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Freescale Semiconductor, Inc.User’s Guide
© Freescale Semiconductor, Inc., 2014. All rights reserved.
Document Number: KT9Z1_638UGRev. 1.0, 3/2014
KIT9Z1J638EVM Evaluation BoardFeaturing the MM9Z1J638 Intelligent Battery Sensor Module
Figure 1. KIT9Z1J638EVM Evaluation Board
Contents1 Kit Contents/Packing List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
2 Jump Start . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
3 Important Notice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
4 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
5 Evaluation Board Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
6 MM9Z1J638 Device Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
7 Required Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
8 Evaluation Board Configuration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
9 Setting Up and Using the Hardware and Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
10 Schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
11 Board Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
12 Bill of Material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
13 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
14 Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
KT9Z1_638UG User’s Guide Rev. 1.0 3/20142 Freescale Semiconductor
Kit Contents/Packing List
1 Kit Contents/Packing List• Assembled and tested evaluation board/module in anti-static bag. • USB cable• Warranty card
2 Jump Start• Go to www.freescale.com/analogtools• Locate your kit• Review your Tool Summary Page• Look for
• Download documents, software, and other information
Jump Start Your Design
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 3
Important Notice
3 Important NoticeFreescale 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 evaluation board 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 evaluation board 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. 2014
KT9Z1_638UG User’s Guide Rev. 1.0 3/20144 Freescale Semiconductor
Introduction
4 IntroductionFreescale’s KIT9Z1J638EVM is a hardware tool for evaluation and development. It is ideal for rapid prototyping of MCU-based applications for current, voltage and temperature sensing. The intelligent battery sensor MM9Z1J638 hardware, KIT9Z1J638EVM, is a simple, yet sophisticated design featuring an intelligent battery sensor with CAN and LIN.
KIT9Z1J638EVM can be used to evaluate the MM9Z1_638 family device. It features a MM9Z1J638, integrating a S12Z MCU and a SMARTMOS analog control IC into a single-package solution. The MM9Z1J638 enables precision measurement of key battery parameters, current, voltage and temperature. The acquisitions are run through three 16-bit sigma-delta ADCs embedded into the analog IC.
The MM9Z1J638 features a LIN protocol and physical interface compatible with LIN 2.0/2.1/2.2 requirements and MSCAN protocol controller and supply capability for 8 and 14 pin CAN interface.
The on-board interfaces include CAN, LIN. The CAN Physical Layer footprint allows to mount 8- or 14-pin CAN interface; the connection of the physical layer to MM9Z1J638 is done through jumpers to allow each configuration.
The KIT9Z1J638EVM is featuring Open Source BDM (OSBDM) providing low-speed debug communications to the S12Z core.
5 Evaluation Board FeaturesThe KIT9Z1J638EVM evaluation board demonstrates the MM9Z1J638 multi-chip module IC. The board’s main features are as follows:
• MM9Z1J638 intelligent battery sensor in a 48-QFN package with wettable flank• High-speed CAN interface using MC33901, high-speed CAN transceiver and msCAN protocol layer
embedded into the MM9Z1J638• LIN interface• Customizable GPIOs for voltage and temperature sensing• LED indicators• Onboard BDM connection via open source OSBDM circuit using the MC9S08JM60 MCU. • Support for external BDM interface (for instance P&E USB Multilink BDM interface)
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 5
Evaluation Board Features
Figure 2. KIT9Z1J638EVM Block Diagram
OSBDM
Mini-BUSB
MC9S08JM60 Intelligent Battery Sensor
MM9Z1J63848 QFN
BKGD
RESET
USBD+/D-
ExternalBDM Port
LIN PHY
msCAN MC33901
Rx
Tx
GND/VBAT
Current Sense Input PinsISENSEL
/ISENSEH
Voltage Sense Input PinsPTB[4..0]
DB9 CAN Connector
CANH
CANL
LINConnector
LIN
CANL
Voltage Sense Input Pins
VSENSE[3..0]
External Temperature Sense Input
PinsPTB[4..0]
KT9Z1_638UG User’s Guide Rev. 1.0 3/20146 Freescale Semiconductor
MM9Z1J638 Device Features
