HV2818 - Carte d'évaluation Microchip - Free user manual and instructions

USER MANUAL HV2818 Microchip

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

APT, ClockWorks, The Embedded Control Solutions Company, EtherSynch, FlashTec, Hyper Speed Control, HyperLight Load, IntelliMOS, Libero, motorBench, mTouch, Powermite 3, Precision Edge, ProASIC, ProASIC Plus, ProASIC Plus logo, Quiet-Wire, SmartFusion, SyncWorld, Temux, TimeCesium, TimeHub, TimePictra, TimeProvider, Vite, WinPath, 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, BlueSky, BodyCom, CodeGuard, CryptoAuthentication, CryptoAutomotive, CryptoCompanion, CryptoController, dsPICDEM, dsPICDEM.net, Dynamic Average Matching, DAM, ECAN, EtherGREEN, In-Circuit Serial Programming, ICSP, INICnet, Inter-Chip Connectivity, JitterBlocker, KleerNet, KleerNet logo, memBrain, Mindi, MiWi, MPASM, MPF, MPLAB Certified logo, MPLIB, MPLINK, MultiTRAK, NetDetach, Omniscient Code Generation, PICDEM, PICDEM.net, PICkit, PICtail, PowerSmart, PureSilicon, QMatrix, REAL ICE, Ripple Blocker, SAM-ICE, Serial Quad I/O, SMART-I.S., SQI, SuperSwitcher, SuperSwitcher II, Total Endurance, TSHARC, USBCheck, VariSense, ViewSpan, WiperLock, Wireless DNA, 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.

© 2020, Microchip Technology Incorporated, All Rights Reserved.

ISBN: 978-1-5224-6286-6

For information regarding Microchip's Quality Management Systems, please visit www.microchip.com/quality.

