script
The following example shows the steps to follow to write a script that will turn on the MC13892, then turn on and off the
RGB LEDs:
1.
Go to the “Board Validation” tab and click on the “Normal Mode” button to select Script Mode
2.
In the “Registers” combo box select the “GPIO WDI Write High State” command
3.
Set a command delay of 100 ms. The command iterations and limits can be left with the default values
4.
Click on the “Create Command” button
5.
In the “Registers” combo box select the “GPIO PWRON1 Write High State” command
6.
Set a command delay of 100 ms. The command iterations and limits can be left with the default values
7.
Click on the “Create Command” button
8.
In the “Registers” combo box select the “GPIO PWRON1 Write High State” command
9.
Set a command delay of 100 ms. The command iterations and limits can be left with the default values
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
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Freescale Semiconductor
Software
10.
11.
12.
13.
14.
15.
16.
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
27.
28.
29.
30.
31.
Click on the “Create Command” button
Select the “Assign Name to Group” option, and write “Turn on Sequence” in the group name text box
Click on the “Create Group” button
In the “Registers” combo box, select the “LED Control 2” register, and with the “Bytes” buttons set the
following value: 10010000 00001001 00000000. This will turn on the red and green LEDs
Set a command delay of 100 ms. The command iterations and limits can be left with the default values
Click on the “Create Command” button
In the “Registers” combo box, select the “LED Control 3” register, and with the “Bytes” buttons set the
following value: 00000000 00011001 00000000. This will turn on the blue LED and the SWBST for
supplying the LEDs
Set a command delay of 1000 ms. The command iterations and limits can be left with the default values
Click on the “Create Command” button
In the “Registers” combo box, select the “LED Control 2” register, and with the “Bytes” buttons set the
following value: 00000000 00000000 00000000. This will turn off the red and green LEDs
Set a command delay of 100 ms. The command iterations and limits can be left with the default values
Click on the “Create Command” button
In the “Registers” combo box, select the “LED Control 3” register, and with the “Bytes” buttons set the
following value: 00000000 00000000 00000000. This will turn off the blue LED and the SWBST for
supplying the LEDs
Set a command delay of 1000 ms. The command iterations and limits can be left with the default values
Click on the “Create Command” button
Select the “Assign Name to Group” option, and write “Loop” on the group name text box
Set a group iterations value of 3
Click on the “Create Group” button
Click on the “Save Script” button and select a location and a name for the script
Load the script in the “Scripts” tab using the “Read Script File” button
Verify the connections of the KITUSBCOMDGLEVME and the KIT13892VxEVBEJ.
Click on the “Start” button of the “Scripts” tab to run the script
The following example shows a script that will read, and compare the battery voltage and the RTC time. This is a more
complex script with which the user will start getting acquainted with the read value comparator:
1.
Go to the “Board Validation” tab and click on the “Normal Mode” button to select Script Mode
2.
In the “Registers” combo box, select the “GPIO WDI Write High State” command
3.
Set a command delay of 100 ms. The command iterations and limits can be left with the default values
4.
Click on the “Create Command” button
5.
In the “Registers” combo box, select the “GPIO PWRON1 Write High State” command
6.
Set a command delay of 100 ms. The command iterations and limits can be left with the default values
7.
Click on the “Create Command” button
8.
In the “Registers” combo box, select the “GPIO PWRON1 Write High State” command
9.
Set a command delay of 100 ms. The command iterations and limits can be left with the default values
10. Click on the “Create Command” button
11. Select the “Assign Name to Group” option and write “Turn on Sequence” on the group name text box
12. Click on the “Create Group” button
13. In the “Registers” combo box, select the “RTC Set Time From Computer Clock” command
14. Set a command delay of 100 ms. The command iterations and limits can be left with the default values
15. Click on the “Create Command” button
16. In the “Registers” combo box, select the “ADC 1” register, and with the “Bytes” buttons set the following
value: 00000000 00000000 00000001. This will set the ADEN bit to enable the ADC
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
38
Freescale Semiconductor
Software
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
27.
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39.
