NXP FRDM-KE17Z Board User Manual

NXP FRDM-KE17Z Board

Overview

The Kinetis KE17Z freedom (FRDM-KE17Z) board is a standalone development platform that supports two microcontrollers
(MCUs): the target MCU and an open-standard serial and debug adapter (OpenSDA) MCU. The target MCU is MKE17Z256VLL7, which is a part of Kinetis E series of Arm® Cortex®-M0+ MCU product family. The OpenSDA MCU is a Kinetis K Series K20 family device, MK20DX128VFM5.
The FRDM-KE17Z board is compatible with the Arduino shields, the NXP FRDM- TOUCH board, and the NXP FRDM-MC-LVBLDC board.
The FRDM-KE17Z board comes preloaded with the bubble peripheral demo. The demo is available at the
boards\frdmke17z\demo_apps\bubble_peripheral folder of MCUXpresso SDK. The board is lead-free and RoHS-compliant.
This document provides detailed information about the FRDM-KE17Z board interfaces, power supplies, clocks, LEDs, sensors, and other interfaces.

Acronyms

The table below lists and explains the acronyms and abbreviations used in this document.

Table 1. Acronyms and abbreviations

Related documentation

The table below lists and explains the additional documents and resources that you can refer to for more information on FRDM-KE17Z. Some of the documents listed below may be available only under a non-disclosure agreement (NDA). To request access to these documents, contact your local field applications engineer (FAE) or sales representative.

Table 2. Related documentation

Intended for system software and hardware developers and applications programmers who want to develop products with this device.| Contact NXP FAE/sales representative
Kinetis KE17Z/13Z/12Z with up to 256 KB Flash Data Sheet| Provides information about electrical characteristics, hardware design considerations, and ordering information| Contact NXP FAE/sales representative
MCUXpresso Software Development Kit (SDK) documentation| MCUXpresso Software Development Kit (SDK) is a comprehensive software enablement package designed to simplify and accelerate application development with NXP MCUs based on Arm ® Cortex ®

-M cores.

| MCUXpresso Software Development Kit (SDK) documentation

Kit contents

The table below lists the items included in the FRDM-KE17Z kit.

Table 3. Hardware kit contents

Block diagram

The figure below shows the FRDM-KE17Z block diagram. Board pictures

The figure below shows the top-side view of FRDM-KE17Z.
Figure 2. FRDM-KE17Z top view The figure below shows the onboard jumpers and connectors on FRDM- KE17Z.

Figure 3. FRDM-KE17Z jumpers and connectors The figure below shows the LEDs and push buttons on FRDM-KE17Z.
Figure 4. FRDM-KE17Z LEDs and push buttons Board features

The table below lists the features of FRDM-KE17Z. Figure 2 shows different components of FRDM-KE17Z.

Table 4. FRDM-KE17Z features

72 MHz CPU frequency

NOTE

For details on the MKE17Z256VLL7 MCU, see Kinetis KE17Z/13Z/12Z with up to 256 KB Flash Reference Manual .

.

Power supply|  | •    5 V input power via an external DC power supply, OpenSDA USB micro-AB connector, or I/O header, J3
FRDM-KE17Z feature| Processor feature used| Description
---|---|---
 |  | •    3.3 V or 5 V for MKE17Z256VLL7 by setting J18

•    3.3 V for MK20DX128VFM5

Clock|  | •    8 MHz crystal clock for MKE17Z256VLL7

•    8 MHz crystal clock for MK20DX128VFM5

•    SWD_CLK for MKE17Z256VLL7

•    SDA_JTAG_TCLK for JTAG connector

•    SWD_CLK_TGTMCU for SWD connector

TSI touch pad| Touch Sensing Input (TSI) module| • Includes two touch electrodes to support TSI functions

•    Electrode 1 is connected to TSI0 Channel 8 and electrode 2 is connected to TSI1 Channel 20

6-axis digital sensor (DNP)| Low-power Inter-Integrated Circuit (LPI2C) module| NXP FXOS8700CQ:

•    Supports motion sensing with NXP FXOS8700CQ

•    6-axis sensor with integrated linear accelerometer and magnetometer

Thermistor| High-speed analog-to-digital converter (ADC)| • Positive Temperature Coefficients (PTC) thermistor