Table of Contents

Preface 5

Introduction......5

Document Layout 5

Conventions Used in this Guide 6

Recommended Reading....7

The Microchip Website....7

Product Change Notification Service....7

Customer Support 7

Document Revision History 7

Chapter 1. Product Overview ...... 9

1.1 Introduction 9

1.2 HV2918 Device Short Overview 9

1.3 HV2918 Analog Switch Evaluation Board Features 9

1.4 What is the HV2918 Analog Switch Evaluation Board? 10

1.5 HV2918 Analog Switch Evaluation Board Technical Parameters 10

1.6 HV2918 Analog Switch Evaluation Board Kit Contents 11

Chapter 2. Installation and Operation .... 13

2.1 Getting Started 13

2.1.1 Additional Tools Required for Operation 13

2.2 HV MUX GUI Installation 13

2.3 HV2918 Analog Switch Evaluation Board Setup Procedure 17

2.3.1 Recommended Power-up and Power-Down Sequences 18

2.4 Interface Connections 19

2.5 HV MUX Controller Board Setup Procedure 20

2.6 Testing the HV2918 Analog Switch Evaluation Board 21

2.7 Generation of Pulser Output at SW7 of HV2918 21

Chapter 3. GUI Description ...... 23

3.1 HV2918 Analog Switch Evaluation Board GUI Description 23

Chapter 4. PCB Design and Layout Notes.... 25

4.1 PCB Layout Techniques for HV2918 25

4.1.1 High-Voltage and High-Speed Grounding and Layout Techniques ..... 25

4.1.2 Decoupling Capacitors Selection 25

Appendix A. Schematics and Layouts 27

A.1 Introduction 27

A.2 EV19W62A – Schematic 28

A.3 EV19W62A – Schematic (Output Connectors) 29

HV2918 Analog Switch Evaluation Board User's Guide

A.4 EV19W62A – Schematic (Power) 30

A.5 EV19W62A – Schematic (Pulse Generator) 31

A.6 EV19W62A – Schematic (SPI Flash) 32

A.7 EV19W62A – Top Silk 33

A.8 EV19W62A – Top Copper and Silk 33

A.9 EV19W62A – Top Copper 34

A.10 EV19W62A – Inner 1 and 4 34

A.11 EV19W62A – Inner 2 35

A.12 EV19W62A – Inner 3 35

A.13 EV19W62A – Bottom Copper 36

A.14 EV19W62A – Bottom Copper and Silk 36

A.15 EV19W62A – Bottom Silk 37

A.16 ADM00825 – Schematic (Connection) 38

A.17 ADM00825 – Schematic (Power Supply) 39

A.18 ADM00825 – Schematic (USB to SPI) 40

A.19 ADM00825 – Schematic (Programmable Clock) 41

A.20 ADM00825 – Schematic (FPGA) 42

A.21 ADM00825 – Schematic (FPGA Decoupling Capacitors) 43

A.22 ADM00825 – Schematic (Connectors) 44

A.23 ADM00825 – Top Silk 45

A.24 ADM00825 – Top Copper and Silk 45

A.25 ADM00825 – Top Copper 46

A.26 ADM00825 – Inner 1 46

A.27 ADM00825 – Inner 2 .... 47

A.28 ADM00825 – Inner 3 47

A.29 ADM00825 – Inner 4 48

A.30 ADM00825 – Bottom Copper 48

A.31 ADM00825 – Bottom Copper and Silk 49

A.32 ADM00825 – Bottom Silk 49

Appendix B. Bill of Materials (BOM) 51

B.1 HV2918 Analog Switch Evaluation Board – BOM 51

B.2 HV MUX Controller Board – BOM 54

Appendix C. Demo Board Waveforms....59

C.1 Board Typical Waveforms 59

Worldwide Sales and Service 60

Preface

NOTICE TO CUSTOMERS

All documentation becomes dated, and this manual is no exception. Microchip tools and documentation are constantly evolving to meet customer needs, so some actual dialogs and/or tool descriptions may differ from those in this document. Please refer to our website (www.microchip.com) to obtain the latest documentation available.

Documents are identified with a "DS" number. This number is located on the bottom of each page, in front of the page number. The numbering convention for the DS number is "DSXXXXXXXXA", where "XXXXXXXXX" is the document number and "A" is the revision level of the document.

For the most up-to-date information on development tools, see the MPLAB ^® IDE online help. Select the Help menu, and then Topics, to open a list of available online help files.

INTRODUCTION

This chapter contains general information that will be useful to know before using the HV2918 Analog Switch Evaluation Board. Items discussed in this chapter include:

• Document Layout
  • Conventions Used in this Guide
  •
  • Recommended Reading
  • The Microchip Website
• Customer Support
  • Document Revision History

DOCUMENT LAYOUT

This document describes how to use the HV2918 Analog Switch Evaluation Board as a development tool to emulate and debug firmware on a target board. The manual layout is as follows:

• Chapter 1. "Product Overview" – Important information about the HV2918 device.
• Chapter 2. “Installation and Operation” – This chapter includes instructions for how to begin using the HV2918 Analog Switch Evaluation Board.
• Chapter 3. "GUI Description" – This chapter describes the features of the GUI PC software.
• Chapter 4. "PCB Design and Layout Notes" – This chapter explains important points of the PCB design of the HV2918 Analog Switch Evaluation Board.
• Appendix A. "Schematic and Layouts" – Shows the schematic and layout diagrams for the HV2918 Analog Switch Evaluation Board.
• Appendix B. "Bill of Materials (BOM)" – Lists the parts used to build the HV2918 Analog Switch Evaluation Board.
• Appendix C. "Demo Board Waveforms" – Describes the various demo waveforms for the HV2918 Analog Switch Evaluation Board.

CONVENTIONS USED IN THIS GUIDE

This manual uses the following documentation conventions:

DOCUMENTATION CONVENTIONS

RECOMMENDED READING

This user's guide describes how to use the HV2918 Analog Switch Evaluation Board. Other useful documents are listed below. The following Microchip document is available and recommended as a supplemental reference resource:

HV2818/HV2918 Data Sheet – “No High-Voltage Bias, Low Harmonic Distortion, 32-Channel, High-Voltage Analog Switch” (DS20006375)

THE MICROCHIP WEBSITE

Microchip provides online support via our website at www.microchip.com. This website is used as a means to make files and information easily available to customers. Accessible by using your favorite Internet browser, the website contains the following information:

• Product Support – Data sheets and errata, application notes and sample programs, design resources, user's guides and hardware support documents, latest software releases and archived software
• General Technical Support – Frequently Asked Questions (FAQs), technical support requests, online discussion groups, Microchip consultant program member listing
• Business of Microchip – Product selector and ordering guides, latest Microchip press releases, listing of seminars and events, listings of Microchip sales offices, distributors and factory representatives

PRODUCT CHANGE NOTIFICATION SERVICE

Microchip's customer notification service helps keep customers current on Microchip products. Subscribers will receive e-mail notifications whenever there are changes, updates, revisions or errata related to a specified product family or development tool of interest.

To register, access the Microchip website at www.microchip.com, click on Product Change Notification and follow the registration instructions.