Ensure the Read/Write button says “Write” and set a command delay of 100 ms. The command iterations
and limits can be left with the default values
Click on the “Create Command” button
In the “Registers” combo box, select the “ADC 1” register, and with the “Bytes” buttons set the following
value: 00000000 00000000 00000111. This will set the ADCCAL bit to calibrate the ADC, set the RAND bit
in order to make a single channel conversion, and configure the ADAx bits to 000 (channel 0 – Battery
Voltage)
Set a command delay of 100 ms. The command iterations and limits can be left with the default values
Click on the “Create Command” button
Select the “Assign Name to Group” option and write “Initialization” on the group name text box
Click on the “Create Group” button
In the “Registers” combo box, select the “ADC 1” register, and with the “Bytes” buttons set the following
value: 00010000 00000000 00000011. This will trigger the ADC to start a conversion
Set a command delay of 1000 ms. The command iterations and limits can be left with the default values
Click on the “Create Command” button
In the “Registers” combo box, select the “ADC 2” register. Ensure the Read/Write button says “Read”. The
GUI will disregard the value contained on the “Bytes” buttons since this is a read command, so they can be
left as zeroes
Set a command delay of 100 ms. Set the commands limits as min = 10488320 and max = 12585984
(equivalent to a min of 3.0 V and a max of 3.3 V on the battery voltage)
Click on the “Create Command” button
In the “Registers” combo box, select the “RTC Time Compare Between Computer Clock and MC13892”
command. This command will ignore the Read/Write button and the values contained on the “Bytes”
buttons
Click on the “Create Command” button
Select the “Assign Name to Group” option and write “Loop” on the group name text box
Set a group iterations value of 3
Click on the “Create Group” button
Click on the “Save Script” button and select a location and a name for the script
Load the script on the “Scripts” tab using the “Read Script File” button
Verify the connections of the KITUSBCOMDGLEVME and the KIT13892VxEVBEJ.
Ensure the MC13892 has 3.3 V on the BATT pin
Click on the “Start” button of the “Scripts” tab in order to run the script
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
39
Freescale Semiconductor
KIT13892VKEVBEJ Board Layout
8
8.1
KIT13892VKEVBEJ Board Layout
Assembly Top
Figure 34. 13892VK Top Assembly Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
40
Freescale Semiconductor
KIT13892VKEVBEJ Board Layout
8.2
Top Layout
Figure 35. 13892VK Top Layout Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
41
Freescale Semiconductor
KIT13892VKEVBEJ Board Layout
8.3
Bottom Layout
Figure 36. 13892VK Bottom Layout Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
42
Freescale Semiconductor
KIT13892VKEVBEJ Board Layout
8.4
Bottom Assembly and Silk Screen
Figure 37. 13892VJ bottom assembly and silk screen layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
43
Freescale Semiconductor
KIT13892VKEVBEJ Board Layout
8.5
Fabrication Drawing
Figure 38. 13892VK Fabrication Drawing
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
44
Freescale Semiconductor
KIT13892VLEVBEJ Board Layout
9
9.1
KIT13892VLEVBEJ Board Layout
Assembly Top
Figure 39. 13892VL Top Assembly and Silk Screen Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
45
Freescale Semiconductor
KIT13892VLEVBEJ Board Layout
9.2
Top Layout
Figure 40. 13892VL Top Layout Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
46
Freescale Semiconductor
KIT13892VLEVBEJ Board Layout
9.3
Bottom Layout
Figure 41. 13892VL Bottom Layout Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
47
Freescale Semiconductor
KIT13892VLEVBEJ Board Layout
9.4
Bottom Assembly and Silk Screen
Figure 42. 13892 Bottom Assembly and Silk Screen Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
48
Freescale Semiconductor
KIT13892VLEVBEJ Board Layout
9.5
Fabrication Drawing
Figure 43. 13892VL Fabrication Drawing
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
49
Freescale Semiconductor
KITUSBCOMDGL Board Layout
10 KITUSBCOMDGL Board Layout
10.1
Assembly Top
Figure 44. USBCONDG Top Assembly Layer
10.2
Bottom Layout
Figure 45. USBCOMDG Bottom Layout Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
50
Freescale Semiconductor
KITUSBCOMDGL Board Layout
10.3
Top Layout
Figure 46. USBCOMDG Top Layout Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
51
Freescale Semiconductor
KITUSBCOMDGL Board Layout
10.4
Fabrication Drawing
Figure 47. USBCOMDG Fabrication Drawing
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
52
Freescale Semiconductor
KITUSBCOMDGL Board Layout
10.5
Silk Screen Bottom
Figure 48. USBCOMDG Bottom Silk Screen Layer.