•    Supports temperature from 90 °C to -20 °C

Debug|  | •    Onboard OpenSDA circuit provides an SWD debug interface to MKE17Z256VLL7

•    Supports micro-AB USB port to access serial port as console for debug

•    Supports JTAG connector to program and debug MK20DX128VFM5

•    Supports SWD connector to program and debug MKE17Z256VLL7

Interrupt buttons|  | Supports 2 interrupt push buttons:

•    SW2/Button 0 is used to issue non-maskable interrupt (NMI) signal to MKE17Z256VLL7

•    SW3/Button 1 is used to issue Asynchronous

Wake-up Interrupt Controller (AWIC) interrupt signal to MKE17Z256VLL7

I/O headers|  | Headers  compatible with:

•    Arduino shields

•    NXP FRDM-TOUCH

•    NXP FRDM-MC-LVBLDC

controlled by the embedded software application
Bluetooth header| LPUART| •    Supports Bluetooth connectivity via Bluetooth header, J19**

Push buttons

In addition to a Reset button for manually triggering a system reset, FRDM- KE17Z supports 2 interrupt push buttons. The following table explains the push buttons on FRDM-KE17Z. Figure 4 shows push buttons on FRDM-KE17Z.

Table 5. Reset and Interrupt push buttons

to enter the OpenSDA bootloader mode.
SW2| Push button| When pressed, generates non-maskable interrupt (NMI) signal to MKE17Z256VLL7. SW2/Button 0 is connected to the PTD3 pin on MKE17Z256VLL7.
SW3| Push button| When pressed, issues Asynchronous Wake-up Interrupt Controller (AWIC) interrupt signal to MKE17Z256VLL7. SW3/Button 1 is connected to the PTE14 pin on MKE17Z256VLL7.**

Connectors

Connectors are onboard devices that allow to connect external devices to the board. Figure 3 shows the FRDM-KE17Z connectors. The table below describes the connectors.

Table 6. FRDM-KE17Z connectors

Part identifier| Connector type| Description| Typical connection
---|---|---|---
J1| 2×8 connector| I/O headers compatible with the Arduino shields, the NXP FRDM-TOUCH board, and the NXP FRDM-MC-LVBLDC board|
J2| 2×10 connector
J3| 2×8 connector
J4| 2×6 connector
J6| USB 2.0 micro- AB connector| Console port (port for connection with host computer)| Connects to USB Type A to micro-AB cable to connect to host computer
J19| 1×4 connector| Bluetooth header|
J15| DC power jack| Power connector| Connects to 5 V power adapter
J11| 2×5 connector| OpenSDA JTAG connector| Debug interface to program and debug MK20DX128VFM5
J14| 2×5 connector| SWD connector| OpenSDA debug interface for target MCU, MKE17Z256VLL7

Jumpers

Jumpers (or shorting headers) are small connectors that allow to choose from two or more options available. Jumpers are installed during board assembly and do not require any changes. In FRDM-KE17Z, all jumpers are 2/3-pin connectors with two settings: open and shorted. Figure 3 highlights the FRDM-KE17Z jumpers available for use. The table below describes the jumpers.
The following is a list of all of the jumper options on FRDM-KE17Z.

Table 7. FRDM-KE17Z jumpers

reset to MKE17Z256VLL7 (default setting)**

•    2-3: SW1 sends reset to MKE17Z256VLL7. This setting is to be used when OpenSDA is not powered

J8| 1×2 header| MCU SWD DIO signal| •    Open: Disconnect MCU SWD_DIO to OpenSDA

•    Shorted: Connect MCU SWD_DIO to OpenSDA (default setting)

J9| 1×2 header| MCU SWD CLK signal| •    Open: Disconnect MCU SWD_CLK to OpenSDA

•    Shorted: Connect MCU SWD_CLK to OpenSDA (default setting)

J12| 1×2 header| Thermistor| •    Open: Test MCU current consumption

•    Shorted: Power supply for thermistor (default setting)

J13| 1×2 header| OpenSDA debug interface| •    Open: Isolates the onboard MCU from OpenSDA debug interface

•    Shorted (by a cut-trace on bottom layer): Connect the SWD_CLK signal from the SWD connector or OpenSDA to the MCU

J17| 1×2 header| MCU VDD

current measurement

| •    Open: Allow current measurement on MCU VDD

•    Shorted: Connect VDD to VDD_KE17Z (default setting)

J18| 1×3 header| Power supply| •    1-2: MKE17Z256VLL7 MCU is 5 V powered (default setting)

•    2-3: MKE17Z256VLL7 MCU is 3.3 V powered

LEDs

FRDM-KE17Z has light-emitting diodes (LEDs) to monitor system functions, such as power-on, reset, board faults, and so on. The information collected from LEDs can be used for debugging purposes.
LEDs are highlighted in Figure 4. The table below describes the FRDM-KE17Z LEDs.