CUSTOMER SUPPORT

Users of Microchip products can receive assistance through several channels:

• Distributor or Representative
- Local Sales Office
• Field Application Engineer (FAE)
- Technical Support

Customers should contact their distributor, representative or field application engineer (FAE) for support. Local sales offices are also available to help customers. A listing of sales offices and locations is included in the back of this document.

Technical support is available through the website at: http://www.microchip.com/support.

DOCUMENT REVISION HISTORY

Revision A (June 2020)

- Initial Release of this Document.

NOTES:

Chapter 1. Product Overview

1.1 INTRODUCTION

The HV2918 Analog Switch Evaluation Board (EV19W62A) works with the Microchip HV MUX Controller Board (ADM00825) to provide no high-voltage bias, low harmonic distortion, 32-channel, high-voltage analog switch demonstration, including basic switch on/off operation. The boards also include 2:1 MUX operation to transmit ±100V high-voltage pulse burst from two built-in MD1822 and TC6320 pulser circuits.

1.2 HV2918 DEVICE SHORT OVERVIEW

The HV2918 device is a no high-voltage bias, low harmonic distortion, 32-channel (16 2:1 MUX), high-voltage analog switch (with bleed resistors in SW pins). It is designed to be used in applications requiring high-voltage switching, controlled by low-voltage control signals, such as medical ultrasound imaging, driving piezoelectric transducers and in printers. The typical 6Ω on-resistance analog switch can pass the analog pulsed signal up to ±2.7A of current, ±100V of voltage and 2.5 μs of pulse width without high-voltage supplies, such as ±100V. It requires only a +5V single bias voltage supply of V DD and V LL for the on/off switch operation. The user can also use +3.3V instead of +5V in the Logic Voltage, V _LL , in order to get lower power consumption.

The HV2918 device has a digital serial interface to control the 32 analog switches individually. The digital interface clock operates up to 66 MHz.

HV2918 has an asymmetric topology to implement small size, compared to other no high-voltage bias analog switch products. In the asymmetric topology, the SW pin can pass a high-voltage pulsed signal, applied to the Y pin, when the switch is in the ON state. When the switch is in the OFF state, high voltage should not be applied to the SW pin. In medical ultrasound systems, the Y pin is connected to Tx/Rx and the SW pin is connected to a single piezoelectric transducer element in order to avoid high-voltage at the SW pin during the switch OFF state.

1.3 HV2918 ANALOG SWITCH EVALUATION BOARD FEATURES

• HV2918 No High-Voltage Bias, Low Harmonic Distortion, 32-Channel, (16 2:1 MUX), High-Voltage Analog Switch (with Bleed Resistors in SW Pins)
- Designed to work with the Microchip HV MUX Controller Board (ADM00825)
- Two 2:1 MUX with built-in MD1822 and TC6320 Pulsers
• 5 MHz 3-Level High-Voltage Pulse Burst Outputs
- On-Board 330 pF//2.5 kΩ Dummy Load per SW6, SW7, SW24, SW25 Pins
- Pulser On/Off and Time Domain Control through the PC GUI and the HV MUX Controller Board

1.4 WHAT IS THE HV2918 ANALOG SWITCH EVALUATION BOARD?

The HV2918 Analog Switch Evaluation Board can control the HV2918 device and built-in pulsers that are connected to the two 2:1 MUX switches for demonstration through the HV MUX Controller Board and GUI. Four switch outputs (SW pins) from two 2:1 MUXes have SMA connectors to which the user can connect four transducer elements. The other side of the 2:1 MUX (Y pins) is connected to the outputs of two built-in MD1822 and TC6320 pulsers. The HV2918 Analog Switch Evaluation Board can drive four transducer elements with 5 MHz, ±100V pulse signals.

The HV2918 Analog Switch Evaluation Board features one HV2918/R4X 9 x 9 x 0.9 mm 64-lead VQFN packaged integrated circuit, two MD1822K6-G 3 x 3 x 1 mm 16-lead QFN packaged integrated circuits and four TC6320K6-G 4 x 4 x 1 mm 8-lead DFN packaged NMOS and PMOS paired integrated circuits.

The HV2918 Analog Switch Evaluation Board uses two high-speed 20-signal pairs, carrying capable right angle backplane connectors, which are designed to work with the HV MUX Controller Board as a control signal source.