10.6
Silk Screen Top
Figure 49. USBCOMDG Top Silk Screen Layer
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
53
Freescale Semiconductor
KIT13892VxEVBEJ Bill of Material
11 KIT13892VxEVBEJ Bill of Material
Qty
Reference
1
BT1
6
C1, C9, C12, C15, C20,
C23
C2, C4, C5(2), C6(2),
C7(2), C8(2), C24, C25
8
Value
Description
Manufacturer
Part Number
HU2477N-LF
Battery Holder CR2477 Top Load Horizontal TH
Renata Batteries
HU2477N-LF
4.7F
CAP CER 4.7F 10V 10% X5R 0603
Taiyo Yuden
LMK107BJ475KA-T
10.0F
CAP CER 10F 16V 10% X7R 0805
Capax
Technologies Inc.
0805X106K160SNT
1
C3
2.2F
CAP CER 2.2F 16V 10% X5R 0603
Murata
GRM188R61C225KE15D
2
C10,C18
22F
CAP CER 22F 10V 20% X5R 0805
Taiyo Yuden
LMK212BJ226MG-T
17
C11,C14,C19,C22,C26,
C29,C31,C37,C39,C41,
C42,C45,C49,C51,C53,
C55,C59
0.1F
CAP CER 0.1F 10V 10% X5R 0402
Kemet
C0402C104K8PAC
3
C13,C16,C21
10F
CAP CER 10F 6.3V 20% X5R 0603
Panasonic
ECJ1VB0J106M
26
C17,C27,C28,C30,C32,
C33,C34,C36,C38,C40,
C43,C44,C46,C47,C48,
C50,C52,C54,C56,C58,
C60,C63,C64, C65,C66,
C67
2.2F
CAP CER 2.2F 6.3V 20% X5R 0402
Murata
GRM155R60J225ME15D
2
C35,C57
0.1F
CAP CER 0.1F 16V 10% X7R 0402
Venkel Company
C0402X7R160-104KNE
2
C61,C62
18PF
CAP CER 18PF 50V 1% C0G 0402
Capax
Technologies Inc.
0402G180F500SNT
19
D1,D2,D3,D4,D5,D6,D8,
D9,D10,D11,D16,D17,
D18,D19,D20,D21,D22
LED WHITE
LED White SGL 35MA SMT
Nichia
NSSW100CT
1
D7(2)
MBR140SFT
Diode SCH PWR RECT 1A 40V SOD123
ON Semiconductor
MBR140SFT1G
2
D12,D13
LED_RED
LED Super Bright Red SMD 0603
Kingbright
AP1608SRC
3
D14,D24,D25
LED_GREE
N
LED GRN SGL 30MA SMT 0603
Kingbright
AP1608MGC
1
D15
BLUE
LED BL SGL 30MA SMT 0603
Kingbright
APT1608QBC/D
1
D23
MBR120LSF
T1G
Diode SCH PWR RECT 1A 20V SMT
ON Semiconductor
MBR120LSFT1G
4
J1,J2,J6,J8
BANANA
CON 1 Banana Uninsulated TH -- 531H NI
Johnson
Components Inc.
108-0740-001
11
J3,J4,J5,J7,J9,J16,J19,
J20,J21,J29,J33
HDR 1X2 TH
HDR 1X2 TH 100MIL SP 330H AU 100L
3M
929647-01-02-EU
18
J12,J13,J22,J23,J26,J27,
J28,J30,J31,J32,J34,J35,
J36,J37,J38,J39,J40,J41
HDR_1X3
HDR 1X3 TH 100MIL SP 330H SN 95L
Framatome
Connectors
International
68001-403HLF
1
J10
HDR_2x3
HDR 2X3 TH 100MIL CTR 330H SN 115L
Samtec
TSW-103-23-T-D
1
J14
HDR_2X8
HDR 2X8 TH 100MIL CTR 330H AU
Samtec
TSW-108-07-G-D
1
J15
HDR_2X7
HDR 2X7 TH 100MIL CTR 330H AU
Samtec
TSW-107-23-T-D
3
J17,J18,J24
CON PLUG
12
CON 1X12 PLUG SHRD TH 2.5MM SP 346H
SN 110L
JST MFG. CO
B12B-XASK-1N-A
1
J25
CON_1X8
CON 1X8 PLUG SHRD TH 2.5MM SP 346H SN
JST MFG. CO
B08B-XASK-1-A(LF)(SN)
1
L1(2)
3.3H
IND PWR 3.3H@100KHZ 1.4A 20% SMT