Table 8. FRDM-KE17Z LEDs

Part identifier| LED color| LED name| Description (When LED in ON)
---|---|---|---
D2| Yellow| SDA| Indicates OpenSDA status

•    Blinks: If MKE17Z256VLL7 is in Bootloader mode

•    ON: If an OpenSDA application is running

D1| Red| Reset| Indicates Reset command is sent to MKE17Z256VLL7 via OpenSDA or when SW1 is pressed
Part identifier| LED color| LED name| Description (When LED in ON)
---|---|---|---
D3| Red/Green/Blue| RGB| Controlled by the embedded software application. IC pins connected to RGB LED:

•    PTD11: RGB_GREEN

•    PTD12: RGB_BLUE

•    PTD10: RGB_RED

D8| Green| Power| Indicates that FRDM-KE17Z is powered on

FRDM-KE17Z Functional Description

This chapter describes the features and functions of FRDM-KE17Z. For details of the MKE17Z256VLL7 MCU features, see Kinetis KE17Z/13Z/12Z with up to 256 KB Flash Reference Manual.
The chapter is divided into the following sections:

• Power supplies
• Clocking
• TSI
• 6-axis digital sensor
• Thermistor
• OpenSDA
• Input/Output headers
• Bluetooth

Power supplies

FRDM-KE17Z can be powered with 5 V power supply via:

• an external DC power supply
• OpenSDA USB micro-AB connector
• I/O header, J3

The power supply devices on the board use the 5 V power to generate required power supplies for MKE17Z256VLL7,
SWD interface, I/O headers for Arduino shields, NXP FRDM-TOUCH board, and NXP FRDM-MC-LVBLDC, and numerous other peripherals.
Since, MKE17Z256VLL7 supports 2.7 V to 5.5 V power supply, MKE17Z256VLL7 can be powered 3.3 V or 5 V by setting J18. For details about setting J18, see Jumpers. However, OpenSDA MK20DX128VFM5 is always 3.3 V powered.

Primary power supply

FRDM-KE17Z can be powered up using one of the following ways:

Table 9. Primary power supply

5 V DC, 450 mA

J3| I/O header provides 5 V power supply via a 5 V DC voltage regulator| P5V_LDO_OUT

5 V DC

Secondary power supplies

The table below describes the FRDM-KE17Z power supply devices that generate secondary power supplies for the board.

Reference

designator

| Device| Power supply voltage| Description
---|---|---|---
J6| ZX62-AB-5P| P5V_SDA| •    Power supply for power switch, MIC2005-0.8YM6 (P5V_SDA)

•    OpenSDA (P5V_SDA)

•    Unregulated power supply for MK20DX128VFM5[U3] (P5V_SDA)

U10| MIC2005-0.8YM 6

(Microchip Technology)

| P5V_SDA_PS W| •    Power supply for FRDM-KE17Z (P5V_SDA_PSW). This power rail provides up to 450 mA of power at 5 V DC to FRDM-KE17Z

•    Power supply for I/O header, J3 (P5V_SDA_PSW)

 | (From 5 V power adapter,

OpenSDA micro- AB USB

connector, or I/O header)

| VDD_5V (5 V DC)| •         Power supply for 3.3 V DC voltage regulator, NCP1117ST33T3G [U14]

•         5 V power supply for VDD if J18 is 1-2

U14| NCP1117ST33T 3G

(On Semiconductor)

| P3V3| •    3.3 V power supply for VDD if J18 is 2-3

•    I/O header, J3 (P3V3)

•    3.3 V power supply for voltage level translator, NTSX2102GU8H [U11, U13] (P3V3)

•    Power supply for FXOS8700CQ sensor

J18| VDD = 5 V, if J18

is 1-2

VDD = 3.3 V, if J18 is 2-3

| VDD| •    Power supply for Bluetooth header (VDD)

•    Power supply for interrupt push buttons (VDD)