The HV MUX Controller Board has an FPGA that generates pulser waveform and logic control signals, and a USB bridge IC that connects the control board to a PC. By using a Microsoft® Windows® operated PC and the GUI software, the user can control the HV2918 device and two built-in pulsers on the HV2918 Analog Switch Evaluation Board.

Four switch terminals, consisting of two 2:1 MUX configurations on the PCB, have SMA connectors to which the user can connect loads. The jumpers close to the SMA connectors are for connecting the on-board dummy R-C load (330 pF//2.5 kΩ) optionally to the pulser output.

WARNING

Risk warning of electrical shock. This board uses multiple hazardous high voltages. Disconnect all high-voltage supplies before working on it. Electrical safety precautions must be taken when working on or using this board.

1.5 HV2918 ANALOG SWITCH EVALUATION BOARD TECHNICAL PARAMETERS

TABLE 1-1: HV2918 ANALOG SWITCH EVALUATION BOARD TECHNICAL PARAMETERS

FIGURE 1-1: HV2918 ANALOG SWITCH EVALUATION BOARD SIMPLIFIED BLOCK DIAGRAM

graph TD
    PC["PC + GUI"] --> FPGA["FPGA"]
    FPGA -->|A1| CH1["Pulser MD1822 + TC6320"]
    FPGA -->|B1| CH1
    FPGA -->|DMP1| CH1
    FPGA -->|A2| CH2["Pulser MD1822 + TC6320"]
    FPGA -->|B2| CH2
    FPGA -->|DMP2| CH2
    HV2918["HV2918"] -->|Y67| SW6["SW6"]
    HV2918 -->|Y2425| SW7["SW7"]
    HV2918 -->|SW24| SW25["SW25"]
    HV2918 -->|SW6| 330pF["330 pF"]
    HV2918 -->|SW7| 330pF["330 pF"]
    HV2918 -->|SW24| 330pF["330 pF"]
    HV2918 -->|SW25| 330pF["330 pF"]
    HV2918 -->|SW6| 2.5kΩ[2.5 kΩ]
    HV2918 -->|SW7| 2.5kΩ[2.5 kΩ]
    HV2918 -->|SW24| 2.5kΩ[2.5 kΩ]
    HV2918 -->|SW25| 2.5kΩ[2.5 kΩ]

1.6 HV2918 ANALOG SWITCH EVALUATION BOARD KIT CONTENTS

The HV2918 Analog Switch Evaluation Board includes:

• HV2918 Analog Switch Evaluation Board (EV19W62A)
• Important Information Sheet

NOTES:

Chapter 2. Installation and Operation

2.1 GETTING STARTED

The HV2918 Analog Switch Evaluation Board is fully assembled and tested. The board requires five power supply voltage rails of +3.3V, +5V, +10V and ±100V.

2.1.1 Additional Tools Required for Operation

1. An oscilloscope with a minimum of 500 MHz bandwidth and two high-impedance probes. Make sure the grounds of the power supply sources are correctly connected to the same ground as the testing oscilloscope ground.
2. A Microchip HV MUX Controller Board (ADM00825).
3. A Microsoft ^ Windows ^ 7 PC with the HV MUX Controller Board GUI software installed and running.
4. J1 and J2 connected to the HV MUX Controller Board.
5. HV MUX Controller Board connected through the USB port to the PC.

2.2 HV MUX GUI INSTALLATION

The HV MUX GUI software installer can be downloaded from the Microchip website at www.mircochip.com. Search for the evaluation board on the website by the part number: EV19W62A.

1. Open the HVMUXGUI-v1.0.0-windows-installer.exe.
2. Initiate the HV MUX GUI software installer by launching the Application Install dialog box.

FIGURE 2-1: HV MUX GUI – APPLICATION INSTALL DIALOG BOX

1. Click Next to start the installation.

FIGURE 2-2: HV MUX GUI – LICENSE AGREEMENT DIALOG BOX

1. Read the License Agreement and accept it by checking the box corresponding to "I accept the agreement". Click Next to proceed with the installation.

FIGURE 2-3: HV MUX GUI – INSTALLATION DIRECTORY DIALOG BOX

1. On the Installation Directory dialog box, browse for the desired location or click Next to install in the default location.

FIGURE 2-4: HV MUX GUI – READY TO INSTALL DIALOG BOX

1. Once the installation path is chosen, the software is ready to install. Click Next.

FIGURE 2-5: HV MUX GUI – INSTALLATION STATUS DIALOG BOX

1. The Installation Status window appears, showing the installation progress.
2. After the installation has completed, click Next.