TDK
VLS252012T-3R3MR99
1
L2
1.5H
IND PWR 1.5H@1MHZ 2A 30% SMT
TDK
VLS252012T-1R5N1R4
4
L3,L4,L5,L6
2.2H
IND PWR 2.2H@1MHZ 1.8A 20% SMT
TDK
VLS252012T-2R2M1R3
2
M1,M2
FDZ193P
TRAN PMOS PWR 20V 3A BGA6
Fairchild
FDZ193P
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
54
Freescale Semiconductor
KIT13892VxEVBEJ Bill of Material
Qty
Reference
Value
Description
Manufacturer
Part Number
1
M3
NTHS2101P
TRAN MOSFET PWR SGL P-CHANNEL 8V
7.5A CHIPFET
ON Semiconductor
NTHS2101PT1G
3
Q1,Q12,Q13
2N7002
TRAN NMOS 60V 115MA SOT23
ON Semiconductor
2N7002LT1G
4
Q2,Q3,Q4,Q5
TRAN NMOS PWR 20V 750MA
ON Semiconductor
MGSF1N02LT1G
6
Q6,Q7,Q8,Q9,Q10,Q11
TRAN PNP PWR 1A 12V WDFN3
ON Semiconductor
NSS12100UW3TCG
1
R1
0.02
RES MF 0.02 OHM 1/5W 1% 0603
Vishay
Intertechnology
CRCW0603R020FKEAEL
1
R2
0.1
RES MF 0.10 OHM 1/8W 5% 0603
Venkel Company
LCR0603-R100JT
11
R3,R4,R10,R11,R12,R14
R15,R17,R18,R19,R22
0
RES MF ZERO OHM 1/16W 5% 0402
ROHM
MCR01MZPJ000
2
R5(2),R8(2)
1.0M
RES MF 1.0M 1/10W 1% 0603
KOA Speer
RK73H1JTTD1004F
3
R6,R7,R9
51
RES MF 51 OHM 1/10W 5% 0603
KOA Speer
RK73B1JTTD510J
1
R13
20K
RES POT 20K 1/4W 10% SMT
Bourns
3224W-1-203E
2
R20,R21
560
RES MF 560 OHM 1/16W 5% 0402
Venkel Company
CR0402-16W561JT
7
R26(2), R27, R28(2), R29,
R30(2), R33, R35
200K
RES MF 200K 1/16W 5% 0402
Yageo America
RC0402JR-07200KL
2
R31,R32
200
RES MF 200 OHM 1/16W 0.1% 0402
Vishay
Intertechnology
MCS04020D2000BE100
4
SW1,SW2,SW3,SW4
FSMSM
SW SPST PB 12V 50MA SMT
Tyco Electronics
1437566-4
13
TPGND1,TPGND2,
TPGND3,TPGND4,
TPGND5,TPGND6,
TPGND7,TPGND8,
TPGND9,TPGND10,
TPGND11,TPGND12,
TPGND13
TP1,TP2,TP3,TP4,TP5,
TP6,TP7,TP8,TP9,TP14,
TP19,TP22,TP23,TP26,
TP28,TP33,TP34,TP35,
TP37,TP39,TP40,TP41,
TP42,TP43,TP44,TP45
TP10,TP11,TP12,TP13,
TP15,TP16,TP17,TP18,
TP20,TP21,TP24,TP25,
TP27,TP29,TP30,TP31,
TP32TP36,TP38,TP46,
TP47,TP48,TP49,TP50,
TP51,TP52,TP53,TP54,
TP55,TP56,TP57,TP58,
TP59
BLACK
Test Point Pad Size 3.4MM X 1.8MM SMT
Keystone
Electronics
5015
U1
MC13892
MC13892
IC MCU PWR Management BGA 186
(12X12MM)
IC MCU PWR Management BGA139(7X7MM)
Freescale
Semiconductor
MC13892VL
MC13892VK
1
Y1
32.768KHZ
XTAL 32.768KHZ RSN -- SMT
Micro Crystal
CC7V-T1A 32.768KHZ
9PF+/-30PPM
9
Extra
Jumper
Shorting Jumper Unplated BLK
3M
929950-00
3
Extra
Cable
1x12
Custom
600-76735
1
Extra
Cable
1x8
Custom
600-76838
26
33
1
MGSF1N02L
T1G
NSS12100U
W3
Notes:
1. Freescale does not assume liability, endorse, or warrant components from external manufacturers that are referenced in circuit drawings or tables.