6 MM9Z1J638 Device FeaturesThe MM9Z1J638 is a fully integrated intelligent battery sensor device. The device supports precise current measurement via an external shunt resistor. It features four voltage measurements via an internal calibrated resistor divider or use of an external divider. Specific device functions include the following:
• Wide range battery current measurement; on-chip temperature measurement• Four battery voltage measurements with internal resistor dividers, and up to five direct voltage
measurements for use with an external resistor divider• Measurement synchronization between voltage channels and current channels• Five external temperature sensor inputs with internal supply for external sensors• Low-power modes with low-current operation• Multiple wake-up sources: LIN, timer, high-voltage input, external CAN interface, and current
threshold and integration• Precision internal oscillator and connections for external crystal• LIN 2.2/2.1/2.0 protocol and physical interface• MSCAN protocol controller, and supply capability for 8 and 14-pin CAN interfaces• S12Z microcontroller with 128 kByte Flash, 8.0 kByte RAM, 4.0 kByte EEPROM
7 Required EquipmentMinimum equipment required:
• DC power supply with 12 V voltage capability and 300 mA current capability• Oscilloscope (preferably four-channel)• Digital multimeter • USB-enabled PC with Windows XP or higher and CodeWarrior 10.x installed
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 7
Evaluation Board Configuration
8 Evaluation Board Configuration
Figure 3. KIT9Z1J638EVM Board Setup
Figure 4. Switch S1 Settings
OSBDM Connector
BDMConnector
Switch S1
Power Supply
LED D6
LED D7
USB
CAN Connector
LIN Connector
VBATGND
VSENSE3
PTB4Ext WU
VSENSE2
VSENSE1
VSENSE0
ISENSEH
ISENSEL
PTB Thermal Sense PTB Voltage Sense
CAN Transceiver (U2)
When using the OSBDM USB interface,set the following S1 switch settings:
When using the BDM connector,set the following S1 switch settings:
KT9Z1_638UG User’s Guide Rev. 1.0 3/20148 Freescale Semiconductor
Setting Up and Using the Hardware and Software
9 Setting Up and Using the Hardware and SoftwareIn order to perform the demonstration examples, first setup the evaluation board hardware and software as follows:
1. Download CodeWarrior 10.4 or higher, using the instructions in the “Jump Start” section.
2. Install CodeWarrior Suite on to a USB-enabled PC running Windows XP or higher.
3. Connect the USB cable from the OBSDM port on the evaluation board to computer.
4. Without turning on the power, connect the positive voltage output (set for +12V) of the DC power supply to the VBAT terminal on the board (schematic label CN5). Connect the ground line from the supply to the GND terminal on the board (CN6).
5. Launch the CodeWarrior Suite.
6. Turn on the power supply.
7. Start development of your application using CodeWarrior.
Notes:
1. Notice on the EVM, for proper operation connect RESET to RESETA, by setting pin 1 of the S1 Switch ON. The S1 switch is not always set, because when flashing the part, there is flow between the reset drive from the BDM interface and the reset from the analog die (through the watchdog). A workaround is to add a 470 nF capacitor between RESET and GND on the BDM interface. This prevents resets while flashing. Disconnecting both pins through the switch S1-1 on KIT9Z1J638EVM avoids this workaround.
2. The RESET pin of the MM9Z1J638 is a reset Input/Output pin of the embedded MCU, so when hitting BP1, the embedded MCU will be reset. RESETA pin of MM9Z1J638 is a reset output (when in normal mode), so setting RESETA pin to 0 will not reset the analog die. This must be done through the HWR bit of the PCR_CTL register. Each time there is a RESET of the MCU, check that the HWRF bit is set. If not, a command reset to the analog die through HWR of PCR_CTL is needed.
9.1 GPIO SetupThe KIT9Z1J638EVM is offering a customizable set of general purpose IOs for measurement of external temperature or voltage through the dedicated 16-bit sigma-delta ADCs of the MM9Z1J638, intelligent battery sensor.
The customization must be performed by setting the right set of components on the selected PTB. Footprints and dedicated banana connectors are available on the board to customize the KIT9Z1J638EVM according to your application needs.
• PTB[3…1] can also be set as 5.0 V IOs which might be connected to TIMer and/or SCI (UART) modules.
• PTB4 can be set as a 5.0 V input and offers extra functionalities such as a CAN wake-up pin and high voltage wake-up input pin.
• PTB5 is a ground switch and is used while monitoring external temperatures to minimize power consumption.
Refer to the schematics in Figure 5.