•    Power supply for voltage level translator, NTSX2102GU8H [U11, U13] (VDD)

•    Power supply for I/O header, J3 (VDD)

J17|  | VDD_KE17Z| •    Power supply for MCU KE17Z (VDD_KE17Z)

•    Power supply for SWD connector (VDD_KE17Z)

SH1|  | V_TGTMCU| •    Power supply for I/O, NTSX2102GU8H[U2],

74LVCH1T45[U6], 74LVC2T45GM,125[U7], 74LVCH1T45[U8],

74LVCH1T45[U9] (V_TGTMCU)

L3|  | VDDA| •    Power supply for MCU KE17Z analog circuits (VDDA)

•    Power supply for thermistor RT1 (VDDA)

L4|  | VREFH| •    Supply reference voltage for MCU KE17Z (VREFH)
R71|  | AREF| •    Supply reference voltage for I/O header, J2 (AREF)
Reference

designator

| Device| Power supply voltage| Description
---|---|---|---
U3| MK20DX128VF M5| SDA_VOUT33| •    Regulator output voltage of MK20DX128VFM5 (SDA_VOUT33)

•    Power supply for OpenSDA (P3V3_SDA)

•    Power supply for OpenSDA JTAG connector (P3V3_SDA)

•    Power supply for voltage level translators, NTSX2102GU8H [U2], NL27WZ14MU1TCG [U4], 74LVCH1T45 [U6, U8, U9], 74LVC2T45GM [U7] (P3V3_SDA)

Clocking

FRDM-KE17Z has the capability to run up to 72 MHz.
The table below provides details of different clocks of FRDM-KE17Z.

Table 10. FRDM-KE17Z clocks

•    Crystal8M_XTAL is connected to MKE17Z256VLL7 pin PTB6

•    Crystal8M_EXTAL is connected

to MKE17Z256VLL7

pin PTB7

Crystal oscillator, X1| SDA_XTAL SDA_EXTAL| Frequency: 8 MHz| OpenSDA:

•    SDA_XTAL is connected to MK20DX128VFM5 pin PTA19

•    SDA_EXTAL is connected to MK20DX128VFM5 pin PTA18

SWD connector| SWD_CLK|  | MKE17Z256VLL7:

•    Connected to MKE17Z256VLL7 pin PTC4

OpenSDA circuit| SDA_JTAG_TCLK|  | JTAG connector
SWD_CLK_TGTMCU|  | SWD connector

TSI

MKE17Z256VLL7 includes the Touch Sensing Input (TSI) module to detect capacitive touch sensor.
TSI is an electrode capacitive scan method based on the hardware. The basic element in capacitive touch sensing is the electrode. In this case, the electrode is an area of conductive material with dielectric material on the top, usually plastic or glass. This is what the user touches. This conductive area plus the dielectric material effectively create a capacitor referenced to the system ground. By touching the dielectric on top of the electrode, the user effectively changes the electrode capacitance both by adding a second conductive area that is grounded and by increasing the dielectric of the original capacitor. The sensor, or the TSI module in this case, uses a capacitive sensing method to measure changes in the electrode capacitance.
FRDM-TOUCH is a touch shield board for FRDM-KE17Z with capacitive touch buttons, slider, and rotary. This board can connect with FRDM-KE17Z and control the onboard RBG LED using keys, slider, and rotary touches.
FRDM-KE17Z includes two touch electrodes to support TSI functions in self- capacitive mode.
The touch electrode 1 is connected to TSI0 channel 8 and touch electrode 2 is connected to TSI1 channel 20.

Table 11. TSI touch pad connections

FRDM-KE17Z outputs TSI signals to headers J2 and J4 to support the FRDM-TOUCH board. FRDM-TOUCH includes four touch keys in a mutual-capacitive mode, touch slider, and rotary.