FIGURE 2-6: HV MUX GUI – INSTALLATION COMPLETE DIALOG BOX

1. Once the Installation Complete dialog box appears, click the Finish button to exit the installer.

2.3 HV2918 ANALOG SWITCH EVALUATION BOARD SETUP PROCEDURE

To operate the HV2918 Analog Switch Evaluation Board, the following steps must be completed:

1. Attach the HV2918 Analog Switch Evaluation Board to the HV MUX Controller Board (ADM00825) with the J1 and J2 connectors.
2. Connect all the jumpers on J43, J44, J45 and J46 for the on-board R-C load.
3. Connect all the power supplies to the voltage supply input connectors J4 and J5, as indicated in Table 2-1, by observing the polarity.

CAUTION

Observe the polarity of each power supply rail and set the voltage and current limit carefully.

1. Turn on the V_LL first and then turn on the V_DD .
2. Turn on the 3V3.
3. Turn on the V GP and V PP/V NN.
4. Connect a USB cable from the HV MUX Controller Board to the PC.
5. Connect +12V/1A power to the HV MUX Controller Board.
6. Run the HV MUX GUI software on the PC.
7. Click the Initialize HV MUX Controller button in the GUI. This causes the status window at the bottom of the screen to display an "Initialization Complete" message.
8. Clear the STBY check box and select the MODE check box. (Do not change these states. Not used for the HV2918 Analog Switch Evaluation Board.)
9. Click the Set HV MUX button. All digital control signals are applied to the HV2918 device.
10. Set the number of pulses and T_OFF time of the pulser.
11. Select CH1 or CH2 to set the Channel 1 pulser or the Channel 2 pulser, respectively.
12. Click the Start button for the selected pulser to generate pulse bursts.
13. Click the Stop button for the selected pulser to stop generating pulse bursts.

TABLE 2-1: POWER SUPPLY VOLTAGES AND CURRENT-LIMITED SETTINGS

FIGURE 2-7: HV2918 ANALOG SWITCH EVALUATION BOARD FRONT VIEW

2.3.1 Recommended Power-up and Power-Down Sequences

Table2-2 shows the recommended power-up and power-down sequences of the HV2918 Analog Switch Evaluation Board.

TABLE 2-2: HV2918 ANALOG SWITCH EVALUATION BOARD POWER-UP AND POWER-DOWN SEQUENCES

2.4 INTERFACE CONNECTIONS

TABLE 2-3: J2 CONTROL INTERFACE SIGNALS

2.5 HV MUX CONTROLLER BOARD SETUP PROCEDURE

The HV MUX Controller Board generates 3.3V control signals for the HV2918 Analog Switch Evaluation Board and features a Spartan-6 XC6SLX9 FPGA.

1. Before powering up the HV2918 Analog Switch Evaluation Board and the HV MUX Controller Board, make sure that the latest GUI software is installed on the PC.
2. Start the GUI program. If the board is not connected, a "Not Connected" message is displayed in the Status bar, located at the bottom left of the screen.
3. Connect the appropriate power supply and turn on the power switch to power-up the HV MUX Controller Board. The FPGA_OK(LD1), DC_IN (LD2) and PWR_OK(LD4) on the HV MUX Controller Board should light up green. A "Connected" message is displayed on the bottom left of the Status bar of the GUI.

The HV MUX Controller Board is now ready to control the HV2918 Analog Switch Evaluation Board.

FIGURE 2-8: HV MUX CONTROLLER BOARD (ADM00825) – FRONT VIEW

2.6 TESTING THE HV2918 ANALOG SWITCH EVALUATION BOARD

The user can turn on/off each of the 32 switches through the USB connected PC GUI software program by following the next steps:

1. Click the Initialize HV MUX Controller button, located at the top left corner.
2. Clear STBY.
3. Select MODE.
4. Put 32-bit data in DIN to set switches on and off. Data 1 means the switch is on and Data 0 means the switch is off.
5. Click the Set HV MUX button. The GUI and controller board now generate 32-bit data and 32 clocks, followed by one LE negative pulse and the switches are on and off according to DIN in the GUI.
6. Select CLR and click the Set HV MUX button to set all switches to off.

Note: The typical voltage and waveforms are provided in Appendix C. "Demo Board Waveforms".

2.7 GENERATION OF PULSER OUTPUT AT SW7 OF HV2918

This section provides the simple step-by-step procedure to make the Ch1 pulser output at the SW7 SMA connector with dummy loads by configuring the GUI.