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 9
Setting Up and Using the Hardware and Software
Figure 5. Using GPIOs as Voltage Sense or External Temperature Sense Inputs
Refer to the MM9Z1_638D1 data sheet for further information regarding voltage and external temperature sensing. Refer to Figure 8 for the component for every GPIO.
Refer to Assembly Layer Top for the localization of components and footprint on the KIT9Z1J638EVM.
Note: GPIO pins might also be connected to OSBDM to set Serial to the USB port. This is done by connecting:
TxD from SCI to one pin out of PTB[3…1], then the selected PTB to JP4-2.
RxD from SCI to one pin out of PTB[4…1], then the selected PTB to JP4-1.
Insure that the two selected PTB pins have no other setting (voltage sensing external divider, external temperature sensing setup), which might conflict with the 5.0 V digital IO setup.
9.2 CAN Configuration
The KIT9Z1J638EVM board comes with an 8-pin high-speed CAN transceiver MC33901, mounted in the U2 position.This transceiver is configured using jumpers JM1 to JM9.
The KIT9Z1J638EVM is highly configurable to set the product within the configuration closest to designer needs, and showcases the versatility of the MM9Z1_638 product. It allows using an 8-pin (without SPLIT pin version) or a 14-pin CAN transceiver as a CAN transceiver. This is done by setting the device in the U2 position on the board, according to Figure 6, and to connect pins through the jumpers as shown in Figure 7.
PTB[4…0] Voltage Sensing External Divider with R1 and R2
PTB[4…0] External TemperatureSensing Thermistor RT
KT9Z1_638UG User’s Guide Rev. 1.0 3/201410 Freescale Semiconductor
Setting Up and Using the Hardware and Software
Figure 6. CAN Transceiver Placement
The connection between CAN transceiver is configured using the jumpers JM1 to JM9. There is one configuration for 8 pins and two for 14 pins.
Figure 7. CAN Jumper Connections
9.3 Hardware DescriptionThis evaluation kit features one MM9Z1J638 (intelligent battery sensor), one MC33901 (high-speed CAN Interface), and one MC9S08JM60CQH (OSBDM debug interface). The board-level logic diagram is show in Figure 2.
9.4 LED DisplayThe following LEDs are provided as visual output devices for the KIT9Z1J638EVM evaluation board:
1. LED D3 indicates when switch S3-2 is ON and PA6 is set to 5.0 V
2. LED D4 indicates when switch S3-1 is ON and PA7 is set to 5.0 V
3. LED D6 indicates when OSBDM is powered by a USB cable
4. LED D7 indicates when OSBDM is connected to the MM9Z1J638 through S1-2, S1-3, S1-4, and the MM9Z1J638 is powered through VBAT and GND connections
U2 mounted with 8-pin CAN transceiver
U2 mounted with 14-pin CAN transceiver
14-pin CAN operation:Low-power mode = sleep mode on MM9Z1J638 - WU through INH
14-pin CAN operation:Low-power mode = stop mode on MM9Z1J638 - WU through RxD
8-pin CAN operation
Note: Jumpers in orange have to be connected for proper operation
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 11
Setting Up and Using the Hardware and Software
9.5 Test Point DefinitionsThe following test-point jumpers provide access to signals on the KIT9Z1J638EVM IC:
Table 1. Test Point Jumpers and Description
Test Point Number Description
TP1 PA7
TP2 VDDL
TP3 PTB0
TP4 PTB1
TP5 PTB2
TP6 PTB3
TP7 PA6
TP8 PA5
TP9 PA4
TP10 VSENSE3
TP11 VSEMSE2
TP12 VSENSE1
TP13 VSENSE0
TP14 ISENSEH
TP15 ISENSEL
TP16 PTB4
TP17 PTB5
TP18 VDDX
TP19 VDDH
TP20 VSUP
TP21 LIN
TP22 VDDA
TP23 ELE_PS_SENSE
TP24 RESET
TP25 RESETA
TP26 GND
TP27 GND
TP28 GND
TP29 GND
TP30 GND
TP31 GND
TP32 GND
TP33 GND
TP34 GND
TP35 CANH
TP36 CANL
KT9Z1_638UG User’s Guide Rev. 1.0 3/201412 Freescale Semiconductor
Schematic
10 Schematic
Figure 8. Evaluation Board Schematic, Part 1
12
34
56
ABCD
65
43
21
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Num
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14VDDD2D 15
NC 16
DGND 17
VDDH 18
GNDSUB 19
VDDX 20
NC 21
VSUP 22
LIN 23
LGND 24
VDDA 25AG
ND
26PT
B5_
GN
D_S
W27
PTB
4_L
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GN
DSU
B29
ISE
NSE
L30
ISE
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H31
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CG
ND
32V
SEN
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SE2
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SE3
36
PTB337 PTB238 PTB139 PTB0_TCLK40 GNDSUB41 VDDL42 TEST_A43 DGND44 RESET_A45 RESET46 BKGD47 PA748
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GN
DG
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PA5
PA4
PA3
PA2
PA1
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VDDX
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VDDA
PTB
5PT
B4
ISE
NSE
LIS
EN
SEH
VSE
NSE
0V
SEN
SE1
VSE
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2V
SEN
SE3
PA7BKGDRESETRESET_A
VDDL
PTB0PTB1PTB2PTB3
C5
18pf
- dn
pC
618
pf -
dnp
PE1
PE0
X1 4M
Hz
- dnp
GN
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GN
D
C11
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GN
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C12
470n
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GN
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CN
6B
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R31
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CN
16
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R32
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CN
17
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R33
2.2k
CN
18
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R36
2.2k
CN
23
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VSE
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2
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R6
100k
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2
BA
NA
NA
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R3
1.8k
- dn
p
GN
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R4
100k
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DA
R9
2.2k
CN
3
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R10
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- dn
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4
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R7
1.8k
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GN
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R8
