WBZ351UE - Electronic component Microchip - Free user manual and instructions

USER MANUAL WBZ351UE Microchip

This user guide provides detailed information about using the Microchip Radio Test 3 tool (MCHPRT3) with the Microchip PIC32CX-BZ3. The MCHPRT3 enables the user to evaluate and demonstrate the RF performance, calibration and functionalities of the PIC32CX-BZ3.

Note: In this user guide, the MCHPRT3 tool with the PIC32 WBZ351 Curiosity Board is only shown as an example.

The MCHPRT3 is intended for development purposes. Any production test must use either a third-party production tool or users must develop their own production tool based on the MCHPRT3 CLI or DLL release.

Features

• DLL Version – DLL Information and Firmware Support Version
• COM PORT – COM Port Information and Configuration
• Baud Rate – 115200 (Default Value)
• RF Bluetooth ^ – Bluetooth Low Energy RF Parameter Configuration and Information
• RF ZB – Zigbee ^ RF Parameter Configuration and Information
  • MAC Address Information and Configuration
• IB File – Read or Save Information Block (IB) File
• Calibration Information and Configuration
  • GPIO Information and Configuration

For more details, refer to 4. Getting Started.

Table of Contents

Introduction ...... 1

Features 1

1. Quick References .... 3

1.1. Hardware Prerequisites....3
1.2. Software Prerequisites.... 3
1.3. Acronyms and Abbreviations....3

1. Overview....4
2. MPLAB X IDE HUT Code Programming Process 6
3. Getting Started....8

4.1. Getting Started with MCHPRT3....9
4.2. Getting Started with MCHPRT3 PIC32CX-BZ3 GUI 11
4.3. MCHPRT3 PIC32CX-BZ2 GUI Demonstration 12

1. Document Revision History....30

Microchip Information.... 31

The Microchip Website....31
Product Change Notification Service.... 31
Customer Support....31
Microchip Devices Code Protection Feature....31
Legal Notice....31
Trademarks....32
Quality Management System....33
Worldwide Sales and Service....34

1. Quick References

1.1 Hardware Prerequisites

• WBZ351 Curiosity Board, EV19J06A (PIC32CX-BZ3 programmed with HUT Firmware)
- USB-A to Micro USB cable
- Test Equipment
- Bluetooth Low Energy and Zigbee Tester (IQxel)

1.2 Software Prerequisites

Download the latest MCHPRT3 installer package, PIC32CX-BZ3 HUT X.X firmware and the corresponding tools from the Microchip website at www.microchip.com/MCHPRT.

• Windows OS (version to be confirmed)
• MCHPRT3 installer package (MCHPRT3_Setup_v1.0.0.XXXX.exe)
• MPLAB ^* X IDE v6.10 or above

1.3 Acronyms and Abbreviations

Table 1-1. Acronyms and Abbreviations

2. Overview

This section provides an overview of the MCHPRT3 tool setup and the components. Install the MCHPRT3_setup_v1.0.0.XXXX.exe tool. The MCHPRT3 tool installs by default in the C:\Microchip\ location.

The following table provides the MCHPRT3 tool package files:

Table 2-1. MCHPRT3 Tool Package Files

The following table provides the PIC32CX-BZ3 package files:

Table 2-2. PIC32CX-BZ3 Package Files

Figure 2-1. MCHPRT3 Package Contents

Note: The MCHPRT3 tool works efficiently only with the HUT firmware version that is packaged with the package.

3. MPLAB X IDE HUT Code Programming Process

In this demonstration, the user can program the HUT firmware to the PIC32CX-BZ3 device using a PC with the installed MPLAB Integrated Programming Environment (IPE).

Figure 3-1. MPLAB X IPE

Perform the following steps for HUT firmware programming:

1. Set up the connection between the WBZ351 Curiosity Board and PC. Refer to 4.1. Getting Started with MCHPRT3.

a. Start "MPLAB X IPE", then check for PIC32CX5109BZ31048 in the "Device" text box. If it is not there, check the USB connection (step 1).
b. Click Apply.
c. Click Browse to load the wbz351 hut.hex, which is the PIC32CX-BZ3 HUT X.X firmware.
d. Click Program, then wait one minute for the programming to complete.