1. Before powering up the HV2918 Analog Switch Evaluation Board, make sure that the latest GUI software is installed on the PC.
2. Start the GUI program. If the board is not connected, a "Not Connected" message is displayed in the Status bar located at the bottom left of the screen.
3. Power up the HV MUX Controller Board and HV2918 Analog Switch Evaluation Board as described in the previous sections. The prompt, "Connected", is displayed in the Status bar.
4. Click the Initialize HV MUX Controller button and check the message window to see "Initialization Complete".
5. Clear STBY.
6. Select MODE.
7. Change the DIN to Bit 7 from '0' to '1' to set SW7 on (DIN = 00000000 00000000 00000000 10000000).
8. Click the Set HV MUX button to turn on the HV2918 SW7.
9. Change the Pulses to 10.
10. Select CH1.
11. Click the Start button. CH1 pulser starts to generate pulse bursts with ten pulses and 30 ms T_OFF time.

The Ch1 and Ch2 of the oscilloscope in Figure 2-9 show the SW7 and the SW6.

FIGURE 2-9: TYPICAL WAVEFORM OF 2:1 MUX CONNECTED TO PULSER

Chapter 3. GUI Description

3.1 HV2918 ANALOG SWITCH EVALUATION BOARD GUI DESCRIPTION

Figure 3-1 displays a screen capture of the HV MUX Controller Board GUI.

Table3-1 provides a detailed description of every item numbered in the screen capture. The selection of the check box, binary data in the DIN entry box and number in the Pulses and TOFF entry box are just settings and don't change the operation of the HV2918 device and built-in pulsers immediately. By clicking the Set HV MUX, Start and Stop buttons, and the control data set by the user in the GUI change operation of the HV2918 device turn on/off the built-in pulsers in the HV2918 Analog Switch Evaluation Board. Follow the explanation for each corresponding item.

FIGURE 3-1: HV MUX CONTROLLER BOARD GUI SCREEN CAPTURE

TABLE 3-1: HV2918 ANALOG SWITCH EVALUATION BOARD GUI DESCRIPTION

Chapter 4. PCB Design and Layout Notes

4.1 PCB LAYOUT TECHNIQUES FOR HV2918

The HV2918 Analog Switch Evaluation Board has an analog switch to pass high-voltage, high-current and high-frequency pulses. The PCB design and layout are important to ensure the success of the implementation.

4.1.1 High-Voltage and High-Speed Grounding and Layout Techniques

The center pad at the bottom of the HV2918 VQFN package is internally connected to the IC's substrate ( V_SUB ). This pad should be connected to GND, externally on the PCB.

The user must pay attention to the connecting traces, since the analog switches pass the high-voltage and high-speed signals. In particular, a controlled impedance of 50 to the ground plane and more trace spacing needs to be applied in this situation.

High-speed PCB trace design practices are used for the HV2918 Analog Switch Evaluation Board PCB layout. The internal circuitry of the HV2918 device can operate at a high frequency, with the primary speed limitation being the load capacitance. Because of these high-speed and high-transient currents that result from driving capacitive loads, the supply voltage bypass capacitors should be as close to the pins as possible.

All the GND pins should have low-inductance feed through connections that are connected directly to a solid ground plane at the second layer of the PCB. It is recommended to minimize the trace length to the ground plane and to insert a ferrite bead in the power supply lead to the capacitor to prevent resonance in the power supply lines. It is important to minimize trace lengths and use sufficient trace width to reduce inductance. Surface mount components are highly recommended.

The use of a solid ground plane, and good power and signal layout practices prevent any possible parasitic capacitance coupling. The user should also ensure that the circulating ground return current from a capacitive load does not react with common inductance to create noise voltages in the input logic circuitry.

4.1.2 Decoupling Capacitors Selection

The V_LL and V_DD supply voltage rails are able to provide fast transient current. Therefore, they should have a low-impedance bypass capacitor close to each of the power supply pins. Use a surface-mounted ceramic capacitor of 0.1 to 2.2 F capacitance with an appropriate voltage rating.

It is important to verify what type of ceramic capacitor is selected for these bypass capacitors. The low-impedance means low-ESR/ESL impedance within the frequency bandwidth range of ultrasound pulses transmitted, including the very fast dV/dt of the pulse's rising and falling edges. A capacitor with low-temperature coefficient and low-voltage coefficient is also recommended. The type of X7R and X5R or other more advanced multilayer ceramic types should be selected for these purposes.