100k
VD
DA
R14
2.2k
- dn
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CN
7
BA
NA
NA
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PTB
2
R15
100k
CN
8
BA
NA
NA
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LL
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R12
1.8k
GN
D
R13
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R18
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9
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R19
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R16
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D
R17
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DA
R35
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CN
22
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NA
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C1
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GN
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C2
2.2n
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D
C8
2.2n
GN
D
C7
2.2n
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D
C19
2.2n
GN
D
PTB
5
D5
5.1V
GN
D
TP18
TSTP
T
TP19
TSTP
T
TP20
TSTP
TTP
21TS
TPT
TP22
TSTP
T
TP17
TSTP
T
TP16
TSTP
T
TP15
TSTP
T
TP14
TSTP
T
TP13
TSTP
T
TP12
TSTP
T
TP11
TSTP
T
TP10
TSTP
T
TP6
TSTP
TTP
5TS
TPT
TP4
TSTP
TTP
3TS
TPT
TP2
TSTP
T
TP8
TSTP
TTP
9
TSTP
T
TP7
TSTP
T
TP1
TSTP
T
STB
b14
CA
NH
13
CA
NL
12
SPL
IT11
VB
AT
10
WA
KE
9
TX
D1
GN
D2
VC
C3
RX
D4
VIO
5
EN
6
INH
7E
RR
b8
U2
TJA
1041
- dn
p
1243
S3 SW D
IP-2
PA6
PA7
CA
N_V
SUP
C18
2.2u
- dn
p
GN
D
GN
D
R34
120
- dnp
GN
D
C17
4.7u
- dn
p
GN
D
CA
N_5
V
CA
N_T
XD
CA
N_R
XD
CA
N_E
NC
AN
_IN
H
CA
N_S
TB
b
CA
N8_
VIO
JM1
PCB
CAN8_VIO
JM4
PCB
JM5
PCB
JM6
PCB
JM3
PCB
JM7
PCB
JM8
PCB
JM2
PCB
12
JMP2
2PT
S
PA5
VD
DX
PA4
PA1
CA
N_T
XD
CA
N_5
V
CA
N_R
XD
CA
N_E
N
EX
T_W
U
PA0
VSU
PC
AN
_VSU
P
CA
N_S
TB
b
CA
N_I
NHR
T1
10k
PTB
5_T
_IN
PUT
PTB
5_T
_IN
PUT
RT
2
10k
PTB
5_T
_IN
PUT
RT
4
10k
- dnp
PTB
5_T
_IN
PUT
RT
3
10k
- dnp
PTB
5_T
_IN
PUT
R29
2.2k
CN
14
BA
NA
NA
_BL
UE
R30
100k
- dn
p
CN
15
BA
NA
NA
_YE
LL
OW
R27
1.8k
- dn
p
GN
D
R28
100k
VD
DA
C15
2.2n
GN
D
RT
5
10k
PTB
5_T
_IN
PUT
123
JMP1
PTB
4
PTB4_WUPTB4PTB4_SENSE
BP2
dtsm
w-6
9nG
ND
R25
47k
VD
DX
PA7
R26
47k
C14
2.2n
GN
D
CN
21B
AN
AN
A_G
RE
EN
mm
912_
638_
evb_
osbd
mm
m91
2_63
8_ev
b_os
bdm
.sch
EX
T_W
U
JM9
PCB
EX
T_W
UC
AN
_RX
D
C28
220p
F
GN
D
BP3
dtsm
w-6
9n
VSU
P
TP24
TSTP
TTP
25TS
TPT
TP26
TSTP
TTP
27TS
TPT
TP28
TSTP
TTP
29TS
TPT
TP30
TSTP
TTP
31TS
TPT
GN
D
R1
3.3k
VD
DX
GN
D
TP33
TSTP
T - d
np
TP32
TSTP
T - d
np
CA
NH
CA
NL
1 6 2 7 3 8 4 9 5
J5 DB
9 - d
np
GN
D
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 13
Schematic
Figure 9. Evaluation Board Schematic, Part 2
12
34
56
78
ABCD
87
65
43
21
D C B A
R74
10k
R73
10k
R75
10k
R77
10k
R79
10k
R78
10k
R66
47
Q3
3904
Q5
3906
R76
10k
V_T
RG
V_T
RG
5V_S
W
TRE
SET_
OU
T
TRE
SET_
IN
RE
SET
OU
T/IN
VC
CA
1
A3
GN
D2
VC
CB
6
B4
DIR
5
U9
SN74
LVC
1T45
VC
CA
1
A3
GN
D2
VC
CB
6
B4
DIR
5
U10
SN74
LVC
1T45
TXD
RX
D_V
IRTU
AL_
TOT
RX
DTX
D_V
IRTU
AL_
TOT
5V_S
WV
_TR
G
V_T
RG
5V_S
W
5V_S
W
VIR
TUA
L S
ER
IAL
PO
RT
VC
CA
1
A3
GN
D2
VC
CB
6
B4
DIR
5
U3
SN74
LVC
1T45