Figure 3-2. MPLAB X IPE (Programming Complete)

1. The PIC32CX-BZ3 is programmed with the HUT X.X firmware and ready for the test using the PIC32CX-BZ3 MCHPRT3 tool.

4. Getting Started

This section describes how to use the MCHPRT3 GUI to test or calibrate the PIC32CX-BZ3 with the Bluetooth Low Energy and Zigbee tester.

The following figure illustrates the MCHPRT3 for PIC32CX-BZ3 GUI with the following components:

Figure 4-1. PIC32CX-BZ3 GUI

4.1 Getting Started with MCHPRT3

MCHPRT3 Package Features

• RF - RF Test for Bluetooth and Zigbee TX/RX
- Calibration – TX Calibration and RX Calibration
• MAC Address – Read/Write Bluetooth Address and Zigbee MAC Address
- IB (Information Block) File – Read/Save IB File to/from Buffer and Read/Commit IB Buffer to/from DUT
• GPIO - GPIO Test Command

Figure 4-2. MCHPRT3 Block Diagram

graph TD
    A["MCHPRT 3"] --> B["RF"]
    A --> C["MAC ADDRESS"]
    A --> D["IB File"]
    A --> E["Calibration"]
    A --> F["GPIO Test"]
    B --> G["BT TX/RX"]
    B --> H["Zigbee TX/RX"]
    C --> I["IB Buffer with File"]
    C --> J["IB Buffer with DUT"]
    H --> K["BT Address"]
    H --> L["Zigbee MAC Address"]

The following are the steps to launch the MCHPRT3 tool:

1. Double click MCHPRT3.exe in the directory: C:\Microchip\MCHPRT3_Setup_v1.0.0.XXXX; the following screen appears.

Figure 4-3. Start-Up Window of the MCHPRT3 Tool

1. From the "Select GUI" drop-down list, select PIC32CX-BZ3.
2. Click Open to launch the PIC32CX-BZ3 window (see the following figure).

Figure 4-4. PIC32CX-BZ3 GUI

Description of each component:

- Buttons on the top:

• Connect/Disconnect - Connects or disconnects the PIC32CX-BZ3
• Reset - Reset the PIC32CX-BZ3
• Refresh COM - Update the list of connected com port
• Cal. VCO - VCO calibration
• BUCK PWM - Switch the power mode into DC-DC (buck) mode
• PMU MLDO - Switch the power mode into MLDO mode
• Get FW Version – Obtain the firmware version from the sample
• Device ID - Select the appropriate part number that is connecting to the tool • For connecting the WBZ351 Module/PIC32CX5109BZ31048, select WBZ351

- For connecting the WBZ350 Module/PIC32CX5109BZ31032, select WBZ350

- Enable PKOB4 - Only needed to check if the user is using the WBZ350 Curiosity Board

- RF for Bluetooth and Zigbee – Settings of RF mode, channel and TX parameter for RF test

• BT - TX setting of payload, PHY (data rate), MPA/LPA (PA setting), Packet length and power step (Power Level). RX - number of RX packet
• Zigbee - TX settings of packet type, MPA/LPA (PA setting), power level, delay time between each packet and packet number. RX - setting of RX data rate and number of RX packet

- Calibration – Complete TX and RX calibration flow. The user can save calibration info to file or commit to NVM type Flash or OTP

• TX Calibration – Perform TX calibration flow to adjust transmitted power and output frequency to target
• RX Calibration – Perform RX calibration flow to obtain RX IQ, RSSI to corresponding received power and so on

- MAC Address – Read/write address

- Bluetooth address and Zigbee MAC address

• IB (Information Block) File

• Read IB file to IB buffer/save IB buffer to IB file
• Read DUT to IB buffer/commit IB buffer to DUT

- GPIO – Test GPIO for selected Port, Pin, In/Out and Level

• Start GPIO - Initialize GPIO for test
• GPIO Command - Execute GPIO test command for selected port, pin, in/out and level
• Stop GPIO - Stop GPIO test

4.2 Getting Started with MCHPRT3 PIC32CX-BZ3 GUI

Program the sample before using the MCHPRT3 tool. For more details on the HUT code programming process, refer to 3. MPLAB X IDE HUT Code Programming Process.