While Freescale offers component recommendations in this configuration, it is the customer’s responsibility to validate their application.
2. Do NOT populate
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
55
Freescale Semiconductor
KITUSBCOMDGLEVME Bill of Material
12 KITUSBCOMDGLEVME Bill of Material
Reference
Value
U1
MC9S08JM8CLCE
C1
0.47F
C2, C5,
C8, C9,
C14, C16,
C19, C33,
C34, C35,
C36, C37,
C38, C39,
C40
0.10F
C3
Description
Manufacturer
Part Number
IC MCU 8BIT 8K FLASH 1K RAM 48MHZ 2.7-5.5 LQFP32
Freescale
Semiconductor
MC9S08JM8CLCE
CAP CER 0.47F 16V 10% X7R 0603
Kemet
C0603C474K4RAC
CAP CER 0.10F 16V 5% X7R 0603
AVX
0603YC104JAT2A
10F
CAP CER 10F 16V 5% X7R 0603
AVX
TAJA106K016R
C4
4.7F
CAP TANT 4.7F 10V 10% -3216-18
AVX
TAJA475K010R
C6, C7,
C26, C27
10PF
CAP CER 10PF 50V 1% COG0603
Kemet
C0603C100F5GAC
C10, C11
22PF
CAP CER 22PF 16V 1% COG0603
Kemet
C0603C22F4GAC
C12, C13,
C15, C17,
C18
0.10F
CAP CER 0.10F 16V 5% X7R 0603
AVX
0603YC104JAT2A
C21
1.0F
CAP CER 1.0F 16V 10% X5R 0603
TDK
C1608X5R1C105K
C22
470PF
CAP CER 470PF 50V 5% COG 0603
Panasonic
ECJ1VC1H471J
C23
2.2F
CAP CER 2.2F 16V 10% X5R 0603
Murata
GRM188R61C225KE15D
C24
2.2F
CAP TANT ESR = 1.800 OHMS 2.2F 10V 10% 3216-18
AVX
TPSA225K010R1800
C28, C29,
C30, C31
10PF
CAP CER 10PF 50V 1% COG 0603
Kemet
C0603C100F5GAC
LED Green SGL 2.2V 20MA 0805
Avago Technologies
HSMG-C170
Diode TVS ESD PROT ULT LOW CAP 5-5.4V SOD-923
ON Semiconductor
ESD9L5.0ST5G
D1
D2-D19
HSMG-C170
ESD9L5.0ST5G
FID1,
FID2, FID3
FID
FIDUCIAL
Generic
FID-040
F1
0.5A
FUSE PLYSW 0.5A 13.2V SMT
Raychem
MICROSMD050F-2
J1
USB_TYPE_A
CON 1X4 USB TYPE A MALE RA TH 178h AU
Samtec
USB-AM-S-S-B-TH
Samtec
TSW-103-07-S-D
J2, J6, J7
HDR 2X3
HDR 2X3 TH 100MIL CTR 335H AU
J3, J5
HDR 1X3
HDR 1X3 TH 100MIL SP 330H AU
Samtec
HTSW-103-07-S-S
J4, J8
HDR 2X6
HDR 2X6 TH 100MIL CTR 330H AU
Samtec
TSW-106-07-S-D
J9
HDR 2X8
HDR 2X8 TH 100MIL CTR 330H AU
Samtec
TSW-106-07-G-D
Laird Technologies
H1812V101R-10
L1
H1812V101R-10
IND FER 100 OHM@100MHZ 8A 25% SMD/1812
L2
H1812V101R-10
IND FER 100 OHM@100MHZ 8A 25% SMD/1812
Laird Technologies
H1812V101R-10
R1
270
RES MF 270.0 OHM 1/10W 1% 0603
KOA Speer
RK73H1JTTD2700F
R2-R15,
R32-R37
2.2K
RES TF 2.20K 1/10W 1% RC0503
Bourns
CRO603FX2201E
R16, R17
33
RES MF 33.0 OHM 1/10W 1% 0603
KOA Speer
RK73H1JTTD33R0F
R18, R20
1.50K
RES MF 1.50K 1/10W 1% 0603
KOA Speer
RK73H1JTTD1501F
R19, R22,
R23, R24
220K
RES MF 220K 1/10W 5% 0603
Venkel Company
CR0603-10W-224JT
R21
1.0M
RES MF 1.0M 1/10W 1% 0603
KOA Speer
RK73H1JTTD1004F
R25, R26
4.70K
RES MF 4.70K 1/10W 1% 0603
KOA Speer
RK73H1JTTD4701F
R27
12.0K
RES MF 12.0K 1/10W 1% 0603
KOA Speer
RK73H1JTTD1202F
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
56
Freescale Semiconductor
KITUSBCOMDGLEVME Bill of Material
Reference
Value
Description
Manufacturer
Part Number
R28, R29
10.0K
RES MF 10.0K 1/10W 1% 0603
KOA Speer
RK73H1JTTD1002F
R30
5.36K
RES MF 5.36K 1/10W 1% 0603
KOA Speer
RK73H1JTTD5361F
R31
20K
RES MF 20K 1/10W 5% 0603
Bourns
CR0603-JW-203ELF
TP1
TEST POINT
Test Point Pin.138X.059 SMT
Nicomatic
C12000B
U2
GTL2010BS
IC VXLTR BIDIR 10BIT GTL-TVC 1.0-5.0V HVQFN24
NXP Semiconductors
GTL2010BS
U3
MAX232A
IC,L,MAX232A,RS232 SO16
Maxim
MAX232ACSE
IC VXLTR BIDIR 2BIT GTL-TVC 1.0-5.0V VSSOP8