5V_S
W
TBG
ND
_OU
T
TBG
ND
_IN
R37
4.7k
V_T
RG
TBG
ND
_EN
IN7
EN
A1
EN
B4
FLG
A2
FLG
B3
AO
UT
8
BO
UT
5
GN
D6
U4
MIC
2026
BG
ND
SW
ITC
H
C20
0.1u
f
5VU
SB
R46
10k
R45
10k
R43
10k
R42
10k
R44
2.2k
5VSW
_EN
VTR
G_E
N 5VSW
_FA
ULT
VTR
G_F
AU
LT
+
C21
10uF
5V_S
W
11
33 2 2
U5
PDTC
115T
IN1
EN
3
GND 2
NR
4
OU
T5
U6
TPS7
9933
5V_T
RG
+C
2210
μF
R47
10k
ELE
_PS_
SEN
SE
C23
100p
f
+C
2410
μF
3V_T
RG
POW
ER
GE
NE
RA
TOR
3V re
gula
tor i
s op
tiona
l
C25
18pf
C26
18pf
R48
1M
O_X
TAL
O_E
XTA
L
R38
10k
R40
TBD
1%
R41
TBD
1%
R54
TBD
1%
R53
TBD
1%
R50
10K
R49
10K
OSB
DM
_RE
V2
OSB
DM
_RE
V1
OSB
DM
_RE
V0
BR
D_I
D1
BR
D_I
D0
OSB
DM
and
MC
UID
VE
RSI
ON
ING
X2 4M
Hz
Q1
3904
- dn
p
Q2
3906
- dn
p
R64
10k
- dnp
R65
10k
- dnp
R57
4.7k
- dn
p
R58
10k
- dnp
R67
100
- dnp
R68
1k -
dnp R69
4.7k
- dn
p
C39
1nf -
dnp
VPP
_EN
TRG
_RST
11
22
33
D10
BA
T54C
- dn
p
V_T
RG
VIN
5
EN
4
SW1
FB3
GND 2
U8
TPS6
1041
- dn
p
11
22
33
D8
BA
T54C
- dn
p
L1 10uH
- dn
p
D9
SS12
- dn
p
R72
9.09
k - d
np
C29
dnp
C40
1uf -
dnp
R71
1k -
dnp
5V_S
W
+C
27
10uf
- dn
p
R70
10k
- dnp
VPP
_ON
12V
VPP
GE
NE
RA
TIO
N
PTC
41
IRQ
/TPM
CLK
2
RE
SET
3
PTP0
/TPM
1CH
24
PTP1
/TPM
1CH
35
PTP2
/TPM
2CH
06
PTF5
/TPM
2CH
17
PTE
0/Tx
D1
8
PTE
1/R
xD1
9
PTE
2/TP
M1C
H0
10
PTE
3/TP
M1C
H1
11
PTE
4/M
ISO
112
PTE
5/M
OSI
113
PTE
6/SP
SCK
114
PTE
7/SS
115
VD
D16
USB
DN
18
VSS
17
USB
DP
19
VU
SB33
20
PTG
0/K
BIP
021
PTG
1/K
BIP
122
PTC
5/R
xD2
44
PTC
3/Tx
D2
43
PTC
242
PTC
1/SD
A41
PTC
0/SC
L40
VSS
OSC
39
PTG
5/E
XTA
L38
PTG
4/X
TAL
37
BG
ND
/MS
36
PTG
3/K
BIP
735
PTG
2/K
BIP
634
PTD
2/K
BIP
2/A
CM
P033
VSS
AD
/VR
EFL
32
VD
DA
D/V
RE
FH31
PTD
1/A
DP9
/AC
MP-
30
PTD
0/A
DP8
/AC
MP+
29
PTB
5/K
BIP
5/A
DP5
28
PTB
4/K
BIP
4/A
DP4
27
PTB
3/SS
2/A
DP3
26
PTB
2/SP
SCK
2/A
DP2
25
PTB
1/M
OSI
2/A
DP1
24
PTB
0/M
ISO
2/A
DP0
23
U7
MC
9S08
JM60
44P
1N
VPP
_ON
OSB
DM
_RE
V2
OSB
DM
_RE
V1
OSB
DM
_RE
V0
O_E
XTA
L
O_X
TAL
OS_
BK
GD
TRE
SET_
IN
VTR
G_I
N
BR
D_I
D1
BR
D_I
D0
VTR
G_E
N
5VSW
_EN
TRE
SET_
OU
T
OS_
RE
SET
VPP
_EN
TBG
ND
_IN
TBG
ND
_OU
T
TBG
ND
_EN
TXD
RX
D
5VSW
_FA
ULT
VTR
G_F
AU
LT
USB
DN
USB
DP
R52
10k
5VU
SB
+C
3110
ufC
301u
f
5VU
SB C34
0.1u
f
+
C32
10uf
UG
ND
5
NC
4
USB
DP
3
USB
DN
2
UV
DD
1
J3 USB
1
R59
33-1
%
R60
33-1
%
L2 FER
RIT
E B
EA
D
USB
DP
USB
DN
C35
0.01
UF
C36
0.1U
F
5VU
SB
11
33
55
22
44
66
J2 OS_
DE
BU
GC
331n
f
R51
10K
5VU
SB
5VU
SBOS_
RE
SET
OS_
BK
GD
C37
100n
f
C38
100n
f
5VU
SB
R62
10k
R63
10k
V_T
RG
R55
1kR
561k
GN
D
5VU
SB
D6
STATUS-green
D7
TPWR-yellow
GN
D
GN
DG
ND
GN
DG
ND
GN
D
GN
DG
ND
GN
D
GN
D
GN
D
GN
DG
ND
GN
D
GN
D
GN
DG
ND
GN
DG
ND
GN
D
GN
D
GN
D
GN
D
GN
D
GN
D
GN
D
GN
DG
ND
GN
D
GN
D
GN
D
GN
D
GN
DG
ND
GN
D
GN
D
GN
D
GN
D
GN
DG
ND
GN
D
TP2
3
TST
PT
1 2
J4 CO
N2
R39
47
TBG
ND
1 1
2 2
33
D11
BA
T54C
TRG
_RST
12
JMP3
2PTS
- dn
p
12
J1 BO
OTL
OA
DE
R_E
NA
BLE
Q4
3904
KT9Z1_638UG User’s Guide Rev. 1.0 3/201414 Freescale Semiconductor
Board Layout
11 Board Layout
11.1 Assembly Layer Top
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 15
Board Layout
11.2 Assembly Layer Bottom
Note: This image is an exception to the standard top-view mode of representation used in this document. It has been flipped to show a bottom view.