To run an RF test on the PIC32 WBZ351 Curiosity Board, perform the following procedure:

1. Connect the Micro USB in the Curiosity Board to the PC.
2. Check whether the jumper for the current measurement was inserted or not.
3. Run MCHPRT3.exe.
4. From the "Select GUI" drop-down list, select PIC32CX-BZ3.
5. Click Open to launch the PIC32CX-BZ3 window.
6. Select the respective "COM PORT" (check device manager in PC). A different USB-to-UART serial converter requires the corresponding driver; install accordingly.
7. Baud Rate - 115200 (default value)
8. Click Connect.
9. Click Reset to reset the device. The PIC32 WBZ351 Curiosity Board is ready for RF Test, Calibration and MAC Address Programming.

Figure 4-5. PIC32 WBZ351 Curiosity Board USB Connection

Figure 4-6. Current Measurement Jumper on PIC32 WBZ351 Curiosity Board

4.3 MCHPRT3 PIC32CX-BZ2 GUI Demonstration

4.3.1 Bluetooth RF Test Demonstration

In this demonstration, the user can transmit Bluetooth Low Energy packets, enter RX mode and Test mode with the PIC32CX-BZ3 by using the MCHPRT3.

Perform the following steps for the demonstration of the Bluetooth RF TX modulation test:

1. Set up the connection between the PIC32 WBZ351 Curiosity Board and PC. For more details, refer to 4.1. Getting Started with MCHPRT3.
2. In the RF BT tab, perform the following steps:

a. From the "RF Modes" drop-down list, select TX Mode.
b. From the "Channel" drop-down list, select 2402 MHz for channel 37.
c. From the "Payload" drop-down list, select PRBS9 (default value).
d. From the "PHY" drop-down list, select the Data Rate (1M,2M, S=2 and S=8), for example, select PHY 1M.
e. From the "Power" drop-down list, select the Output Power, for example, select 11dB.
f. From the "Packet Length" drop-down list, select the Packet Length (0-255), for example, 255 (default value).

1. Click START to transmit the Bluetooth Low Energy packet.

Figure 4-7. MCHPRT3 PIC32CX-BZ3 GUI for Bluetooth RF TX Modulation Test Demonstration

Perform the following steps for the demonstration of the Bluetooth RF RX mode:

1. Set up the connection between the PIC32 WBZ351 Curiosity Board and PC. For more details, refer to 4.1. Getting Started with MCHPRT3.
2. In the RF BT tab, perform the following steps:

a. From the "RF mode" drop-down list, select RX Mode.
b. From the "Channel" drop-down list, select 2402 MHz for channel 37.

1. Click START to receive the Bluetooth Low Energy packet. The number of received packets is shown in the drop-down list, "RX Packet".

Figure 4-8. MCHPRT3 PIC32CX-BZ3 GUI for Bluetooth RF RX Mode Demonstration

Perform the following steps for the demonstration of the Bluetooth RF CW tone test:

1. Set up the connection between the PIC32 WBZ451 Curiosity Board and PC. For more details, refer to 4.1. Getting Started with MCHPRT3.

2. In the RF BT tab, perform the following steps:

3. From the "RF Modes" drop-down list, select CW Mode.

4. From the "Channel" drop-down list, select 2402 MHz for channel 37.

5. From the "Power" drop-down list, select the Output Power, for example, select 11 dB.

6. Click START to transmit the CW tone at the selected channel.

Figure 4-9. MCHPRT3 PIC32CX-BZ3 GUI for Bluetooth RF CW Mode Demonstration

Perform the following steps for the demonstration of the Bluetooth Low Energy Test mode:

1. For the Bluetooth Low Energy Test mode, the sample must contain the following connection:

2. HCI_TXD (PA5 from the module)

3. HCI_RXD (PA6 from the module)
4. VDD (connect with external power supply)

5. Ground

6. Use the USB-to-UART serial converter to make the connection between the sample and PC by connecting the HCI_TXD, HCI_RXD and ground with the converter.

