FRDM-KW40Z

Freescale Semiconductor, Inc. User’s Guide Document Number: FRDMKW40ZUG Rev. 2, 10/2015 FRDM-KW40Z Freescale Freedom Development Board User's Guide 1 Introduction This guide describes the hardware for the FRDM-KW40Z Freescale Freedom development board. The FRDM-KW40Z Freedom development board is a small, low-power, and cost-effective evaluation and development board for application prototyping and demonstration of the MKW40Z SoC family of devices. These evaluation boards offer easy-to-use mass-storage-device mode flash programmer, a virtual serial port, and standard programming and run-control capabilities. The MKW40Z SoC is an ultra-low-power, highly integrated single-chip device that enables Bluetooth Low Energy (BLE) and/or IEEE® Std. 802.15.4/RF connectivity for portable, ultra-low-power embedded systems. The MKW40Z SoC family integrates a radio transceiver operating in the 2.36 GHz to 2.48 GHz range (supporting a range of FSK/GFSK and O-QPSK modulations), ARM® Cortex®-M0+ CPU, 160 KB flash memory and 20 KB SRAM, BLE Link Layer hardware, 802.15.4 packet processor hardware, and peripherals optimized to meet the requirements of the target applications. 1.1 Audience This guide is intended for system designers. © 2015 Freescale Semiconductor, Inc. All rights reserved. 1. 1.1. 2. 2.1. 2.2. 2.3. 2.4. 3. 3.1. 3.2. 3.3. 4. 4.1. 4.2. 4.3. 5. 5.1. 5.2. 5.3. 5.4. 5.5. 5.6. 5.7. 5.8. 5.9. 6. Contents Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Audience . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Safety information . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 FCC guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 Regulatory approval for Canada (IC RSS 210) . . . . . 3 Electrostatic discharge considerations . . . . . . . . . . . . 3 Disposal instructions . . . . . . . . . . . . . . . . . . . . . . . . . 3 FRDM-KW40Z overview and description . . . . . . . . . 4 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 Board features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 Serial and Debug Adapter . . . . . . . . . . . . . . . . . . . . . 7 FRDM-KW40Z development board . . . . . . . . . . . . . 8 FRDM-KW40Z board overview . . . . . . . . . . . . . . . . 8 Functional description . . . . . . . . . . . . . . . . . . . . . . . 12 Schematic, board layout, and bill of materials . . . . . 24 PCB manufacturing specifications . . . . . . . . . . . . . . 33 Single PCB construction . . . . . . . . . . . . . . . . . . . . . 34 Panelization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Solder mask . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Silk screen . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Electrical PCB testing . . . . . . . . . . . . . . . . . . . . . . . 35 Packaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Hole specification/tool table . . . . . . . . . . . . . . . . . . . 35 File descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 Safety information 2 2.1 Safety information FCC guidelines This equipment is to be used by developers for evaluation purposes only, and must not be incorporated into any other device or system. This device must not be sold to the general public. Integrators are responsible for reevaluating the end product (including the transmitter) and obtaining a separate FCC authorization. The FCC approval of this device only covers the original configuration of this device (as supplied). Any modifications to this product (including changes shown in this guide) may violate the rules of the Federal Communications Commission and Industry Canada and make the operation of the product unlawful. 2.1.1 Labeling The FCC labels are located on the back of the board. 2.1.2 Operating conditions The device must comply with part 15 of the FCC rules. Operation is subject to these two conditions: • This device must not cause harmful interference. • This device must accept any interference received, including interference that can cause undesired operation. 2.1.3 Exposure limits The device must comply with FCC radiation exposure limits set forth for an uncontrolled environment. Install the antenna(s) used by the device to provide a separation distance of at least 8 inches (20 cm) from all persons. 2.1.4 Antenna restrictions An intentional radiator must be designed to ensure that no antenna (other than that furnished by the responsible party) is used with the device. Using a permanently attached antenna or an antenna that uses a unique coupling to the intentional radiator is considered sufficient to comply with the provisions of this Section. The manufacturer may design the unit so that a broken antenna can be replaced by the user, but using a standard antenna jack or electrical connector is prohibited. This requirement does not apply to carrier current devices or to devices operated under the provisions of Sections 15.211, 15.213, 15.217, 15.219, or 15.221 of the IEEE 802.15.4 Standard. This requirement does not apply to intentional radiators that must be professionally installed (such as perimeter protection systems and field disturbance sensors) or to other intentional radiators which must be measured at the installation site (in accordance with Section 15.31(d)). The installer is responsible for ensuring that a proper antenna is employed (to not exceed the limits in this Part). FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 2 Freescale Semiconductor, Inc. Safety information 2.2 Regulatory approval for Canada (IC RSS 210) This equipment complies with Industry Canada license-exempt RSS standard(s). Operation is subject to these two conditions: 1. This board must not cause interference. 2. This board must accept any interference, including interference that may cause undesired operation of the device. 2.2.1 26 PART 5—Appendix Le présent appareil est conforme aux CNR d'Industrie Canada applicables aux appareils radio exempts de licence. L'exploitation est autorisée aux deux conditions suivantes: 1. l'appareil ne doit pas produire de brouillage, et 2. l'utilisateur de l'appareil doit accepter tout brouillage radioélectrique subi, même si le brouillage est susceptible d'en compromettre le fonctionnement. 2.3 Electrostatic discharge considerations Although the damage from electrostatic discharge (ESD) is much less common on these devices when compared to the early CMOS circuits, use standard handling precautions to avoid exposure to static discharge. Qualification tests are performed to ensure that these devices can withstand exposure to reasonable levels of static without suffering any permanent damage. All ESD testing must conform to the JESD22 Stress Test Qualification for Commercial Grade Integrated Circuits. During the device qualification, ESD stresses were performed for the Human Body Model (HBM), the Machine Model (MM), and the Charge Device Model (CDM). All latch-up test testing must conform to the JESD78 IC Latch-Up Test. When operating or handling the development boards or components, Freescale strongly recommends using at least grounding wrist straps, plus any (or all) of these ESD dissipation methods: • Flexible fabric, solid fixed size, or disposable ESD wrist straps. • Static control workstations, static control monitors and table or floor static control systems. • Static control packaging and transportation materials and environmental systems. 2.4 Disposal instructions This product may be subject to special disposal requirements. For product disposal instructions, see freescale.com/productdisposal. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 3 FRDM-KW40Z overview and description 3 3.1 FRDM-KW40Z overview and description Introduction The FRDM-KW40Z development board is an evaluation environment supporting Freescale MKW40Z SoC transceiver. The MKW40Z SoC integrates a radio transceiver operating in the 2.36 GHz to 2.48 GHz range (supporting a range of FSK/GFSK and O-QPSK modulations) and an ARM Cortex-M0+ MCU into a single package. Freescale supports the MKW40Z SOC with tools and software that include hardware evaluation and development boards, software development IDE, applications, drivers, custom PHY usable with IEEE Std. 802.15.4 compatible MAC, BLE Link Layer, and enables the usage of the Bluetooth Low Energy protocol in the MBAN frequency range for proprietary applications. The FRDM-KW40Z development board consists of the MKW40Z device with 32 MHz reference oscillator crystal, RF circuitry (including antenna), 2-Mbit external serial flash, and supporting circuitry in the popular Freedom form. The board is a standalone PCB and supports application development with Freescale IEEE Std. 802.15.4 protocol stacks. 3.2 3.2.1 Board features FRDM-KW40Z board The FRDM-KW40Z development board is based on Freescale Freedom development platform. It is the most diverse reference design containing the MKW40Z device and all necessary I/O connections for use as a standalone board, or connected to an application. You can also connect it to the Freedom development platform. Figure 1 shows the FRDM-KW40Z development board. A similar board (not shown) uses the MKW40Z device. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 4 Freescale Semiconductor, Inc. FRDM-KW40Z overview and description Figure 1. FRDM-KW40Z Freedom development board The FRDM-KW40Z development board has these features: • Freescale ultra-low-power MKW40Z SoC BLE/IEEE Std. 802.15.4 platform. • IEEE Std. 802.15.4, 2006-compliant transceiver supporting 250 kbps O-QPSK data in 5.0 MHz channels, and full spread-spectrum encoding and decoding. • Fully compliant Bluetooth v4.1 Low Energy (BLE). • IEEE 802.15.4-compliant wireless node. • Reference design area with small-footprint, low-cost RF node. — Differential input/output port used with external balun for single-port operation. — Low count of external components. — Programmable output power from -20 dBm to +5 dBm at the SMA connector, no harmonic trap, with DC/DC Bypass and Buck modes of operation. — Receiver sensitivity is -102 dBm, typical (@1 % PER for 20-byte payload packet) for 802.15.4 applications, at the SMA connector. — Receiver sensitivity is -91 dBm (for BLE applications). • Integrated PCB inverted F-type antenna and SMA RF port. • Selectable power sources. • DC-DC converter with Buck, Boost, and Bypass operation modes. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 5 FRDM-KW40Z overview and description • • • • • • • • • • • 32 MHz reference oscillator. 32 kHz reference oscillator. 2.4 GHz frequency operation (ISM and MBAN). External serial flash memory for Over-the-Air Programming (OTAP) support. Integrated Open-Standard Serial and Debug Adapter (OpenSDA). Cortex 10-pin (0.05) SWD debug port for target MCU. Cortex 10-pin (0.05) JTAG port for OpenSDA updates. Four red LED indicators. One blue LED indicator. Two push-button switches. Two TSI buttons. This figure shows the main board features and Input/Output headers for the Freescale FRDM-KW40Z board: Figure 2. FRDM-KW40Z component placement FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 6 Freescale Semiconductor, Inc. FRDM-KW40Z overview and description 3.3 Serial and Debug Adapter The FRDM-KW40Z development board includes OpenSDA v2.1-a serial and debug adapter circuit that includes an open-source hardware design, an open-source bootloader, and debug interface software. It bridges serial and debug communications between a USB host and an embedded target processor as shown in Figure 3. The hardware circuit is based on a Freescale Kinetis K20 family microcontroller (MCU) with 128 KB of embedded flash and an integrated USB controller. OpenSDAv2.1 comes preloaded with the CMSIS-DAP bootloader - an open-source mass storage device (MSD) bootloader and the CMSIS-DAP Interface firmware (aka mbed interface), which provides a MSD flash programming interface, a virtual serial port interface, and a CMSIS-DAP debug protocol interface. For more information on the OpenSDAv2.1 software, see mbed.org and https://github.com/mbedmicro/CMSIS-DAP. Figure 3. OpenSDAv2.1 high-level block diagram OpenSDAv2.1 is managed by a Kinetis K20 MCU built on the ARM Cortex-M4 core. The OpenSDAv2.1 circuit includes a status LED (D2) and a pushbutton (SW6). The pushbutton asserts the Reset signal to the MKW40Z target MCU. It can also be used to place the OpenSDAv2.1 circuit into bootloader mode. UART and GPIO signals provide an interface to either the SWD debug port or the K20. The OpenSDAv2.1 circuit receives power when the USB connector J6 is plugged into a USB host. 3.3.1 Virtual serial port A serial port connection is available between the OpenSDAv2.1 MCU and pins PTC6 and PTC7 of the MKW40Z. NOTE To enable the Virtual COM, Debug, and MSD features, mbed drivers must be installed. Download the drivers at https://developer.mbed.org/handbook/Windows-serial-configuration. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 7 FRDM-KW40Z development board 4 4.1 FRDM-KW40Z development board FRDM-KW40Z board overview The FRDM-KW40Z board is an evaluation board based on Freescale MKW40Z transceiver, and it provides a platform to evaluate the MKW40Z SoC device and to develop software and applications. The core device is accompanied by a 32 MHz reference oscillator crystal, RF circuitry (including antenna), and supporting circuitry. The FRDM-KW40Z board is intended as the core PCB for MKW40Z device evaluation and application development, and can be used in the following modes: • Simple standalone evaluation platform. • Daughter card for other Freedom development platform boards. • Mother card for application-specific daughter cards, such as a shield card. 4.1.1 PCB features The FRDM-KW40Z board has these features: • The Freescale Freedom development board form factor. • Four-layer, metal, 0.062 inches thick FR4 board. • LGA footprint and power supply (DC-DC converter). • DC-DC converter with Buck, Boost, and Bypass operation modes. • Printed-metal F-Antenna or SMA connector (for conducted measurements). • 32 MHz reference oscillator crystal. • 32.768 kHz crystal provided for optional timing oscillator. • Standard Freedom daughter card mounting interface (shield). • External serial flash memory for OTAP support. • Combo sensor—six-axis sensor with integrated linear accelerometer and magnetometer. 4.1.2 Form factor Figure 4 shows the FRDM-KW40Z board with the location of the I/O headers. This list provides the details: • J1, J2, J3, and J4: — Headers have standard 0.1 in/2.54 mm pin spacing. — J2 is 20-pin. — J1 and J3 are 16-pin. — J4 is 12-pin. — All pin headers mounted on the top side of the FRDM-KW40Z board are intended for plugging into matching receptacles on the Freedom platform development board. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 8 Freescale Semiconductor, Inc. FRDM-KW40Z development board • J16, J17, J18, and J22: — Headers have standard 0.787 in./2.00 mm pin spacing. — J18 is a 2  2 pin. — J16, J17, and J22 are 2  3 pins. — Pin headers mounted on the top side of the FRDM-KW40Z are intended to select between power configurations, Bypass, Buck, and Boost. Figure 4. FRDM-KW40Z board with I/O headers locations FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 9 FRDM-KW40Z development board This figure shows the footprint of the FRDM-KW40Z board with the board dimensions: Figure 5. FRDM-KW40Z board dimensions 4.1.3 Board level specifications Table 1. FRDM-KW40Z board specifications Parameter Min Typ Max Units Notes/Conditions Size (PCB: X, Y) — — 81.2  53.3 3.20  2.10 mm inches — Layer build (PCB) — 1.57 0.062 — Dielectric material (PCB) — — — — FR4 — — — mA See the data sheet Operating temperature (see note) -40 +25 +70 °C Operating temperature is limited to +70 °C due to switches. Basic circuit handles a maximum temperature of +85 °C. Storage temperature -30 +25 +70 °C — 2480 MHz 2480 MHz General mm Four-layer inches Power Current consumption Temperature RF 802.15.4 frequency range 2405 RF BLE frequency range 2400 — — All 16 channels in the 2450 MHz band All 40 channels in the 2450 MHz band FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 10 Freescale Semiconductor, Inc. FRDM-KW40Z development board Table 1. FRDM-KW40Z board specifications (continued) Parameter RF ISM and MBAN frequency range Min 2360 Typ — Max Units 2483 MHz Notes/Conditions — RF receiver Saturation (maximum input level) — +0 — dBm See the data sheet Sensitivity for 1 % packet error rate (PER) (+25 °C) 802.15.4 — -102 — dBm See the data sheet Sensitivity for 1 % packet error rate (PER) (+25 °C) BLE — -91 — dBm See the data sheet RF power output -20 — +5 dBm Programmable in steps. At the antenna feed with no harmonic trap.1 2nd harmonic — 50 40 dBm See the data sheet 3rd harmonic — 50 40 dBm See the data sheet FCC — — — — Product is approved according to the FCC part 15 Standard. CE (ETSI) — — — — Product is approved according to the EN 300 328 V1.7.1 (2006-10) Standard. CE (EMC) — — — — Product is approved according to the EN 301 489-1 V1.6.1 (2005-09) and EN 301 489-17 V1.2.1 (2002-08) s=Standards. — — — — Product is approved according to the IEC 60950-1 and EN 60950-1, First Edition Standards. RoHS — — — — Product complies with the EU Directive 2002/95/EC of 27 January 2003. WEEE — — — — Product complies with the EU Directive 2002/95/EC of 27 January 2003. RF transmitter Regulatory approval Safety UL Environment 1 Harmonic trap will add 1-2 dB of loss FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 11 FRDM-KW40Z development board 4.2 Functional description The FRDM-KW40Z board is built around Freescale MKW40Z SoC in a 48-pin LGA package. It features an IEEE Std. 802.15.4 and BLE 2.4 GHz radio frequency transceiver and a Kinetis family ultra-low-power, mixed-signal ARM Cortex-M0+ MCU in a single package. This board is intended as a simple evaluation platform and as a building block for application development. The four-layer board provides the MKW40Z SoC with its required RF circuitry, 32 MHz reference oscillator crystal, and power supply with a DC-DC converter including Bypass, Buck, and Boost modes. The layout for this base-level functionality can be used as a reference layout for your target board. This figure shows a simple functional block diagram: Figure 6. FRDM-KW40Z board functional block diagram 4.2.1 RF performance and considerations The FRDM-KW40Z board’s integrated transceiver includes a 1 mW nominal output power PA with internal Voltage-Controlled Oscillator (VCO), integrated transmit/receive switch, on-board power supply regulation, and full spread-spectrum encoding and decoding. The main specifications of the MKW40Z SoC are: • Nominal output power is set to 0 dBm. • Programmable output power ranges from -20 dBm to +5 dBm at the SMA (no harmonic trap). • Typical sensitivity is -102 dBm (@1 % PER for 25 °C) at the SMA (802.15.4). • Typical sensitivity is -91 dBm (@1 % PER for 25 °C) at the SMA (BLE). • Frequency ranges from 2360 to 2480 MHz. • Differential bidirectional RF input/output port with integrated transmit/receive switch. • “F” printed-metal antenna for a small-footprint, low-cost design. • Minimum number of RF marching components and external 50:100 balun. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 12 Freescale Semiconductor, Inc. FRDM-KW40Z development board The external 50 (balanced):100 (unbalanced) balun connects a single-ended 50-Ohm port to the differential RF port of the MKW40Z SoC transceiver. The layout has a provision for out-of-band signal suppression (components L4 and C33), if required. The following figure shows the typical topology of the RF circuitry. The RF connector J5 is provided for conducted measurement purposes, and it is used as DNP. Figure 7. FRDM-KW40Z board’s RF circuitry 4.2.2 Clocks The FRDM-KW40Z board provides two clocks: • 32 MHz Reference Oscillator—Figure 8 shows the 32 MHz external crystal Y1. This mounted crystal meets the specifications outlined in Reference Oscillator Crystal Requirements for the MC1320x, MC1321x, MC1322x, and MC1323x IEEE 802.15.4 Devices (document AN3251). The IEEE Std. 802.15.4 requires the frequency to be accurate to less than 40 ppm. — Capacitors C41 and C42 provide the bulk of the crystal load capacitance. At 25 °C, the frequency must be accurate to 10 ppm (or less) to enable temperature variation. — To measure the 32 MHz oscillator frequency, program the CLKOUT (PTB0) signal to provide buffered output clock signal. • Optional 32.768 kHz Crystal Oscillator—a secondary 32.768 kHz crystal Y2 is provided (see Figure 9). Use this oscillator for a low-power accurate time base. — The module provides the Y2 crystal and its load capacitors C46 and C47. — Load capacitors C46 and C47 provide the entire crystal load capacitance; there is no on-board trim capacitance. — The 32 kHz oscillator components are supplied, but not enabled. The 0 Ohm resistors R71 and R76 disable the 32 kHz oscillator. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 13 FRDM-KW40Z development board Figure 8. FRDM-KW40Z board’s 32 MHz reference oscillator circuit Figure 9. FRDM-KW40Z board’s optional 32.768 kHz oscillator circuit FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 14 Freescale Semiconductor, Inc. FRDM-KW40Z development board 4.2.3 Power management There are several different ways to power and measure current on the FRDM-KW40Z board. The FRDM-KW40Z power-management circuit is shown in this figure: Figure 10. FRDM-KW40Z board’s power-management circuit Power the FRDM-KW40Z in several ways: • Power the board through the micro USB type B connector (J6), which provides P5V_USB to LDO 3V3 (U17). • Power the board through the Freedom development board headers, which provide either P3.3V or P5-9V_VIN on header J3 pin-16 to LDO 3V3 (U17). • Power the board from an external battery (Coincell – BT500). • Power the board from an external DC supply in these ways: — Connect an adapter that can supply 1.8 to 3.6 VDC to J19 pins 1 using the selector J23 pin 2-3. — Connect an unregulated external supply (of up to 5.5 VDC) to J19 pin 1 and the GND pin to use the onboard 3.3 V LDO regulator (using the selector J23 pin 1-2). The 2-pin 12 headers J8, J20, and J21 can supply current to various board components and measure the current (if desired). Green LED marked as LED6 is available as a power indicator. Power headers can supply either the LED, MCU, or peripheral circuits. Measure the current by inserting a current meter in place of a designated jumper. Connection configurations are described in Table 2. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 15 FRDM-KW40Z development board Table 2. Power distribution headers Supply designation Header pins P3V3_BRD J8 1-2 Supply voltage to board peripherals • Normally jumpered • Jumper used to enable sensor, external flash memory, and buzzer on board • Leave open for lowest power • Usage—measure the current or breakout for current consumption P3V3_LED_PWR J20 1-2 Supply voltage to power LED • Normally jumpered • Jumper used to enable green power LED on board • Leave open for lowest power • Usage—measure the LED current V_MCU J21 1-2 Supply voltage to MKW40Z SoC • Normally jumpered • Powers the MKW40Z SoC and transceiver • Usage—measure or supply the MCU and radio current Description The DC-DC power configuration headers provide the DC-DC modes, and can be easily modified for the desired mode. The connection configurations are described in Table 3: Table 3. DC-DC power distribution headers DC-DC mode Reference designator and header pins Description Bypass J18 1-2 J16 1-2 J17 3-4 J22 1-3, 2-4 Supply voltage to power Bypass mode • Normally jumpered as primary mode • Power level range 1.8 V–3.6 V Buck J18 2-4 J16 5-6 J17 3-4 J22 3-5 Supply voltage to power Buck mode • Alternative configuration, related to Coin cell option • Power level range 1.8 V–4.2 V • DC-DC converter requires at least 2.1 V to start; the supply can drop to 1.8 V after the DC-DC converter settles Buck Auto-Start J18 2-4 J16 3-4 J17 3-4 J22 3-5 Supply voltage to power Buck Auto-Start mode • Alternative configuration, related to Coin cell option • Power level range 1.8 V–4.2 V • DC-DC converter requires at least 2.1 V to start; the supply can drop to 1.8 V after the DC-DC converter settles Boost J18 2-4 J16 3-4 J17 1-2, 5-6 J22 3-5 Supply voltage to power Boost mode • Alternative configuration, related to single battery option • Power level range 0.9 V–1.8 V NOTE When configuring the Buck mode, SWD connector does not support J-Link Lite. J-Link BASE is required. It is due to the 1.8 V operating mode. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 16 Freescale Semiconductor, Inc. FRDM-KW40Z development board Figure 11. Bypass headers Figure 12. Buck headers Figure 13. Buck Auto-Start headers Figure 14. Boost headers FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 17 FRDM-KW40Z development board 4.2.4 FRDM-KW40Z board peripheral functions The FRDM-KW40Z development board includes the Freedom development board headers to interface with the general-purpose functions, and to assist in the implementation of target applications. The FRDM-KW40Z board has alternate port functions routed to those interface headers where you can use the off-board Freedom development platform peripherals. 4.2.4.1 Serial flash memory (SPI interface) Component U4 is the AT45DB021E 2-Mbit (256 KB) serial flash memory with SPI interface. Use the memory for Over-the-Air Programming (OTAP) for storing the non-volatile system data or parameters. The figure below shows the memory circuit. • Memory power supply is P3V3_BRD. • Discrete pullup resistors for the SPI port are included. • You can share the SPI with other peripherals using the J2 SPI connectors. The normal SPI_SS and the second chip-select must not be active at the same time. • The SPI Write Protect and Reset have a discrete pullup resistor. Figure 15. AT45DB021E 2-Mbit (256 KB) serial flash memory circuit FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 18 Freescale Semiconductor, Inc. FRDM-KW40Z development board 4.2.4.2 Combo sensor (I2C interface) Component U9 is Freescale FXOS8700CQ sensor, a six-axis sensor with integrated linear accelerometer and magnetometer, very low power consumption, and selectable I2C. Figure 16 shows the sensor circuit. • The sensor power supply is P3V3_BRD. • Discrete pullup resistors for the I2C port are provided. • There is one interruption signal. • The I2C can be shared with other peripherals through the J4 pin 10 and pin 12 (I2C1 connectors). Figure 16. FXOS8700CQ combo sensor circuit FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 19 FRDM-KW40Z development board 4.2.4.3 Buzzer Component BZ500 is is a piezoelectric transducer (MPN: AST1109MLTRQ). Use the buzzer for sound applications. Figure 17 shows the buzzer circuit. PWM signal is required to enable the buzzer. • The buzzer power supply is P3V3_BRD. • The resonant frequency is 4.0 kHz. • Buzzer is driven by Q1 and MCU output PTB3 signal. • The driven signal can be shared with other peripherals through the J1 pin 16. Figure 17. Buzzer circuit 4.2.4.4 Potentiometer (ADC interface) Use the 5 k potentiometer (R67) for ADC verification and applications. Figure 18 shows the potentiometer circuit. • The POT power supply can be either the P3V3 or V_BATT for the input source. • A single-turn potentiometer is provided. • Signal is routed through ADC0_SE. • The ADC trace can be shared with other peripherals through the J4 pin 3. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 20 Freescale Semiconductor, Inc. FRDM-KW40Z development board Figure 18. Potentiometer circuit NOTE To measure the POT value, program the ADC in differential mode. The V_BATT is taken as the differential input. 4.2.4.5 IR transmitter (CMT interface) An infrared transmitter or blaster is provided to control the IR. Figure 19 shows the IR circuit. • The IR power supply is P3V3_LED. • The IR has a range of approximately 10 meters. • The current draw is approximately 100 mA when active. • When using the blaster as an application, assure the proper orientation. Figure 19. IR transmitter circuit FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 21 FRDM-KW40Z development board 4.2.4.6 Interface connectors J1, J2, J3, and J4 The four connectors (J1, J2, J3, and J4) are 100-mil pin headers mounted on the front (component side), supporting the standard Freedom connector. • P3V3, P5V_USB, and P5-9V_VIN provide the supply voltage for the headers connector. — The I/O power supply for the FRDM-KW40Z board and the power supply for the MKW40Z SoC must use the same voltage to avoid potential damage. The pin definitions for the headers are shown in Table 4 and Table 5, respectively. Table 4. J1 and J2 connectors Header pin no. J1 Description MKW40Z pin name Header pin no. J2 Description MKW40Z pin name 1 NC NC 1 NC NC 2 UART0_RX_TGTMCU PTC6 (D0/Rx/int) 2 SWD_DIO_TGTMCU PTA0 (D8/Int) 3 NC NC 3 NC NC 4 UART0_TX_TGTMCU PTC7 (D1/Tx/int) 4 KW40_SWD_CLK PTA1 (D9/Int) 5 NC NC 5 NC NC 6 ELEC_IN1 PTA16 (D2/int) 6 SPI_SS PTC19 (D10/SPI_SS) 7 NC NC 7 NC NC 8 ELEC_IN2 PTA17 (D3/PWM/int) 8 SPI_SIN PTC18 (D11/MOSI) 9 NC NC 9 NC NC 10 SW4 PTA19 (D4/int) 10 SPI_SOUT PTC17 (D12/MISO) 11 NC NC 11 NC NC 12 SW3 PTA18 (D5/PWM/int) 12 SPI_CLK PTC16 (D13/SCK) 13 NC NC 13 NC NC 14 INT1_COMBO PTB2 (D6/PWM/Int) 14 GND VSS (GND) board ground 15 NC NC 15 NC NC 16 BUZZER PTB3 (D7/CMP/int) 16 P3V3 VREF — — — 17 NC NC — — — 18 PTC1 PTC1 (D14/Ana/Int) — — — 19 NC NC — — — 20 PTC0 PTC0 (D15/Ana/Int) FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 22 Freescale Semiconductor, Inc. FRDM-KW40Z development board Table 5. J3 and J4 connectors Header pin no. J3 Description MKW40Z pin name Header pin no. J4 Description MKW40Z pin name 1 NC NC 1 ADC_SE0/BATTERY_ MONITORING ADC0_SE0 2 PTC4 EXTRG_IN 2 PTB17 PTB17/XTAL32k/I2C_SDA 3 NC NC 3 ADC0_SE1/POT ADC0_DM0/CMPO_IN1 4 P3V3 IO_REF 4 PTB16 PTB16/EXTAL32k/I2C_SCL 5 NC NC 5 NC NC 6 RST_TGTMCU_b RESET 6 CMT PTB1/TSI_CH15/CMT_IRO 7 NC NC 7 NC NC 8 P3V3 V_OUT 8 PTC5 PTC5/TSI_CH1 9 NC NC 9 COM PTB0/CLKOUT 10 P5V_USB 5V 10 I2C1_SDA PTC3/I2C1_SDA 11 NC NC 11 PTB18 PTB18/CMP0_IN2 12 GND GND 12 I2C1_SCL PTC2/I2C1_SCL 13 NC NC — — — 14 GND GND — — — 15 NC NC — — — 16 P5-9V_VIN Unregulated Voltage — — — FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 23 A B C D 2 L3 10uH 1 DFLS130L-7 D6 GND 3 3003 BT500 2 1 10uF C43 P3V3_BATT DFLS130L-7 P5-9V_VIN_VR D3 P5-9V_VIN P5V_SDA_PSW COIN CELL HOLDER DFLS130L-7 XTAL_32M EXTAL_32M PSWITCH J27 HDR_2X1 TP530 D8 C C531 1uF VDCDC_IN J_VDD_1P8F V_MCU 1 V_BATT C25 10uF J19 VIN U17 HDR 1X2 TH 3 DCDC_CFG DCDC_LP DCDC_LN EXTAL_32M XTAL_32M 4 1 2 A C D7 R75 0 DFLS130L-7 A V_BATT TP30 C 1 L6 2 10nH (1.45-3.6V) VDD_1P45F C54 10uF DNP J18 HDR 2X2 TP534 J_VDD_1P8F 4 2 P3V3 34 33 24 25 J8 HDR_2X1 HDR_2X1 J20 R78 C525 12PF R83 R84 100 Ohm controlled impedance from DUT to balun. TP533 TP544 ADC0_SE0/BATTERY_MONITORING V_MCU P3V3_LED TP536 P3V3_LED_PWR TP518 POWER MANAGMENT P3V3_BRD 0 DNP 0 DNP PTC0 PTC1 I2C1_SCL I2C1_SDA PTC4 PTC5 UART0_RX_TGTMCU UART0_TX_TGTMCU SPI_CLK SPI_SOUT SPI_SIN SPI_SS R56 R52 UART FlowControl C528 0.1UF {4,5} {4,5} R70 R69 0 C42 0.6PF 0 1 C44 11pF 2 32MHz XTAL EXTAL_32M P3V3 HDR 2X5 J9 32MHZ Y1 1 3 5 7 9 2 4 6 8 10 3 4 1 5 HARMONIC TRAP C41 11pF XTAL_32M 2 1 Jumper is shorted