Table 12. TSI lane connections

TSI channel| I/O

header

| Description| MKE17Z256VLL7 pin
---|---|---|---
TSI0_CH0| J2[5]|  | PTE6
TSI0_CH1| J2[3]|  | PTE2
TSI0_CH2| J2[9]|  | PTA13
TSI0_CH3| J2[7]|  | PTA12
TSI0_CH4| J2[17]| TOUCH_M_TX_1| PTA11
TSI1_CH4| PTA2
TSI0_CH5| J2[15]| TOUCH_M_TX_0| PTA10
TSI1_CH5| PTA3
TSI0_CH6| J2[13]| TOUCH_M_RX_1| PTE1
TSI1_CH6| PTD2
TSI0_CH7| J2[11]| TOUCH_M_RX_0| PTE0
TSI1_CH7| PTD4
TSI0_CH10| J4[1]| TOUCH_S_0| PTE10
TSI1_CH10| PTE7
TSI0_CH11| J4[3]| TOUCH_S_1| PTD1
TSI1_CH11| PTA6
TSI channel| I/O

header

| Description| MKE17Z256VLL7 pin
---|---|---|---
TSI0_CH12| J2[19]| GND| PTD0
TSI1_CH12| PTA7
TSI0_CH13| J4[5]| TOUCH_S_2| PTE16
TSI1_CH13| PTC8
TSI0_CH14| J4[7]| TOUCH_S_3| PTE15
TSI1_CH14| PTC9
TSI0_CH15| J4[9]| TOUCH_S_4| PTE13
TSI1_CH0| PTC6
TSI0_CH16| J4[11]| TOUCH_S_5| PTE5
TSI1_CH1| PTC7

6-axis digital sensor

FRDM-KE17Z reserves an area (U12) to support motion sensing with NXP FXOS8700CQ 6-axis sensor with integrated linear accelerometer and magnetometer. FXOS8700CQ is a small, low-power, 3-axis, linear accelerometer and 3-axis, magnetometer combined into a single package.
FXOS8700CQ is connected to MKE17Z256VLL7 through an I2C interface, LPI2C0. The I2C address for FXOS8700CQ is 0x1C. Since, MKE17Z256VLL7 is 5 V powered by default, voltage level translators (U11, U13) are connected between MKE17Z256VLL7 and FXOS8700CQ to provide 3.3 V power supply to FXOS8700CQ.

Table 13. FXOS8700CQ pin connections

Thermistor

FRDM-KE17Z includes a Positive Temperature Coefficients (PTC) thermistor with following features:

• Supports temperature from 90 °C to -20 °C
• THERM_0 is connected to the PTC1 pin on MKE17Z256VLL7
• THERM_1 is connected to the PTC0 pin on MKE17Z256VLL7

OpenSDA

OpenSDA is an open-standard serial and debug adapter.

The onboard MK20DX128VFM5 OpenSDA circuit bridges serial and debug communications between the USB host and MKE17Z256VLL7. The OpenSDA circuit provides an SWD debug interface to MKE17Z256VLL7. A standard USB A male to micro-AB male cable is used for debugging via the USB connector (J6).
The P&E debug application is an OpenSDA application that provides debugging and a virtual serial port all in one application. USB drivers for all P&E Microcomputer Systems debug tools are available at http://www.pemicro.com/opensda.
For details about the JTAG and SWD connectors, see Connectors.
The following table explains the OpenSDA signals connected to the target MCU (MKE17Z256VLL7).

Table 14. OpenSDA interface signals

Input/Output headers

FRDM-KE17Z supports I/O headers compatible with the Arduino shields, the NXP FRDM-TOUCH board, and the NXP FRDM-MC-LVBLDC board. The following tables explain the pinouts for Arduino on FRDM-KE17Z.

Table 15. J2 connector (at left-upper side) pinouts for Arduino

Table 16. J1 connector (at right-upper side) pinouts for Arduino

Table 17. J3 connector (at left-lower side) pinouts for Arduino

Table 18. J4 connector (at right-lower side) pinouts for Arduino

Bluetooth
FRDM-KE17z supports 1×4 Bluetooth header, J19. J19 is connected to the MKE17Z256VLL7 through the LPUART1 interface. The following table shows the connections for the Bluetooth header Tx/Rx signals.

Table 19. Bluetooth header connections

Appendix A

Revision History

The table below summarizes the revisions to this document. Table 20. Revision history

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References

• Our Terms And Conditions Of Commercial Sale | NXP Semiconductors
• Support | NXP Semiconductors
• Power.org
• Our Terms And Conditions Of Commercial Sale | NXP Semiconductors
• Support | NXP Semiconductors
• PEmicro | Experts in Embedded tools for Flash Programming and Development
• MCUXpresso SDK | Software Development for Kinetis, LPC, and i.MX MCUs | NXP Semiconductors

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