7. Power the sample with 3.3V supply.
8. Select the respective COM PORT (the COM port with the converter) in MCHPRT3.
9. In the RF BT tab, perform the following steps:

a. From the "RF mode" drop-down list, select Test Mode.

1. Click START to enter the Bluetooth test mode, then click Disconnect in the GUI. Disconnect the UART interface from the DUT while keeping the power supply, then connect it with the Bluetooth tester.

Figure 4-10. MCHPRT3 PIC32CX-BZ3 GUI for Bluetooth Test Mode Connecting with Bluetooth Tester Demonstration

Perform the following steps for the demonstration of the Bluetooth Low Energy adaptivity frequency hopping (AFH) packet transmission:

1. Set up the connection between the PIC32 WBZ351 Curiosity Board and PC. For more details, refer to 4.1. Getting Started with MCHPRT3.

2. In the RF BT tab, perform the following steps:

a. From the "RF mode" drop-down list, select AFH Mode.
b. From the "Payload" drop-down list, select PRBS9 (default value).
c. From the "PHY" drop-down list, select the Data Rate (1M,2M, S=2 and S=8), for example, select PHY 1M.
d. From the "RF mode" drop-down list, select the Output Power, for example, select 11 dB.

e. From the "Packet Length" drop-down list, select the Packet Length (0-255), for example, 255 (default value).

1. Click START to transmit the Bluetooth Low Energy packet with adaptivity frequency hopping.

Figure 4-11. MCHPRT3 PIC32CX-BZ3 GUI for Bluetooth Adaptivity Frequency Hopping (AFH) TX Test Demonstration

4.3.2 Zigbee RF Test Demonstration

In this demonstration, the user can transmit Zigbee packets, enter RX mode and CW mode with the PIC32CX-BZ3 by using the MCHPRT3.

Perform the following steps for the demonstration of the Zigbee packet transmission:

1. Set up the connection between the PIC32 WBZ351 Curiosity Board and PC. For more details, refer to 4.1. Getting Started with MCHPRT3.

2. In the RF ZB tab, perform the following steps:

a. From the "RF Modes" drop-down list, select TX Mode.
b. From the "Channel" drop-down list, select 2405 MHz for channel 11.

c. From the "Packet Type" drop-down list, select Packet Type as General (default value) or Smallest.
d. From the "Power Level" drop-down list, select Level 0.

Note: Level 0: Uncalibrated maximum transmit power from the device, i.e., the output power would be varied between devices. This Level 0 is provided only for testing purpose. For calibrated power level, Level 1 (11 dBm) to Level 15 (-3 dBm), 1 dBm power step per level.

e. From the "Delay Time" drop-down list, select the Packet Delay Time (00-250) (the default value is 10).
f. From the "Packet Number" drop-down list, select the Number of Transmitting Packet (00-250) (the default value is 00, Continuous Packet Transmission).

3. Click START to transmit the Zigbee packet.

Note: The "Data Rate" must be set at 250 Kbps, and the "Delay Time" must be 10 for the standard Zigbee packet stream.

Figure 4-12. MCHPRT3 PIC32CX-BZ3 GUI for Zigbee RF TX Modulation Test Demonstration

Perform the following steps for the demonstration of the Zigbee RX mode:

1. Set up the connection between the PIC32 WBZ351 Curiosity Board and PC. For more details, refer to 4.1. Getting Started with MCHPRT3.

2. In the RF ZB tab, perform the following steps:

a. From the "RF Modes" drop-down list, select RX Mode.
b. From the "Channel" drop-down list, select 2405 MHz for channel 11.
c. From the "RX Data Rate" drop-down list, select Data Rate (250K, 500K, 1M and 2M), for example, select 250K.

1. Click START to receive the Zigbee packet. The total number of received packets are available under the "RX Packet" drop-down list.