by a cut-trace on bottom layer. Cutting the trace will effectively isolate the on-board MCU from the OpenSDA debug interface. J12 HDR 1X2 DNP C33 1.8pF DNP L4 2.4nH DNP CAD NOTE: Embed pads into 50 Ohm line. 3-4 3-4 5-6 1-2 RF_50 KW40_SWD_CLK SWD_DIO_TGTMCU pg(4,5) pg(3,4,5) FIUO: ___ Thursday, July 30, 2015 Sheet 3 ANT1 F_Antenna of 5 Rev C CAD NOTE: Open Solder Mask Bottom below F-Antenna on "feedpoint" via RF RF_ANT PUBI: X SCH-28379 | PDF: SPF-28379 Document Number Date: KW40x MCU X-FRDM-KW40Z FCP: ___ C40 10PF C34 10PF DNP RF_SMA Place both capacitor sharing pin 1 pg(3,4) pg(3) Size C Page Title: ICAP Classification: Drawing Title: RST_TGTMCU_b SWD_CLK_TGTMCU DNP CAD NOTE: SMA - F-Antenna: 1 3-5 J5 SMA 3-5 1-2 5-6 3-5 1-3 2-4 3-4 3-4 3-4 50 ohm controlled impedence line from Balun to SMA and F_Antenna SHORTING HEADER ON BOTTOM LAYER 6 2 4 3 Z1 50/100 OHMS 2-4 UART0_CTS_TGTMCU {4} UART0_RTS_TGTMCU {4} 2-4 Boost (0.9V - 1.8V) - Single battery 2-4 1-2 Boost Auto Mode (1.8V - 4.2V) Buck (1.8V - 4.2V) - Coin Cell 1 PWR_CFG PSW_CFG DCDC_CFG REG_CFG J16 J18 J17 J22 Power Configuration Bypass (1.8V - 3.6V) SWD CONNECTOR RF_P RF_N ADC0_SE0/BATTERY_MONITORING ADC0_SE1/POT 0 0 C526 12PF R508 10.0K P3V3 P3V3 UART0_RX UART0_TX R509 10.0K C527 12PF BATTERY_MONITOTING 0 J21 HDR_2X1 0 SH503 0.1UF C530 Place caps close to DUT 0.1UF C529 MKW40Z160 MCU MKW40Z160VHT4 RF_P RF_N ADC0_DP0/CMP0_IN0 ADC0_DM0/CMP0_IN1 36 37 38 39 40 41 42 43 45 46 47 48 VDD_1P45F 0.1UF C524 J_VDD_1P8F PTC0/ANT_A/I2C0_SCL/UART0_CTS/TPM0_CH1 PTC1/ANT_B/I2C0_SDA/UART0_RTS/TPM0_CH2/BLE_ACTIVE PTC2/TSI0_CH14/TX_SWITCH/I2C1_SCL/UART0_RX/CMT_IRO/DTM_RX PTC3/TSI0_CH15/RX_SWITCH/I2C1_SDA/UART0_TX/DTM_TX PTC4/TSI0_CH0/EXTRG_IN/UART0_CTS/TPM1_CH0 PTC5/TSI0_CH1/LPTMR0_ALT2/UART0_RTS/TPM1_CH1 PTC6/TSI0_CH2/I2C1_SCL/UART0_RX/TPM2_CH0 PTC7/TSI0_CH3/SPI0_PCS2/I2C1_SDA/UART0_TX/TPM2_CH1 PTC16/TSI0_CH4/SPI0_SCK/I2C0_SDA/UART0_RTS/TPM0_CH3 PTC17/TSI0_CH5/SPI0_SOUT/UART0_RX/DTM_RX PTC18/TSI0_CH6/SPI0_SIN/UART0_TX/DTM_TX PTC19/TSI0_CH7/SPI0_PCS0/I2C0_SCL/UART0_CTS/BLE_ACTIVE (1.71-3.6V) VDD_1P8 C45 10uF VDD_1P45 PWR_CFG 3 1 2 4 6 VDD_1P45F HDR 2X3 J22 * For External PS, If 3.6V - 20V shunt J23 1-2, else if PS 1.8 - 3.6V shunt J23 2-3. DFLS130L-7 D9 J23 HDR_1X3 C27 10uF P3V3_VREG NCP1117ST33T3G TAB VOUT 2 PTB2/ADC0_SE3/CMP0_IN3/TPM1_CH0 PTB3/ADC0_SE2/CMP0_IN4/CLKOUT/TPM1_CH1/RTC_CLKOUT/ERCLK32K PTB16/EXTAL32K/I2C1_SCL/TPM2_CH0 PTB17/XTAL32K/I2C1_SDA/TPM2_CH1 PTB18/DAC0_OUT/ADC0_SE4/CMP0_IN2/I2C1_SCL/TPM_CLKIN0/TPM0_CH0/NMI 1 3 5 REG_CFG L5 2 VDD_1P8F 100nH C55 C39 10uF 1uF PTB0/I2C0_SCL/CMP0_OUT/TPM0_CH1/CLKOUT PTB1/ADC0_SE1/CMP0_IN5/I2C0_SDA/LPTMR0_ALT1/TPM0_CH2/CMT_IRO PTA0/SWD_DIO/TSI0_CH8/SPI0_PCS1/TPM1_CH0 PTA1/SW D_CLK/TSI0_CH9/TPM1_CH1 PTA2/RESET/TMP0_CH3 PTA16/TSI0_CH10/SPI1_SOUT/TPM0_CH0 PTA17/TSI0_CH11/SPI1_SIN/TPM_CLKIN1 PTA18/TSI0_CH12/SPI1_SCK/TPM2_CH0 PTA19/TSI0_CH13/SPI1_PCS0/TPM2_CH1 PSWITCH U18 R85 102K EXTERNAL PS R73 0 DNP DFLS130L-7 A 9 30 29 DCDC_LP 0 16 17 18 19 21 22 23 1 2 3 4 5 6 7 8 DCDC_CFG J33 HDR_2X1 TP29 2 11 12 R68 SW5 HDR 2X3 2 4 6 TL1015AF160QG 1 1 3 5 J16 6 HDR 2X3 5 0 DCDC_LP J17 2 4 PSW_CFG R72 COM CMT INT1_COMBO BUZZER PTB16/XTAL_32K PTB17/EXTAL_32K PTB18 Place ind close to DUT D5 P5V_USB V_BATT {3,4} SWD_DIO_TGTMCU {3} KW40_SWD_CLK {3,4,5} RST_TGTMCU_b ELEC_IN1 ELEC_IN2 SW4 SW3 A C A C A C 1 3 GND 1 2 1 2 1 10 VDCDC_IN 31 VDD_XTAL 20 VDD_0 44 VDD_1/VDD 28 VDDA 27 VREFH 35 VDD_RF1 14 VDD_1P8 32 VDD_RF2 15 VDD_1P45 GND1 GND2 GND3 GND4 GND5 GND6 GND7 GND8 GND9 GND10 GND11 GND12 GND13 GND14 GND15 GND16 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 VSSA 26 DCDC_GND 13 DCDC_CFG 1 2 3 1 2 1 2 1 2 DCDC_CFG TP519 2 TP523 3 TP506 4 TP505 24 1 A B C D 4.3 2 5 FRDM-KW40Z development board Schematic, board layout, and bill of materials Figure 20. FRDM-KW40Z board schematic rev. C (sheet 1 of 3) FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. SHELL5 1 2 3 4 5 VBUS DD+ ID GND 1 330 OHM L2 2 0 R36 DNP UART1_CTS_TGTMCU_R 6 8 10 5 7 9 SDA_JTAG_TMS SDA_JTAG_TCLK SDA_JTAG_TDO SDA_JTAG_TDI SDA_RST R63 10.0K P3V3_SDA SDA_SWD_OE SDA_SWD_EN HDR 2X5 2 4 J11 1 3 5 {For enablement purposes only} DNP 0 R50 UART1_RTS_TGTMCU_R 0.1UF C31 P3V3_SDA TP4 TP513 P5V0_SDA_USB_CONN_VBUS OpenSDA INTERFACE JTAG CONNECTOR 10 SHELL4 8 SHELL3 SHELL2 7 SHELL1 6 USB_MICRO_AB TP3 1 330 OHM L1 U6 U1 P5V_SDA P3V3_SDA R25 R21 2 PU/PD LOGIC: SERIAL INTERFACE IS ALWAYS RESET WHEN USB PORT IS DISCONNECTED R47 10.0K SDA_RST R46 4.7K P5V_SDA U2 1 J6 1 2 1 2 9 TP524 TP520 TC_XTAL_TP C506 2.2uF P5V_SDA P3V3_SDA 0.1UF C504 SDA_VOUT33 C509 1uF 33 SDA_USB_DN 33 SDA_USB_DP 10uF C3 C502 10uF MK20DX128VFM5 EPAD VSS1 RESET EXTAL32 XTAL32 VREGIN VOUT33 USB0_DM USB0_DP VBAT VSSA VDDA VDD1 20 ADC0_SE8/TSI0_CH0/PTB0/I2C0_SCL/FTM1_CH0/FTM1_QD_PHA/LLWU_P5 21 ADC0_SE9/TSI0_CH6/PTB1/I2C0_SDA/FTM1_CH1/FTM1_QD_PHB 17 EXTAL0/PTA18/FTM0_FLT2/FTM_CLKIN0 18 XTAL0/PTA19/FTM1_FLT0/FTM_CLKIN1/LPTMR0_ALT1 12 13 JTAG_TDI/EZP_DI/TSI0_CH2/PTA1/UART0_RX/FTM0_CH6 14 JTAG_TDO/TRACE_SWO/EZP_DO/TSI0_CH3/PTA2/UART0_TX/FTM0_CH7 15 JTAG_TMS/SWD_DIO/TSI0_CH4/PTA3/UART0_RTS/FTM0_CH0 16 NMI/EZP_CS/TSI0_CH5/PTA4/FTM0_CH1/LLWU_P3 JTAG_TCLK/SWD_CLK/EZP_CLK/TSI0_CH1/PTA0/UART0_CTS/UART0_COL/FTM0_CH5 POWER_EN 4 R41 DNP R40 R44 1K 15K 10.0K P5V_SDA 0.1UF C21 P5V_SDA 1 VTRG_EN ENABLE CSLEW VIN U10 ACTIVE HIGH 3 MIC2005_CSLEW 5 C13 18PF DNP 2 4 6 D2 P3V3_SDA TP507 R505 10.0K DNP VTRG_FAULT_B 10.0K R33 P3V3_SDA SDA_USB_P5V_SENSE X1 2 R504 4.7K DNP TP510 P5V_SDA POWER_EN VTRG_FAULT_B 1 R10 220 UART1_RTS_TGTMCU_R UART1_CTS_TGTMCU_R UART1_TX_TGTMCU_R UART1_RX_TGTMCU_R SDA_SPI0_SCK SDA_SPI0_SOUT SDA_SPI0_SIN SDA_LED TP511 MIC2005-0.8YM6 GND FAULT VOUT 29 PTD4/SPI0_PCS1/UART0_RTS/FTM0_CH4/EWM_IN/LLWU_P14 30 ADC0_SE6B/PTD5/SPI0_PCS2/UART0_CTS/UART0_COL/FTM0_CH5/EWM_OUT 31 ADC0_SE7B/PTD6/SPI0_PCS3/UART0_RX/FTM0_CH6/FTM0_FLT0/LLWU_P15 32 PTD7/CMT_IRO/UART0_TX/FTM0_CH7/FTM0_FLT1 C10 22PF DNP SDA_SWD_OE_B SDA_EXTAL SDA_XTAL SDA_JTAG_TCLK SDA_JTAG_TDI SDA_JTAG_TDO SDA_JTAG_TMS SDA_SWD_EN_B LED GREEN 22 ADC0_SE15/TSI0_CH14/PTC1/SPI0_PCS3/UART1_RTS/FTM0_CH0/I2S0_TXD0/LLWU_P6 23 ADC0_SE4B/CMP1_IN0/TSI0_CH15/PTC2/SPI0_PCS2/UART1_CTS/FTM0_CH1/I2S0_TX_FS 24 CMP1_IN1/PTC3/SPI0_PCS1/UART1_RX/FTM0_CH2/I2S0_TX_BCLK/LLWU_P7 25 PTC4/SPI0_PCS0/UART1_TX/FTM0_CH3/CMP1_OUT/LLWU_P8 26 PTC5/SPI0_SCK/LPTMR0_ALT2/I2S0_RXD0/CMP0_OUT/LLWU_P9 27 CMP0_IN0/PTC6/SPI0_SOUT/PDB0_EXTRG/I2S0_RX_BCLK/I2S0_MCLK/LLWU_P10 28 CMP0_IN1/PTC7/SPI0_SIN/USB_SOF_OUT/I2S0_RX_FS (To enable 5v from USB connector) PWR SWITCH 33 2 19 10 9 6 5 4 3 11 8 7 1 U7 OpenSDA Interface A C 4 3 8.00MHZ 0 SDA_SWD_EN_B_R TP517 R23 0.1UF R39 0.1UF C518 10.0K R51 10.0K 3 3 P3V3_SDA R49 4.7K 3 1 SDA_RTS_EN5 P3V3_SDA P3V3_SDA R37 4.7K 3 1 SDA_CTS_EN5 P3V3_SDA R64 4.7K 1 5 P3V3_SDA R59 4.7K 3 5 1 P3V3_SDA 7 6 5 4 P3V3_SDA 0.1UF C514 P3V3_SDA R19 4.7K 3 SDA_RX_EN 5 Isolation and level shift stage (for 1.8 to 5V compatibility) TP525 UART1_RTS_TGTMCU_R TP522 10.0K A1 A2 VCCB 1B 2B DIR VCCA DIR 4 6 2 C522 0.1UF C515 0.1UF 2 4 6 0.1UF C517 V_TGTMCU 2 4 6 C511 0.1UF 0.1UF C520 V_TGTMCU 2 4 6 V_TGTMCU 8 1 2 3 PU/PD LOGIC (DIR PIN): BUFFER IS TRISTATED WHEN P3V3_SDA IS UNPOWERED GND B VCCB 74LVCH1T45 A VCCA DIR U14 74LVCH1T45 GND B VCCB 0.1UF V_TGTMCU 2 4 C503 TP_2102_A 0.1UF C501 P3V3_SDA 1 2 UART1_RTS_TGTMCU_BUF UART1_CTS_TGTMCU_BUF SWD_CLK_TGTMCU_BUF SWD_DIO_TGTMCU_BUF UART1_TX_TGTMCU_BUF UART1_RX_TGTMCU_BUF 1K 1K SHORTING HEADER ON BOTTOM LAYER J13 HDR 1X2 DNP R28 Isolation Resistors R27 C1 1000pF SW1_RST_B DNP R5020 TL1015AF160QG SW6 1-2: Default. 