KT9Z1_638UG User’s Guide Rev. 1.0 3/201416 Freescale Semiconductor
Board Layout
11.3 Top Layer Routing
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 17
Board Layout
11.4 Bottom Layer Routing
Note: This image is an exception to the standard top-view mode of representation used in this document. It has been flipped to show a bottom view.
KT9Z1_638UG User’s Guide Rev. 1.0 3/201418 Freescale Semiconductor
Bill of Material
12 Bill of Material
Table 2. Bill of Material (1)
Schematic Label Quantity Assy. Opt. Value Description Package
Integrated Circuits
U1 1 (2) Freescale MM912J638BM2EP QFN48LD-EP
U2 1 Freescale MC33901WEF (SO-8) SO-14
U3 1 SN74LVC1T45DBVR SOT-23-6
U4 1 MIC2026-1YM SOIC-8
U5 1 PDTC115T SOT-23
U6 1 TPS79933 TSOT-23−5
U7 1 (2) Freescale MC9S08JM60CQH QFP44
U8 1 DNP (3) TPS61041 SOT-23-5
U9, U10 2 SN74LVC1T45 SOT-23-6
Crystal Oscillators
X1, X2 2 4.0 MHz 4.0 MHz HC-49/SMT HC-49 SMD
Transistors
Q1 1 DNP (3) MMBT3904 SOT-23
Q2 1 DNP (3) MMBT3906 SOT-23
Q3, Q4 2 MMBT3904 SOT-23
Q5 1 MMBT3906 SOT-23
Diodes (including LEDs)
D1, D2 2 SS2P5-E3/84A SMP
D3, D4 2 HSMH-C170 D0805
D5 1 5.1 V BZX384-C5V1,115 SOD323
D6 1 STATUS GREEN D1206
D7 1 TPWR YELLOW D1206
D8 1 DNP (3) BAT54C, 215 SOT-23
D9 1 DNP (3) SS12 DO-214AC (SMA)
D10 1 DNP (3) BAT54C SOT-23
D11 1 BAT54C SOT-23
Capacitors
C1, C2, C7, C8, C14, C15, C19
7 2.2 nF 50V Capacitor C0805
C3 1 4.7 μF 100V Capacitor c2220
C4, C37, C38 3 100 nF 50V Capacitor C0805
C5, C6, C25, C26 4 18 pF 50V Capacitor C0805
C9, C10, C16, C29
4 DNP (3) — DNP Capacitor C0805
C11, C30 2 1.0 μF 50V Capacitor C0805
C12 1 470 nF 100V Capacitor C0805
C13 1 47 nF 100V Capacitor C0805
C17 1 4.7 μF 16V Capacitor C0805
C18 1 2.2 μF 100V Capacitor C1210
C20, C34, C36 3 0.1 μF 50V Capacitor C0805
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 19
Bill of Material
C21, C22, C24, C31, C32
5 10 μF 10V Capacitor C0805
C23 1 100 pF 50V Capacitor C0805
C27 1 DNP (3) 10 μF 10V Capacitor C0805
C28 1 220 pF 100V Capacitor C0805
C33 1 1.0 nF 50V Capacitor C0805
C35 1 0.01 μF 100V Capacitor C0805
C39, C40 2 DNP (3) 1.0 nF 50V Capacitor C0805
Inductors
L1 1 DNP (3) 10μH Choke Coil ELL6SH100M
L2 1 Ferrite Bead BLM21PG331SN1D L0805
Resistors
R1 1 3.3 k Resistor R0805
R2, R11, R21, R22, R54
5 0 Resistor R0805
R3, R7, R27 3 DNP (3) 1.8 k Resistor R0805
R4, R8, R15, R19, R28
5 100 k Resistor R0805
R5, R9, R23, R24, R29, R31, R32, R33, R36,
R44
10 2.2 k Resistor R0805
R6, R10, R13, R17, R30
5 DNP (3) 100 k Resistor R0805
R12, R53 2 1.8 k Resistor R0805
R14, R18 2 DNP (3) 2.2 k Resistor R0805
R16 1 3.6 k Resistor R0805
R20 1 DNP Resistor R0805
R25, R26 2 47 k Resistor R0805
R34 1 120 Resistor R0805
R35, R55, R56 3 1.0 k Resistor R0805
R37 1 4.7 k Resistor R0805
R38 1 10 k Resistor R0805
R39, R66 2 47 Resistor R0805
R40, R41, R42, R43, R45, R46, R47, R49, R50, R51, R52, R62, R63, R73, R74, R75, R76, R77,