NOTES:

Appendix A. Schematics and Layouts

A.1 INTRODUCTION

This appendix contains the following schematics and layouts for the HV2918 Analog Switch Evaluation Board (EV19W62A) and the HV MUX Controller Board (ADM00825).

1. HV2918 Analog Switch Evaluation Board (EV19W62A):

• EV19W62A – Schematic
- EV19W62A – Schematic (Output Connectors)
• EV19W62A – Schematic (Power)
• EV19W62A – Schematic (Pulse Generator)
• EV19W62A – Schematic (SPI Flash)
• EV19W62A – Top Silk
• EV19W62A – Top Copper and Silk
• EV19W62A – Top Copper
• EV19W62A – Inner 1 and 4
- EV19W62A – Inner 2
• EV19W62A – Inner 3
• EV19W62A – Bottom Copper
• EV19W62A – Top Copper and Silk
• EV19W62A – Bottom Silk

1. HV MUX Controller Board (ADM00825):

• ADM00825 – Schematic (Connection)
• ADM00825 – Schematic (Power Supply)
• ADM00825 – Schematic (USB to SPI)
- ADM00825 – Schematic (Programmable Clock)
• ADM00825 – Schematic (FPGA)
• ADM00825 – Schematic (FPGA Decoupling Capacitors)
- ADM00825 – Schematic (Connectors)
• ADM00825 – Top Silk
• ADM00825 – Top Copper and Silk
- ADM00825 – Top Copper
- ADM00825 – Inner 1
- ADM00825 – Inner 2
- ADM00825 – Inner 3
- ADM00825 – Inner 4
- ADM00825 – Bottom Copper
• ADM00825 – Bottom Copper and Silk
• ADM00825 – Bottom Silk

A.2 EV19W62A - SCHEMATIC

A.3 EV19W62A - SCHEMATIC (OUTPUT CONNECTORS)

A.4 EV19W62A - SCHEMATIC (POWER)

A.5 EV19W62A - SCHEMATIC (PULSE GENERATOR)

A.6 EV19W62A - SCHEMATIC (SPI FLASH)

A.7 EV19W62A - TOP SILK

A.8 EV19W62A - TOP COPPER AND SILK

A.9 EV19W62A - TOP COPPER

A.10 EV19W62A - INNER 1 AND 4

A.11 EV19W62A - INNER 2

A.12 EV19W62A - INNER 3

A.13 EV19W62A - BOTTOM COPPER

A.14 EV19W62A - BOTTOM COPPER AND SILK

A.15 EV19W62A - BOTTOM SILK

A.16 ADM00825 - SCHEMATIC (CONNECTION)

graph TD
    A["Component 1"] --> B["Pin 1"]
    A --> C["Pin 2"]
    A --> D["Pin 3"]
    A --> E["Pin 4"]
    A --> F["Pin 5"]
    A --> G["Pin 6"]
    A --> H["Pin 7"]
    A --> I["Pin 8"]
    A --> J["Pin 9"]
    A --> K["Pin 10"]
    A --> L["Pin 11"]
    A --> M["Pin 12"]
    A --> N["Pin 13"]
    A --> O["Pin 14"]
    A --> P["Pin 15"]
    A --> Q["Pin 16"]
    A --> R["Pin 17"]
    A --> S["Pin 18"]
    A --> T["Pin 19"]
    A --> U["Pin 20"]
    A --> V["Pin 21"]
    A --> W["Pin 22"]
    A --> X["Pin 23"]
    A --> Y["Pin 24"]
    A --> Z["Pin 25"]
    A --> AA["Pin 26"]
    A --> AB["Pin 27"]
    A --> AC["Pin 28"]
    A --> AD["Pin 29"]
    A --> AE["Pin 30"]
    A --> AF["Pin 31"]
    A --> AG["Pin 32"]
    A --> AH["Pin 33"]
    A --> AI["Pin 34"]
    A --> AJ["Pin 35"]
    A --> AK["Pin 36"]
    A --> AL["Pin 37"]
    A --> AM["Pin 38"]
    A --> AN["Pin 39"]
    A --> AO["Pin 40"]
    A --> AP["Pin 41"]
    A --> AQ["Pin 42"]
    A --> AR["Pin 43"]
    A --> AS["Pin 44"]
    A --> AT["Pin 45"]
    A --> AU["Pin 46"]
    A --> AV["Pin 47"]
    A --> AW["Pin 48"]
    A --> AX["Pin 49"]
    A --> AY["Pin 50"]
    A --> AZ["Pin 51"]
    A --> BA["Pin 52"]
    A --> BB["Pin 53"]
    A --> BC["Pin 54"]
    A --> BD["Pin 55"]
    A --> BE["Pin 56"]
    A --> BF["Pin 57"]
    A --> BG["Pin 58"]
    A --> BH["Pin 59"]
    A --> BI["Pin 60"]
    A --> BJ["Pin 61"]
    A --> BK["Pin 62"]
    A --> BL["Pin 63"]
    A --> BM["Pin 64"]
    A --> BN["Pin 65"]
    A --> BO["Pin 66"]
    A --> BP["Pin 67"]
    A --> BQ["Pin 68"]
    A --> BR["Pin 69"]
    A --> BS["Pin 70"]
    A --> BT["Pin 71"]
    A --> BU["Pin 72"]
    A --> BV["Pin 73"]
    A --> BW["Pin 74"]
    A --> BX["Pin 75"]
    A --> BY["Pin 76"]
    A --> BZ["Pin 77"]
    A --> CA["Pin 78"]
    A --> CB["Pin 79"]
    A --> CC["Pin 80"]
    A --> CD["Pin 81"]
    A --> CE["Pin 82"]
    A --> CF["Pin 83"]
    A --> CG["Pin 84"]
    A --> CH["Pin 85"]
    A --> CI["Pin 86"]
    A --> CJ["Pin 87"]
    A --> CK["Pin 88"]
    A --> CL["Pin 89"]
    A --> CM["Pin 90"]
    A --> CN["Pin 91"]
    A --> CO["Pin 92"]
    A --> CP["Pin 93"]
    A --> CQ["Pin 94"]
    A --> CR["Pin 95"]
    A --> CS["Pin 96"]
    A --> CT["Pin 97"]
    A --> CU["Pin 98"]
    A --> CV["Pin 99"]
    A --> CW["Pin 100"]