2-3: Reset signal direct to the MCU, to use when OpenSDA is not powered. TP501 R503 10.0K P3V3_SDA SDA_RST_TGTMCU_J_B RESET SDA_RST_TGTMCU_J_B V_TGTMCU GND B VCCB 74LVCH1T45 A VCCA DIR U16 U13 A GND B VCCB U15 74LVCH1T45 A VCCA DIR 74LVC2T45GM,125 VCCA 1A 2A GND SDA_SWD_EN SDA_SWD_OE V_TGTMCU U8 GND B VCCB 74LVCH1T45 A VCCA DIR U5 1 2 6 Y2 4 Y1 GND NLX2G14 2 VCC 5 P3V3_SDA J25 HDR 1X2 P3V3_SDA 0 SDA_SWD_EN_R 0.1UF C523 10.0K C516 R65 R66 R60 0.1UF C521 TP515 1 3 U11 0.1UF C513 DNP SDA_RST_TGTMCU_B 0 SDA_SWD_OE_R UART1_CTS_TGTMCU_R SDA_SPI0_SCK TP529 SDA_SWD_EN SDA_SPI0_SOUT TP528 SDA_SWD_OE R61 UART1_TX_TGTMCU_R SDA_SPI0_SIN TP514 10.0K R35 0 SDA_SWD_OE_B_R R34 10.0K P3V3_SDA UART1_RX_TGTMCU_R 22PF DNP C15 R31 R38 10.0K P3V3_SDA 3 1 2 Freescale Semiconductor, Inc. SDA_LED_R R55 R43 1K 1K J14 HDR 1X2 SHORTING HEADER DNP ON BOTTOM LAYER 1 2 U500 OE B1 B2 VCCB R501 Output to system from Level shifter 100 V_TGTMCU TP500 3.3VDC, 10mA should be provided to this rail (P3V3_SDA) in order to power openSDA module OPEN SDA INPUT POWER i path P3V3_SDA Output to system from Level shifter Output to system from Level shifter Output to system from Level shifter resistors with the same orientation and provide same airgap between RX to TX resistors terminals in a square fashion. 2 R1 A SDA_RST_LED 4.7K R500 180K V_TGTMCU LVLRST_EN P3V3_SDA TP_2102_B 0.1UF C500 V_TGTMCU Output to system from Level shifter RED D1 Place both 5 Bypass CAD NOTE: RX/TX POKA-YOKE: C 8 7 6 RST Push Button NTSX2102GU8H GND A1 A2 VCCA J24 HDR_1X3 4 2 3 1 2 1 2 3 5 SH501 i path SH500 0 DNP SH502 SDA_VOUT33 V_TGTMCU 0 0 pg(3) pg(3) pg(3) pg(3) i path i path P3V3 Power should be provided to this rail for the logic related to your platform I/O FIUO: ___ Thursday, Jullly 30, 2015 Sheet 4 of PUBI: X SCH-28379 | PDF: SPF-28379 Document Number Date: 1 FCP: ___ OpenSDA interface X-FRDM-KW40Z Siiize D Page Tiiitllle: ICAP Clllassiiifiiicatiiion: Drawiiing Tiiitllle: P3V3 This power rail is supported from 1.8V to 5V I/O POWER INPUT P5V_TRG_SDA can provide up to 450mA (per USB spec) of power at 5VDC to your system SDA_VOUT33 can provide up to 120mA of power at 3.3VDC to your system P5V_SDA_PSW Note: You can power openSDA with your own power supplies by replacing this rail (SDA_VOUT33) with your 3.3V power supply rail SDA_VOUT33 OPEN SDA POWER OUTPUTS UART0_RTS_TGTMCU UART0_CTS_TGTMCU SWD_CLK_TGTMCU pg(3) pg(3) pg(3,5) SWD_DIO_TGTMCU UART0_TX_TGTMCU UART0_RX_TGTMCU RST_TGTMCU_b TARGET MCU INTERFACE SIGNALS 1 5 Rev C A B C D FRDM-KW40Z development board Figure 21. FRDM-KW40Z board schematic rev. C (sheet 2 of 3) FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 25 A B D 1 SPI_SS 15 2 10 7 6 4 2 1 SPI_CLK U9 C22 NC_15 BYP I2C_SCL_FXOS8700CQ I2C_SDA_FXOS8700CQ SA0_FXOS8700CQ 0.1UF BUZZER R12 4.7K C519 0.1UF DNP DNP TVS2 SW4 SW3 13 3 16 8 9 11 TP502 TP503 R42 R30 R14 47K R512 1K TP526 5 1 AST1109MLTRQ BUZZER Q1 MMBT3904LT1G R507 0 P3V3_BRD 0 0 TP509 5 1 2 4 P3V3_BRD C6 8 2 1 SW4 2 PB TP537 COM R511 330 LED5 BLUE P3V3_LED TP20 TP531 I2C1_SCL I2C1_SDA pg(3,4,5) 0 INT2_COMBO R18 RST_TGTMCU_b 0 INT1_COMBO DNP R7 R510 10.0K 0.1UF C512 R13 10.0K SH19 0 DNP TP542 TP28 TP14 INT1_COMBO 330 LED4 RED 13 12 11 10 6 9 15 14 B1 B2 B3 B4 NC NC1 EXP C46 12PF 0 TP535 TP540 TP26 Y2 2 CMT R79 27K R80 1.5K PTC4 330 LED2 RED P3V3_LED 32.768KHZ 1 0 PTB17 U12 8 7 2 3 4 5 TXB0104 OE GND A1 A2 A3 A4 1 Q2 MMBT3904LT1G TP539 P3V3 TP22 PTC5 PTC4 SWD_DIO_TGTMCU BUZZER TP2 TP36 3 FRDM-KW40 signals to DEMO which require translation from 3.3 V to 5V. Zero Ohm 0402 Cut Trace PCB Footprint. SH23 0 SH20 0 SH21 0 SH22 0 0.1UF C510 BZ500 P3V3 TP538 D11 VSMB2948SL R82 18.2 TP541 TP21 INFRARED LED 1 PTC5 330 P3V3_LED C49 0.1UF DNP TP543 TP25 LED1 RED P3V3_LED 32kHz XTAL C47 12PF 0 R77 R76 DNP PTB17/EXTAL_32K IN CIRCUIT TEST GND PROBING VCCA PTC1 330 LED3 RED 0 R74 PTB16/XTAL_32K P3V3_LED R71 DNP VCCB SH18 0 DNP P3V3_BRD PTC0 P5V_USB pg(5) D10 pg(5) D9 pg(5) D8 pg(5) D7 R29 10.0K 4 R513 10.0K DNP PTB16 P3V3_LED P3V3_BRD P3V3_BRD P3V3_BRD SPI_SIN TL1015AF160QG AT45DB021E SO SW3 TL1015AF160QG 1 TP508 0.1UF R17 10.0K DNP P3V3 POWER ON/ COMMUNICATING R81 330 LED6 GREEN TP19 C11 0.1UF WP SI SCK CS P3V3_LED_PWR I2C1_SCL I2C1_SDA R506 10.0K R32 0 DNP RST_FXOS8700CQ CRST_FXOS8700CQ INT2_COMBO_R C9 1000pF DNP C2 1000pF DNP U4 INT1_COMBO_R TP504 SPI_SOUT FXOS8700CQ RSVD2 RSVD1 RST CRST SA0/MISO SA1/CS INT2 INT1 R16 10.0K P3V3_BRD SDA/MOSI SCL/SCLK 0.1UF C507 TP516 P3V3_BRD SA1_FXOS8700CQ 4.7uF C508 P3V3_BRD 10.0K R22 PGB2010402KRHF FXOS8700CQ COMBO SENSOR P3V3_BRD R20 10.0K P3V3_BRD ELEC_IN1 ELEC_IN2 DNP 2 1 TVS1 PGB2010402KRHF INTERRUPT PUSH BUTTONS R24 10.0K 3x3mm 1 SW1 ELECTRODES ELEC_IN2 1 3x3mm SW2 P3V3 A C R26 10.0K DNP A C 1 5 A C ELEC_IN1 14 VDD 1 VDDIO GND2 12 6 VCC GND EP 7 9 A C A C 3 2 pg(3,4) UART0_RX_TGTMCU PTC1 PTC0 ADC0_SE1/POT pg(3) PTB18 pg(3,5) COM PTB18/DAC0_OUT/ADC0_SE4/CMP0_IN2/I2C_SCL PTB0/TSIO_CH14/I2C0_SCL/CLKOUT CMT PTC5 I2C1_SDA I2C1_SCL pg(5) pg(5) pg(3,5) pg(3,5) pg(3,5) pg(3,5) PTB17 PTB16 P5V_USB P3V3 C32 1000pF R67 5K 2 J15 HDR_1X3 TP532 V_BATT POT ADC0_SE1/POT 2 R88 0 0 P5-9V_VIN SH33 SH31 J2 CON_2x10_0.1 0 0 P3V3 P3V3 C48 2.2uF SH24 SH27 SH26 0 0 0 0 0 TP31 DEBUG GROUND HOOK PTC3/TSI0_CH15/ATST4/RX_SWITCHT/I2C1_SDA/UART0_TX PTC2/TSI0_CH14/ATST3/TX_SWITCHT/I2C1_SCL/UART0_RX PTB17/XTAL32K/I2C_SDA PTB16/EXTAL32K/I2C_SCL PTB1/TSIO_CH15/I2C0_SDA/CMT_IRO PTC5/TSI0_CH1/LPTMR0_ALT2/UART0_RTS_b P5V_USB pg(3,4,5) RST_TGTMCU_b PTC4/TSI0_CH0/EXTRG_IN/UART0_CTS_b ADC0_DM0/ADC0_SE1/ADC0_DP1/CMPO_IN1 ADC0_DP0/ADC0_SE0/CMPO_IN0 ARDUINO COMPATIBLE HEADERS I2C1 Place both resistors with the same orientation and provide same airgap between SCL to SDA resistors terminals in a square fashion. CAD NOTE: SCL/SDA POKA-YOKE: DFLS130L-7 D4 P5V_SDA_PSW R87 J29 HDR_2X1 J3 CON_2x8_0.1 FREEDOM PLATFORM COMPATIBILITY HEADERS PTC1/ANT_B/I2C0_SDA/UART0_RTS_b PTC0/ANT_A/I2C0_SCL/UART0_CTS_b PTC17/TSI0_CH5/SPI0_SOUT/UART0_RX PTC16/TSI0_CH4/SPI0_SCK/I2C0_SDA/UART0_RTS_b 0 0 DNP 0 0 DNP 0 0 DNP 0 0 DNP J28 HDR_2X1 SH3 SH7 R8 PTC19/TSI0_CH7/SPI0_PCS0/I2C0_SCL/UART0_CTS_b 0 0 0 0 0 J31 HDR_2X1 J30 HDR_2X1 SH4 SH8 R3 PTA1/SWD_CLK PTC18/TSI0_CH6/SPI0_SIN/UART0_TX SH10 R5 SH9 R4 PTB3/ADC0_SE2/ADC0_DP2/CMP0_IN4/RTC_CLKOUT SH15 SH14 SH13 SH12 SH11 PTA0/SWD_DIO/TSI0_CH8 PTA16/TSIO_CH10/SPI1_SOUT PTA17/TSIO_CH11/SPI1_SIN PTA19/TSIO_CH13/SPI1_PCS0 PTA18/TSIO_CH12/SPI1_SCK PTB2/ADC0_SE3/ADC0_DM2/CMP0_IN3 PTC7/TSI0_CH3/I2C_SDA/UART0_TX/SPI0_PS2 PTC6/TSI0_CH2/I2C_SCL/UART0_RX USB HOST POWER pg(3,5) PTC4 pg(3,5) ADC0_SE0/BATTERY_MONITORING pg(3,5) Place both resistors with the same orientation and provide same airgap between MISO to MOSI resistors terminals in a square fashion. CAD NOTE: MISO/MOSI POKA-YOKE: pg(3,5) pg(3,5) SPI_SOUT SPI_CLK SPI_SIN pg(3,5) pg(3,5) pg(3,5) SPI_SS D10 KW40_SWD_CLK D9 pg(3,5) pg(5) pg(3,4) pg(5) BUZZER pg(3,5) pg(5) D7 pg(3,4) SWD_DIO_TGTMCU pg(5) D8 I2C0 P3V3 SPI0 ELEC_IN1 ELEC_IN2 SW4 SW3 pg(3,5) INT1_COMBO pg(3,5) pg(3,5) pg(3,5) pg(3,5) pg(3,4) UART0_TX_TGTMCU UART0 2 2 1 2 1 2 1 2 1 3 1 3 5 7 9 11 13 15 1 C52 C51 C50 R54 R45 FCP: ___ SH25 SH28 SH29 SH30 DFLS130L-7 0 0 A C53 10uF DNP 10uF 10uF 10uF DNP DNP DNP OUT FIUO: ___ 0 0 0 0 PUBI: X Document Number Thursday, July 30, 2015 Size C Date: 1 Sheet 5 SCH-28379 | PDF: SPF-28379 of 5 J4 CON_2x6_0.1 J1 CON_2x8_0.1 ARDUINO SHIELDS & PERIPHERALS X-FRDM-KW40Z ICAP Classification: Drawing Title: Page Title: IN 5VDC VR SUPPORT J26 HDR_1X3 DNP P5-9V_VIN P5V_USB D10 C 2 4 6 8 10 12 14 16 GND1 1 2 3 2 A C 1 2 3 4 1 2 3 1 A C A 20 18 16 14 12 10 8 6 4 2 19 17 15 13 11 9 7 5 3 1 P5V_LDO_OUT 3 BYP_FXOS8700CQ C 16 14 12 10 8 6 4 2 15 13 11 9 7 5 3 1 1 3 5 7 9 11 26 2 4 6 8 10 12 5 Rev C A B C D FRDM-KW40Z development board Figure 22. FRDM-KW40Z board schematic rev. C (sheet 3 of 3) FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. FRDM-KW40Z development board Figure 23. FRDM-KW40Z development board component location (top view) Figure 24. FRDM-KW40Z development board test points FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 27 FRDM-KW40Z development board Figure 25. FRDM-KW40Z development board layout (top view) Figure 26. FRDM-KW40Z development