Figure 4-13. MCHPRT3 PIC32CX-BZ3 GUI for Zigbee RF RX Mode Demonstration

Perform the following steps for the demonstration of the Zigbee CW mode to transmit CW tone:

1. Set up the connection between the PIC32 WBZ351 Curiosity Board and PC. For more details, refer to 4.1. Getting Started with MCHPRT3.

2. In the RF ZB tab, perform the following steps:

a. From the "RF mode" drop-down list, select CW Mode.

b. From the "Channel" drop-down list, select 2405 MHz for channel 11.
c. From the "Power Level" drop-down list, select Level 0.

3. Click START to transmit the CW tone.

Figure 4-14. MCHPRT3 PIC32CX-BZ3 GUI for Zigbee CW Mode Demonstration

ED Mode, LQI Mode, CCA Mode, TX to RX mode and RX to TX mode, as well as the area of ZB CERT are used in Zigbee PHY certification.

• ED mode: This mode is for Zigbee PHY test item: TP/154/PHY/RECEIVE-06, which is a test for the DUT is capable of reporting Energy Detection (ED) values with the proper monotonicity and linearity requirements. Due to the limit on the ED value register, the range of ED value shows in MCHPRT3 would not be the same as the request of Zigbee PHY test plan. It is accepted to give another ED value with the same requested received power range. In our Zigbee PHY certification, ED value would be 16 for -76 dBm and 56 to 57 for -36 dBm received power.
  Note: ED value could be converted into RSSI by this formula: RSSI = ED value -94

- LQI mode: This mode is for Zigbee PHY test item: TP/154/PHY/RECEIVE-07, which is a test for the DUT capable of reporting Link Quality Indicator (LQI).

- CCA mode: This mode is for Zigbee PHY test item: TP/154/PHY/RECEIVE-08, which is a test for the DUT capable of reporting on channel traffic by at least 1 of the 3 Clear Channel Assessment (CCA) methods (modes) at the CCA ED Threshold specified in the Zigbee PHY test plan.

- TX to RX mode: This is for Zigbee PHY test item: TP/154/PHY/TURNAROUND-TIME-02, which is a test for the DUT that has a TX-to-RX turnaround time less than or equal to the TX-to-RX Turnaround Time specified in the Zigbee PHY test plan.

- RX to TX mode: This is for Zigbee PHY test item: TP/154/PHY/TURNAROUND-TIME-01, which is a test for the DUT that has a RX-to-TX turnaround time that meets the RX-to-TX Turnaround Time specified in the Zigbee PHY test plan.

Figure 4-15. MCHPRT3 PIC32CX-BZ3 GUI for Zigbee PHY Test

4.3.3 Calibration Flow Demonstration

In this demonstration, the user can calibrate TX parameters and RX parameters of the PIC32CX-BZ3 using a PC with the installed MCHPRT3 tool. The calibration step could be checked in the "Cal. Flow Status" in the Calibration page.

Perform the following steps for the demonstration of the calibration flow (see the following figure):

1. Set up the connection between the PIC32 WBZ351 Curiosity Board and PC. For more details, refer to 4.1. Getting Started with MCHPRT3.
2. Connect the u.FL connector on the PIC32CX-BZ3 to the Bluetooth/Zigbee tester (IQxel or others) to measure the RF power from the PIC32CX-BZ3.
3. Check the cable loss between the PIC32CX-BZ3 u.FL connector to the Bluetooth/Zigbee tester.
4. MLDO is the preferred mode of calibration. Click PMU MLDO to use the MLDO mode to perform calibration.

CAUTION

OTP is limited in memory of 4k, and it can only be calibrated 10 to 15 times.