A.17 ADM00825 - SCHEMATIC (POWER SUPPLY)

A.18 ADM00825 - SCHEMATIC (USB TO SPI)

A.19 ADM00825 - SCHEMATIC (PROGRAMMABLE CLOCK)

A.20 ADM00825 - SCHEMATIC (FPGA)

A.21 ADM00825 - SCHEMATIC (FPGA DECOUPLING CAPACITORS)

A.22 ADM00825 - SCHEMATIC (CONNECTORS)

A.23 ADM00825 - TOP SILK

A.24 ADM00825 - TOP COPPER AND SILK

A.25 ADM00825 - TOP COPPER

A.26 ADM00825 - INNER 1

A.27 ADM00825 - INNER 2

A.28 ADM00825 - INNER 3

A.29 ADM00825 - INNER 4

A.30 ADM00825 - BOTTOM COPPER

A.31 ADM00825 – BOTTOM COPPER AND SILK

A.32 ADM00825 - BOTTOM SILK

NOTES:

Appendix B. Bill of Materials (BOM)

B.1 HV2918 ANALOG SWITCH EVALUATION BOARD – BOM

TABLE B-1: HV2918 ANALOG SWITCH EVALUATION BOARD – BILL OF MATERIALS

Note: The components listed in this Bill of Materials are representative of the PCB assembly. The released BOM used in manufacturing uses all RoHS-compliant components.

TABLE B-1: HV2918 ANALOG SWITCH EVALUATION BOARD – BILL OF MATERIALS

Note: The components listed in this Bill of Materials are representative of the PCB assembly. The released BOM used in manufacturing uses all RoHS-compliant components.

TABLE B-1: HV2918 ANALOG SWITCH EVALUATION BOARD – BILL OF MATERIALS

Note: The components listed in this Bill of Materials are representative of the PCB assembly. The released BOM used in manufacturing uses all RoHS-compliant components.

B.2 HV MUX CONTROLLER BOARD - BOM

TABLE B-2: HV MUX CONTROLLER BOARD – BILL OF MATERIALS

Note: The components listed in this Bill of Materials are representative of the PCB assembly. The released BOM used in manufacturing uses all RoHS-compliant components.

NOTES:

Appendix C. Demo Board Waveforms

C.1 BOARD TYPICAL WAVEFORMS

FIGURE C-1: 5 MHz, 4 Pulses, Ch1 Pulser Input and Output when All SW Off.

FIGURE C-2: 5 MHz, 10 Pulses, V PP/VNN = ±100V, VDD = +5 V, VGP = 10 V, 330 pF//2.5 kΩ Load.

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