R78, R79
20 10 k Resistor R0805
R48 1 1.0 M Resistor R0805
R57, R69 2 DNP (3) 4.7 k Resistor R0805
R58, R64, R65, R70
4 DNP (3) 10 k Resistor R0805
R59, R60 2 33 Resistor R0805
R67 1 DNP (3) 100 Resistor R0805
Table 2. Bill of Material (continued) (1)
Schematic Label Quantity Assy. Opt. Value Description Package
KT9Z1_638UG User’s Guide Rev. 1.0 3/201420 Freescale Semiconductor
Bill of Material
R68, R71 2 DNP (3) 1.0 k Resistor R0805
R72 1 DNP (3) 9.09 k Resistor R0805
RT1, RT2, RT5 3 10 k Thermistor R0805
RT3, RT4 2 DNP (3) 10 k Thermistor R0805
Switches, Connectors, Jumpers and Test Points
BP1, BP2, BP3 3 Tactile Switch DTSMW-69N DTSMW69
S1 1 SWITCH DIP-8
S2, S3 2 SWITCH DIP-4
CN1, CN3, CN7, CN9, CN14,
CN226 BANANA BLUE Banana connector 4.0 mm
CN2, CN4, CN8, CN10, CN15
5 BANANA YELLOW Banana connector 4.0 mm
CN5, CN12, CN16, CN17, CN18, CN23
6 BANANA RED Banana connector 4.0 mm
CN6, CN13 2 BANANA BLACK Banana connector 4.0 mm
CN11, CN19, CN20, CN21
4 BANANA GREEN Banana connector 4.0 mm
CON1 HEADER CON 6x2 2.54mm
J1 1 JUMPER CON 2 2.54mm (BOOTLOADER_ENABLE)
J2 1 JUMPER CON HE-10 6 MD (OS_DEBUG)
J3 1 USB Connector 5P MINI TYPE B RECPT SMT WITH POSTS
J4 1 JUMPER CON 2 2.54mm
J5 1 CONNECTOR DB9 Female
JM1 - JM9 9 JUMPER PCB
JMP1 1 JUMPER PTB4 CON 3 2.54mm
JMP2, JMP3 2 JUMPER 2PTS CON 2 2.54mm
JP1 1 JUMPER CON HE-10 6 MD (BDM_EXT)
TP1 - TP33 33 TSTPT 5000
Notes1. 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. Critical Components. For critical components, it is vital to use the manufacturer listed. 3. DNP = Do not populate
Table 2. Bill of Material (continued) (1)
Schematic Label Quantity Assy. Opt. Value Description Package
KT9Z1_638UG User’s Guide Rev. 1.0 3/2014Freescale Semiconductor, Inc. 21
References
13 ReferencesFollowing are URLs where you can obtain information on related Freescale products and application solutions:
13.1 SupportVisit www.freescale.com/support for a list of phone numbers within your region.
13.2 WarrantyVisit www.freescale.com/warranty for a list of phone numbers within your region.
Freescale.com Support Pages
Description URL
KIT9Z1J638EVM Tool Summary Page http://www.freescale.com/webapp/sps/site/prod_summary.jsp?code=KIT9Z1J638EVM
MM9Z1J638 Product Summary Page http://www.freescale.com/webapp/sps/site/prod_summary.jsp?code=MM9Z1_638
MM9Z1_638 Data Sheet http://www.freescale.com/files/analog/doc/data_sheet/MM9Z1_638D1.pdf
Analog Home Page Home Page http://www.freescale.com/analog
Battery Home Page Home Page http://www.freescale.com/battery
OSBDM Source Code Home Page http://www.pemicro.com/osbdm
KT9Z1_638UG User’s Guide Rev. 1.0 3/201422 Freescale Semiconductor
Revision History
14 Revision History
Revision Date Description of Changes
1.0 3/2014 • Initial Release
Document Number: KT9Z1_638UGRev. 1.0
3/2014
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