NXP Semiconductors
GTL2002DC
IC LIN VREG LDO 1.5-15V 150MA 2-5-16V SOT23-5
Micrel
MIC5205YM5
Shorting Jumper Unplated BLK
3M
929950-00
XTAL 12MHZ SER 9PF SMT
ECS INC.
International
ECS-120-9-42X-CKM-TR
U4, U5, U6
U8
Qty. 2
Y1
GTL2002DC
MIC5205
Jumper
12 MHZ
Notes:
1. Freescale does not assume liability, endorse, or warrant components from external manufacturers that are referenced in circuit drawings or tables.
While Freescale offers component recommendations in this configuration, it is the customer’s responsibility to validate their application.
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
57
Freescale Semiconductor
References
13 References
The following list contains URLs where you can obtain information on other Freescale products and application
solutions:
Description
URL
Reference Web Sites
Reference URL Locations
Freescale Web Site
http://www.freescale.com/
Freescale’s Analog Web Site
www.freescale.com/analog
Data Sheet MC13892
http://www.freescale.com/files/analog/doc/data_sheet/MC13892.pdf
Freescale Power Management Web Site
http://www.freescale.com/webapp/sps/site/taxonomy.jsp?nodeId=01435979961182
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
58
Freescale Semiconductor
Revision History
14
Revision History
Revision
Date
4.0
8/2014
Description of Changes
• Updated kit contents/packing list
• Added revision history page
• Updated back page
MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ, Rev. 4.0
59
Freescale Semiconductor
How to Reach Us:
Information in this document is provided solely to enable system and software implementers to use Freescale products.
Home Page:
freescale.com
There are no express or implied copyright licenses granted hereunder to design or fabricate any integrated circuits based
Web Support:
freescale.com/support
Freescale reserves the right to make changes without further notice to any products herein. Freescale makes no
on the information in this document.
warranty, representation, or guarantee regarding the suitability of its products for any particular purpose, nor does
Freescale assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any
and all liability, including without limitation consequential or incidental damages. “Typical” parameters that may be
provided in Freescale data sheets and/or specifications can and do vary in different applications, and actual performance
may vary over time. All operating parameters, including “typicals,” must be validated for each customer application by
customer’s technical experts. Freescale does not convey any license under its patent rights nor the rights of others.
Freescale sells products pursuant to standard terms and conditions of sale, which can be found at the following address:
freescale.com/SalesTermsandConditions.
Freescale and the Freescale logo are trademarks of Freescale Semiconductor, Inc., Reg. U.S. Pat. & Tm. Off.
SMARTMOS is a trademark of Freescale Semiconductor, Inc. All other product or service names are the property of their
respective owners.
© 2014 Freescale Semiconductor, Inc.
Document Number: KT13892UG
Rev. 4.0
8/2014

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KT13892UG, MC13892 Evaluation Board Supports KIT13892VKEVBEJ and KIT13892VLEVBEJ - User s Guide