board layout (bottom view) FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 28 Freescale Semiconductor, Inc. FRDM-KW40Z development board 4.3.1 Bill of materials Table 6. Bill of materials (common parts for all frequency bands) (Sheet 1 of 5) Item Qty Reference Value 1 1 ANT1 F_Antenna 2 1 BT500 3 1 BZ500 4 2 C1,C32 1000pF 5 2 C2,C9 DNP 1000pF 6 7 C3,C25,C27, C39,C43,C45,C50 2 10uF 7 28 C6,C11,C21, C22,C31,C500,C5 01,C503, C504,C505, C507,C510, C511,C512, C513,C514, C515,C516, C517,C518, C520,C521, C522,C523, C524,C528, C529,C530 8 2 3003 Description Mfg. part number — — PCB F ANTENNA, NO PART ORDER HOLDER BATTERY 20MM DIA TH Keystone Electronics 3003 MALLORY AST1109MLTRQ CAP CER 1000PF 50V 5% C0G 0402 MURATA GRM1555C1H102JA01D CAP CER 1000PF 50V 5% C0G 0402 MURATA GRM1555C1H102JA01D CAP CER 10uF 16V 20% X5R 0603 TAIYO YUDEN EMK107BBJ106MA-T 0.1UF CAP CER 0.1UF 10V 10% X5R 0402 KEMET C0402C104K8PAC 22PF CAP CER 22PF 50V 5% C0G 0402 AVX 04025A220JAT2A YAGEO AMERICA AST1109MLT AUDIO DEVICE BZR PIEZO 4.1 KHZ RQ 73DB 1-20V SMT C10,C15 DNP Mfg. name 9 1 C13 DNP 18PF CAP CER 18PF 50V 5% C0G 0603 10 1 C33 DNP 1.8pF CAP CER 1.8PF 50V 0.25PF C0G 0402 MURATA GRM1555C1H1R8CA01D CC0603JRNPO9BN180 11 1 C34 DNP 10PF CAP CER 10PF 50V 5% C0G 040210PF AVX 04025A100JAT2A 12 1 C40 10PF CAP CER 10PF 50V 5% C0G 040210PF AVX 04025A100JAT2A 13 2 C41,C44 11pF CAP CER 11pF 50V 1% C0G 0402 AVX 04025U110FAT2A 14 1 C42 0.6PF CAP CER 0.6PF 50V +/-0.25PF C0G 0402 MURATA GRM1555C1HR60CZ01 15 5 C46,C47,C525, C526,C527 12PF CAP CER 12PF 50V 5% C0G 0402 MURATA GRM1555C1H120JZ01D 16 2 C48,C506 2.2UF CAP CER 2.2uF 25V 10% X5R 0603 TDK C1608X5R1E225K 17 2 C49,C519 DNP 0.1UF CAP CER 0.1UF 10V 10% X5R 0402 KEMET C0402C104K8PAC 18 5 C50,C51,C52, C53, C54 DNP 10uF CAP CER 10UF 10V 20% X5R 0603 TAIYO YUDEN LMK107BJ106MALTD 19 1 C55 1uF CAP CER 1uF 16V 10% X5R 0603 TAIYO YUDEN EMK107BJ105KA-T 20 1 C508 4.7uF CAP CER 4.7UF 6.3V 20% X5R 0402 VENKEL COMPANY C0402X5R6R3-475MNP 21 2 C509, C531 1.0UF CAP CER 1.0UF 10V 10% X5R 0402 YAGEO AMERICA CC0402KRX5R6BB105 22 1 D1 23 1 D2 LED GREEN LED GRN SGL 20MA 0603 OSRAM LG L29K-G2J1-24-Z 24 8 D3,D4,D5,D6, D7,D8,D9,D10 DFLS130L-7 DIODE SCH 1A 30V PowerDI123 DIODES INC DFLS130L-7 RED LED ULTRA BRIGHT RED SGL 30MA LITE ON 0603 LTST-C190KRKT FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 29 FRDM-KW40Z development board Table 6. Bill of materials (common parts for all frequency bands) (Sheet 2 of 5) Item Qty Reference Value Description Mfg. name Mfg. part number 25 1 D11 VSMB2948SL LED IR RA 100mA 1.35V 940NM SMD VISHAY INTERTECHNOLOGY 26 1 J2 CON_2x10 CON 2x10 FEMALE 100MIL SP 335H 394LL AU MTCONN JT254F-D180-850-210-10 D 27 2 J1,J3 CON_2X8 CON 2x8 FEMALE 100MIL SP 335H 394LL AU MTCONN JT254F-D180-850-208-10 D 28 9 J8,J20,J21,J27,J2 8,J29,J30,J31,J33 HDR 1X2 HDR 1X2 TH 2MM SP 217H AU 110L SAMTEC TMM-102-02-G-S 29 1 J5 DNP CON, SMA, EDGE 0.062IN, 50  FEMALE 18 GHZ EMERSON CONNECTIVITY 142-0701-851 30 1 J6 MOLEX 475900001 31 2 J9, J11 32 1 J12 DNP 33 3 J13,J14,J25 DNP 34 3 J15,J23,J24 HDR_1X3 HDR 1X3 TH 2MM SP 217H AU 110L SAMTEC TMM-103-02-G-S SMA USB_MICRO_ CON 5 AB USB_MICRO_AB_RECEPTACLE RA SKT SMT 0.65MM SP 122H AU HDR 2X5 VSMB2948SL HDR 2X5 TH 50MIL CTR 167H AU 91L ANYTRONIC 0922S0205011N6T-2LF HDR 1X2 HDR 1X2 TH 2MM SP 217H AU 110L TMM-102-02-G-S HDR 1X2 HDR 1X2 TH 2MM SP 217H AU 110L, NO PART TO ORDER SAMTEC — — 35 3 J16,J17,J22 HDR 2X3 HDR 2X3 TH 2MM CTR 217H AU 110L SAMTEC TMM-103-02-G-D 36 1 J18 HDR 2X2 HDR 2X2 TH 2MM CTR 217H AU 110L SAMTEC TMM-102-02-G-D 37 1 J19 HDR 1X2 TH HDR 1X2 TH 100MIL SP 339H AU 98L SAMTEC TSW-102-07-G-S 38 1 J4 CON_2X6 CON 2x6 FEMALE 100MIL SP 335H 394LL AU 39 1 J26 DNP HDR_1X3 HDR 1X3 TH 100MIL SP 330H AU 98L SAMTEC HTSW-103-07-S-S 40 4 LED1,LED2, LED3,LED4 LED RED CLEAR SGL 30MA SMT 0805 LITE ON LTST-C171KRKT 41 1 LED5 BLUE LED BLUE SGL 20MA SMT 0805 LITE ON LTST-C171TBKT 42 1 LED6 GREEN LED GRN SGL 30MA SMT 0805 LITE ON LTST-C171KGKT 43 2 L1,L2 330 W IND FER BEAD 330@100MHZ 1.7A 0603 TDK MPZ1608S331A 44 1 L3 10uH IND WW FER 10uH@1MHz 0.99A 20% TDK 4012 VLS4012ET-100M 45 1 L4 DNP 2.4nH IND—0.0024UH@100MHZ 300MA 0.0003UH 0402 MURATA LQG15HN2N4S02D 46 1 L5 100 nH IND -- 0.1uH@100MHZ 200MA 5% 0402 TDK MLG1005SR10JT000 47 1 L6 10nH IND—0.010uH@100MHZ 350MA 5% 0402 TDK MLK1005S10NJT000 48 2 Q1,Q2 ON SEMICONDUCTOR MMBT3904LT1G 49 1 R1 RES MF 100  1/16W 5% 0402 VENKEL COMPANY CR040216W101JT 50 11 R3,R4,R5,R8, R36,R50,R73, R502,SH18, SH19,SH502 DNP RES MF ZERO OHM 1/16W 5% 0402 ROHM MCR01MZPJ000 RED MMBT3904LT TRAN NPN GEN 200MA 40V SOT-23 1G 100 0 MTCONN JT254F-D180-850-206-10 D FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 30 Freescale Semiconductor, Inc. FRDM-KW40Z development board Table 6. Bill of materials (common parts for all frequency bands) (Sheet 3 of 5) Item Qty Reference Value Mfg. name Mfg. part number RES MF ZERO OHM 1/16W 5% 0402 ROHM MCR01MZPJ000 220 RES MF 220  1/10W 5% 0603 KOA SPEER RK73B1JTTD221J R12,R19,R37, R46,R49,R59, R64,R501 4.7K RES MF 4.7K 1/16W 5% 0402 YAGEO AMERICA RC0402JR-074K7L R14 47K RES MF 47K 1/16W 5% 0402 VENKEL COMPANY CR0402-16W-473JT 10.0K RES MF 10.0K 1/16W 1% AEC-Q200 0402 VISHAY INTERTECHNOLOGY CRCW040210K0FKED 10.0K RES MF 10.0K 1/16W 1% AEC-Q200 0402 VISHAY INTERTECHNOLOGY CRCW040210K0FKED 33 RES MF 33.0  1/16W 1% 0402 THYE MING TECH CO LTD CR-02FL6---33R R27,R28,R41, R43,R55,R512 1K RES MF 1.0K 1/16W 5% 0402 VISHAY INTERTECHNOLOGY CRCW04021K00JNED R32,R52,R56, R71,R76 DNP 0 RES MF ZERO OHM 1/10W—0603 VISHAY INTERTECHNOLOGY CRCW06030000Z0EA 15K RES MF 15K 1/16W 1% 0402 KOA SPEER RK73H1ETTP1502F 0 RES MF ZERO OHM 1/10W -AEC-Q200 0603 VISHAY INTERTECHNOLOGY CRCW06030000Z0EA VISHAY INTERTECHNOLOGY CRCW0402330RJNED 51 19 R7,R18,R30, R31,R35,R42, R61,R66,R68, R69,R70,R72, R74,R75,R77, R78,R83,R84, R507 52 1 R10 53 8 54 1 55 20 R13,R16,R20, R22,R23,R24, R29,R33,R34, R38,R39,R47, R51,R60,R63, R65,R503,R506, R508,R509 56 6 R17,R26,R40, R505, R510, R513 DNP 57 2 R21,R25 58 6 59 5 0 Description 60 1 R44 61 4 R45,R54,R87,R88 62 6 R48,R53,R57, R62,R81,R511 330 RES MF 330  1/16W 5% 0402 63 1 R67 5K RES POT 5.0K 1/4W 20% SMT 64 1 R79 27k RES MF 27K 1/16W 5% 0402 VISHAY INTERTECHNOLOGY CRCW040227K0JNED 65 1 R80 1.5K RES MF 1.5K 1/16W 5% 0402 VISHAY INTERTECHNOLOGY CRCW04021K50JNED — — 66 1 R82 18.2 RES MF 18.2  1/4W 1% 0805 ROHM ESR10EZPF18R2 67 1 R500 180K RES MF 180K 1/16W 1% 0402 KOA SPEER RK73H1ETTP1803F 68 1 R504 DNP 4.7K RES MF 4.7K 1/16W 5% 0402 YAGEO AMERICA RC0402JR-074K7L 69 1 R85 102K RES MF 102K 1/16W 1% 0402 KOA SPEER RK73H1ETTP1023F 70 24 SH3,SH4,SH7, SH8,SH9,SH10, SH11,SH12,SH13, SH14,SH15, SH20,SH21, SH22,SH23, SH24,SH25, SH26,SH27, SH28,SH29, SH30,SH31,SH33 0 ZERO OHM CUT TRACE 0402 PADS; NO PART TO ORDER — — FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 31 FRDM-KW40Z development board Table 6. Bill of materials (common parts for all frequency bands) (Sheet 4 of 5) Item Qty Reference Value Description Mfg. name Mfg. part number 0 ZERO OHM CUT TRACE 0603 PADS; NO PART TO ORDER — — 71 3 SH500,SH501, SH503 72 4 SW3,SW4,SW5, SW6 73 2 SW1,SW2 3x3mm 74 36 TP2,TP3,TP4, TP14,TP19, TP20,TP22, TP29,TP30, TP36, TP500-534, TP536, TP540-543 75 21 TP3,TP4,TP21, TP25,TP26,TP28, TP30,TP507, TP513,TP518, TP524,TP530, TP531,TP533, TP534,TP535, TP536,TP537, TP538,TP539, TP544 76 1 TP31 TESTLOOP_ TEST POINT PC MULTI PURPOSE BLACK BLK TH KEYSTONE ELECTRONICS 5011 77 2 TVS1,TVS2 DNP PGB2010402 DIODE ESD SUPPRESSOR KRHF BIDIR—12V 0402 LITTELFUSE PGB2010402KRHF 78 3 U1,U2,U6 0402ESDA-M DIODE TVS BIDIR—30V 0402 LP COOPER BUSSMANN 0402ESDA-MLP1 79 1 U4 AT45DB021E IC MEM SPI SERIAL 2MBIT FLASH 85MHZ 1.65-3.6V UDFN8 ADESTO TECHNOLOGIES AT45DB021E-MHN2B-T 80 5 U5,U13,U14, U15,U16 74LVCH1T45 IC XCVR 1BIT 3-STATE DUAL 1.2–5.5V XSON6 NXP SEMICONDUCTORS 74LVCH1T45GM,132 81 1 U7 MK20DX128V IC MCU FLASH 128KB 50MHZ FM5 