1. Click Start Cal. to start the new calibration.
2. Click VTA Cal in Cal. step 1. VTA and wait for done.
3. Click Freq. Start in Cal. step 2. Freq., the DUT transmits the Bluetooth Low Energy packet at 2440 MHz.
4. Check the carrier frequency at the tester, then click Freq. decrease or Freq. increase to change the carrier frequency.
5. When the carrier frequency is close to 2440 MHz with +/-4 ppm, click Freq. Done.
6. Click IQ Cal. Start. in Cal. step 2. RX IQ.
7. Generate 2424 MHz CW tone from the test equipment at -50 dBm including cable loss by using the tester, then feed it into DUT and click IQ -50 Tune.
8. Generate 2426 MHz CW tone from the test equipment at -50 dBm including cable loss by using the tester, then click IQ Main Tune.
9. If IQ Cal. in step 11 and 12 are not a success, MCHPRT3 would require repeating IQ Cal. with -40 dBm or -30 dBm 2424 MHz and 2426 MHz CW tone by using the tester. Click IQ -40 Tune or IQ -30 Tune to repeat the step.
10. Click IQ Cal. Done.
11. Click TX P1 Start in Cal. step 4. RF TX, enter the power level shown in the tester with the cable loss, then click TX P1 Tune.
12. Click TX P2 Start in Cal. step 4. RF TX, enter the power level shown in the tester with the cable loss, then click TX P2 Tune.
13. Click TX P3 Start in Cal. step 4. RF TX, enter the power level shown in the tester with the cable loss, then click TX P3 Tune.
14. Click TX P4 Start in Cal. step 4. RF TX, enter the power level shown in the tester with the cable loss, then click TX P4 Tune.
15. Click TX P5 Start in Cal. step 4. RF TX, enter the power level shown in the tester with the cable loss, then click TX P5 Tune.
16. Click TX P6 Start in Cal. step 4. RF TX, enter the power level shown in the tester with the cable loss, then click TX P6 Tune.

17. Click ED Cal. Init., generate 2440 MHz CW tone at -70 dBm including cable loss by using the tester ED Cal. Trim in Cal. step 5. ED.

18. Click ED Cal. Done.

19. Click Save Cal. Data in Cal. step 6. Save data to save the calibration data into the file and the DUT.

Figure 4-16. MCHPRT3 PIC32CX-BZ3 GUI for Calibration Flow Demonstration

Figure 4-17. Calibration Setup

graph LR
    A["PC\nMCHPRT 3 installed"] <-->|UART| B["DUT\nE.g. PIC32 WBZ351 Curiosity Board"]
    B <-->|RF Cable| C["Tester\nBT/Zigbee tester, E.g. IQxel"]

4.3.4 Operation on IB (Information Block) File

Figure 4-18. MCHPRT3 PIC32CX-BZ3 GUI for IB (Information Block) File Operation

The user can perform the following in the IB File tab:

• Read the IB (1) File to IB Buffer(2).
• Save IB Buffer into the IB File.
• From the "IB Type" drop-down list, select Flash (default value).
• Read the IB from DUT into the IB Buffer.
• Commit the IB Buffer into DUT – the IB is stored in the Flash.

Note:

1. Use the Information Block (IB) to store various types of calibration and system configuration information.
2. The IB Buffer is a temporary PC location for the Information Block (IB).

4.3.5 MAC Address Programming

In this demonstration, the user can set the Bluetooth Address and Zigbee MAC Address of the PIC32CX-BZ3 using a PC with the MCHPRT3 tool installed.

In the MAC Address tab, perform the following steps for MAC Address programming:

1. From the IB Type drop-down list, select Flash (default value).
2. To read the Bluetooth address from the IB, click Read BT Addr from IB.
3. To write the Bluetooth address:

a. Click Write BT Addr to IB Buffer.

b. Click Commit BT Addr IB Buffer to IB.

1. To read the Zigbee MAC address from IB, click Read ZB Addr from IB.

2. To write Zigbee MC address:

a. Click Write ZB Addr to IB Buffer.
b. Click Commit ZB Addr IB Buffer to IB.

It is recommended to write all the calibration parameters into Flash during the initial calibration. After confirming the correct calibration and MAC address, write them into OTP memory.

Figure 4-19. MCHPRT3 PIC32CX-BZ3 GUI for MAC Address Programming

4.3.6 GPIO Demonstration

In this demonstration, the user can configure or test the GPIO of the PIC32CX-BZ3 using a PC with the installed MCHPRT3 tool.