1.71–3.6V QFN32 FREESCALE SEMICONDUCTOR MK20DX128VFM5 82 1 U8 74LVC2T45G IC XCVR DUAL SUPPLY 1.2–5.5V M,125 XQFN8 NXP SEMICONDUCTORS 74LVC2T45GM,125 83 1 U9 FXOS8700CQ IC ACCELEROMETER AND MAGNETOMETER SENSOR 3-AXIS 2.5V QFN16 FREESCALE SEMICONDUCTOR FXOS8700CQ 84 1 U10 MIC2005-0.8Y IC LIN SW PWR 0.8A 2.5-5.5V M6 SOT23-6 MICREL MIC2005-0.8YM6 85 1 U11 NLX2G14 IC INV DUAL SCHMITT TRIGGER 1.65-5.5V ULLGA6 On Semiconductor NLX2G14AMX1TCG 86 1 U12 TXB0104 IC VXLTR 4BIT BIDIRECTIONAL 1.2-3.6V/1.65-5.5V QFN14 TEXAS INSTRUMENTS TXB0104RGYRG4 87 1 U17 NCP1117ST3 IC VREG LDO 1A 3.3V SOT223 3T3G ON Semiconductor NCP1117ST33T3G 88 1 U18 MKW40Z160V IC MCU XCVR 2.4GHZ BLUETOOTH HT4 LOW ENERGY MAPLGA64 FREESCALE SEMICONDUCTOR MKW40Z160VHT4 TL1015AF160 SW SPST PB 50MA 12V SMT QG E SWITCH TL1015AF160QG CAPACITIVE SINGLE ELECTRODE 3X3MM SQUARED ROUNDED CORNERS (NOT A PART TO ORDER) — — TPAD_030 TEST POINT PAD 30MIL DIA SMT, NO PART TO ORDER — — TPAD_040 TEST POINT PAD 40MIL DIA SMT, NO PART TO ORDER — — FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 32 Freescale Semiconductor, Inc. PCB manufacturing specifications Table 6. Bill of materials (common parts for all frequency bands) (Sheet 5 of 5) Item Qty Reference Value 89 1 U500 90 1 X1 8.00MHZ 91 1 Y1 32MHZ 92 1 Y2 32.768KHZ 93 1 Z1 50/100 W 5 Description NTSX2102GU IC DUAL SUPPLY XCVR 50 MBPS 8H 5.5V XQFN8 Mfg. name NXP Semiconductors Mfg. part number NTSX2102GU8H XTAL 8.00MHZ RSN CERAMIC—SMT MURATA CSTCE8M00G55-R0 XTAL 32MHZ 9PF—SMT 3.2X2.5MM NDK EXS00A-CS02368 XTAL 32.768 KHZ SMT ROHS COMPLIANT EPSON ELECTRONICS FC-135 32.7680KA-A3 XFMR BALUN 2.45GHZ 50MHZ 50/100  3W SMT JOHANSON TECHNOLOGY 2450BL15B100_ PCB manufacturing specifications This section provides the specifications used to manufacture the FRDM-KW40Z development Printed Circuit Board (PCB) described in this guide. The FRDM-KW40Z development boards must comply with the following: • The PCB must comply with Perfag1D/3C (www.perfag.dk/en/). • The PCB manufacturer’s logo is required. • The PCB production week and year code is required. — The manufacturer’s logo and week/year code must be stamped on the back of the PCB solder mask. — The PCB manufacturer must not insert text on the PCB either in copper or in silkscreen without written permission from Freescale Semiconductor, Inc. • The required Underwriter’s Laboratory (UL) Flammability Rating: — The level is 94V-0 (http://ulstandards.ul.com/standard/?id=94). — The UL information must be stamped on the back of the PCB solder mask. • • NOTE A complete set of design files for the MKW40Z development boards is available at the Freescale website (www.freescale.com/KW40Z) under the “Software and Tools” tab. Use the reference designs as a starting point for custom applications. The Freescale IEEE 802.15.4/ZigBee Package and Hardware Layout Considerations Reference Manual (document ZHDCRM) is also available at the same website to provide additional design guidance. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 33 PCB manufacturing specifications 5.1 Single PCB construction This section describes individual PCB construction details. • The FRDM-KW40Z PCBs are four-layer, multi-layer designs. • The FRDM-KW40Z PCBs must contain no blind, buried, or micro vias. • PCB data: — FRDM-KW40Z board size must be approximately 81  53 mm (3.20  2.10 inches). — FRDM-KW40Z board final thickness (Cu/Cu) must be 1.57 mm (0.62 inches) 10 % (excluding solder mask). The following table defines some of the layers of the complete PCB. The artwork identification refers to the name of the layer in commonly used terms. Table 7. FRDM-KW40Z layer by layer overview Layer Artwork identification File name 1 Silkscreen Top PSS.art 2 Top Layer Metal L1_PS.art 3 Ground Layer L2_GND.art 4 Signal Layer L3_INT_1.art 5 Bottom Layer Metal L4_SS.art 6 Silkscreen Bottom SSS.art CAUTION The FRDM-KW40Z development board contains high-frequency 2.4 GHz RF circuitry. As a result, RF component placement, line geometries and layout, and spacing to the ground plane are critical parameters. Board stackup geometry is critical. Dielectric and copper thicknesses and spacing must not be changed; follow the stackup information provided in the reference design (see the following figure). Figure 27. FRDM-KW40Z PCB layer stackup cross-section (four-layer) • • Solder mask is required Silk screen is required FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 34 Freescale Semiconductor, Inc. PCB manufacturing specifications 5.2 Panelization The panel size can be negotiated according to production volume. 5.3 Materials The PCB composite materials must meet these requirements: • Laminate—the base material (laminate) must be FR4. If you use other laminate material, then the RF electrical characteristics may change and degrade the RF performance. • Copper foil: — Top and bottom copper layers must be 1 oz. copper. — Interior layers must be 1 oz. copper. • Plating—all pad plating must be Hot Air Levelling (HAL). 5.4 Solder mask The solder mask must meet these requirements: • Solder mask type must be Liquid Film Electra EMP110 or equivalent. • Solder mask thickness must be 10-30 µm. 5.5 Silk screen The silk screen must meet these requirements: • Silk screen color must be white. • Silk screen must be applied after applying solder mask (if solder mask is required). • The silk screen ink must not extend into any plated-thru-holes. • The silk screen must be clipped back to the line of resistance. 5.6 • • 5.7 Electrical PCB testing All PCBs must be 100 % tested for opens and shorts. Impedance measurement report is not mandatory. Packaging Packaging for the PCBs must meet these requirements: • Finished PCBs must remain in panel. • Finished PCBs must be packed in plastic bags that do not contain silicones or sulphur materials (those materials can degrade solderability). 5.8 Hole specification/tool table See the ncdrill-1-4.tap file included with the Gerber files and the FAB-28379.pdf file. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 Freescale Semiconductor, Inc. 35 Revision history 5.9 File descriptions Files provided with the download include Design, Gerber, and PDF files. Gerber files are RS-274x format. Not all files included with the Gerber files are intended for PCB manufacturing. The included PDF files are: • FAB-28379.pdf—FRDM-KW40Z board fabrication drawing. • GRB-28379.zip—FRDM-KW40Z board metal layers, solder mask, solder paste, and silk screen. • SPF-28379.pdf—FRDM-KW40Z board schematic diagram. Design files are in Allegro format with OrCAD schematic capture. 6 Revision history Rev. number Date Substantive change(s) 1 06/2015 Schematic, layout and block diagram update; initial release. 2 09/2015 Schematic, layout and figures. FRDM-KW40Z Freescale Freedom Development Board User’s Guide, Rev. 2, 10/2015 36 Freescale Semiconductor, Inc. How to Reach Us: Home Page: www.freescale.com Web Support: www.freescale.com/support Information in this document is provided solely to enable system and software implementers to use Freescale products. There are no express or implied copyright licenses granted hereunder to design or fabricate any integrated circuits based on the information in this document. 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 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: www.freescale.com/SalesTermsandConditions. Freescale, the Freescale logo, Kinetis, and Freescale Freedom are trademarks of Freescale Semiconductor, Inc., Reg. U.S. Pat. & Tm. Off. All other product or service names are the property of their respective owners. ARM, the ARM Powered logo, Cortex, and Cortex-M0+ are registered trademarks of ARM Limited (or its subsidiaries) in the EU and/ or elsewhere. All rights reserved. © 2015 Freescale Semiconductor, Inc. Document Number: FRDMKW40ZUG Rev. 2 10/2015