In the GPIO tab, perform the following steps for the GPIO demonstration (see the following figure):

1. Click Start GPIO Test to initiate the GPIO settings for configuration or test.
2. Select "Port", "Pin", "In/Out" and "Level" to configure or test the GPIO pins.
3. Click Run to apply the GPIO configuration.
4. Repeat step 2 and 3 to perform a new GPIO configuration or test.
5. Click Stop GPIO Test to stop the GPIO settings for configuration or test.
6. Check the checkbox on each item to perform multiple GPIO configurations. Click Run All Select GPIO to apply all the selected GPIO configuration.

Figure 4-20. MCHPRT3 PIC32CX-BZ3 GUI GPIO Demonstration

5. Document Revision History

Table 5-1. The document revision history describes the changes that were implemented in the document. The changes are listed by revision, starting with the most current publication.

Microchip Information

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The Microchip name and logo, the Microchip logo, Adaptec, AVR, AVR logo, AVR Freaks, BesTime, BitCloud, CryptoMemory, CryptoRF, dsPIC, flexPWR, HELDO, IGLOO, JukeBlox, KeeLoq, Kleer, LANCheck, LinkMD, maXStylus, maXTouch, MediaLB, megaAVR, Microsemi, Microsemi logo, MOST, MOST logo, MPLAB, OptoLyzer, PIC, picoPower, PICSTART, PIC32 logo, PolarFire, Prochip Designer, QTouch, SAM-BA, SenGenuity, SpyNIC, SST, SST Logo, SuperFlash, Symmetricom, SyncServer, Tachyon, TimeSource, tinyAVR, UNI/O, Vectron, and XMEGA are registered trademarks of Microchip Technology Incorporated in the U.S.A. and other countries.

AgileSwitch, ClockWorks, The Embedded Control Solutions Company, EtherSynch, Flashtec, HyperSpeed Control, HyperLight Load, Libero, motorBench, mTouch, Powermite 3, Precision Edge, ProASIC, ProASIC Plus, ProASIC Plus logo, Quiet-Wire, SmartFusion, SyncWorld, TimeCesium, TimeHub, TimePictra, TimeProvider, and ZL are registered trademarks of Microchip Technology Incorporated in the U.S.A.

Adjacent Key Suppression, AKS, Analog-for-the-Digital Age, Any Capacitor, AnyIn, AnyOut, Augmented Switching, BlueSky, BodyCom, Clockstudio, CodeGuard, CryptoAuthentication, CryptoAutomotive, CryptoCompanion, CryptoController, dsPICDEM, dsPICDEM.net, Dynamic Average Matching, DAM, ECAN, Espresso T1S, EtherGREEN, EyeOpen, GridTime, IdealBridge, IGaT, In-Circuit Serial Programming, ICSP, INICnet, Intelligent Paralleling, IntelliMOS, Inter-Chip Connectivity, JitterBlocker, Knob-on-Display, MarginLink, maxCrypto, maxView, memBrain, Mindi, MiWi, MPASM, MPF, MPLAB Certified logo, MPLIB, MPLINK, mSiC, MultiTRAK, NetDetach, Omniscient Code Generation, PICDEM, PICDEM.net, PICkit, PICtail, Power MOS IV, Power MOS 7, PowerSmart, PureSilicon, QMatrix, REAL ICE, Ripple Blocker, RTAX, RTG4, SAM-ICE, Serial Quad I/O, simpleMAP, SimpliPHY, SmartBuffer, SmartHLS, SMART-I.S., storClad, SQL, SuperSwitcher, SuperSwitcher II, Switchtec, SynchroPHY, Total Endurance, Trusted Time, TSHARC, Turing, USBCheck, VariSense, VectorBlox, VeriPHY, ViewSpan, WiperLock, XpressConnect, and ZENA are trademarks of Microchip Technology Incorporated in the U.S.A. and other countries.

SQTP is a service mark of Microchip Technology Incorporated in the U.S.A.

The Adaptec logo, Frequency on Demand, Silicon Storage Technology, and Symmcom are registered trademarks of Microchip Technology Inc. in other countries.

GestIC is a registered trademark of Microchip Technology Germany II GmbH & Co. KG, a subsidiary of Microchip Technology Inc., in other countries.

All other trademarks mentioned herein are property of their respective companies.

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