ADS1192ECG-FE

ADS1x9xECG-FE Demonstration Kit User's Guide Literature Number: SLAU384A December 2011 – Revised April 2012 Contents ................................................................................................................. 5 ............................................................................................ 5 2 Overview ............................................................................................................................ 6 2.1 Introduction ............................................................................................................... 6 2.2 Features Supported in this Version ................................................................................... 6 3 Software Installation ............................................................................................................ 7 3.1 Minimum Requirements ................................................................................................ 7 3.2 Installing the Software (PC application) .............................................................................. 7 3.3 Installing the USB Drivers ............................................................................................ 12 4 Running the Software ........................................................................................................ 16 4.1 Overview of the Features ............................................................................................. 17 5 ADS1x9xECG-FE Hardware Introduction .............................................................................. 27 5.1 Power Supply ........................................................................................................... 27 5.2 Clock ..................................................................................................................... 28 5.3 Memory .................................................................................................................. 28 5.4 Accessing ADS1x9x Digital Signals ................................................................................. 28 5.5 GPIO Test Points ...................................................................................................... 28 5.6 Analog Inputs ........................................................................................................... 28 5.7 USB Interface ........................................................................................................... 29 5.8 Onboard Key Interface ................................................................................................ 29 5.9 Visual Indication ........................................................................................................ 30 6 Evaluation of ECG and Respiration Specific Functions .......................................................... 30 6.1 Evaluation Mode (Analysis Mode) ................................................................................... 31 6.2 Live Data Streaming Mode ........................................................................................... 32 7 USB-Based Firmware Upgrade ............................................................................................ 37 8 Connector Interface ........................................................................................................... 38 8.1 DB9 ECG Electrode Connector ...................................................................................... 39 8.2 USB Mini Connector ................................................................................................... 39 Appendix A ECG Cable Details .................................................................................................... 40 Appendix B ADS1x9x EVM Bill of Materials (BOM) ........................................................................ 41 Appendix C PCB Layout and Schematics ..................................................................................... 46 C.1 PCB Layout ............................................................................................................ 46 C.2 Schematics ............................................................................................................ 49 1 ADS1x9xECG-FE 1.1 2 Important Disclaimer Notice Table of Contents SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated www.ti.com List of Figures 1 ADS1x9xECG-FE Demonstration Kit ..................................................................................... 6 2 PC Application Installation Screen 1 ..................................................................................... 8 3 PC Application Installation Screen 2 ..................................................................................... 8 4 PC Application Installation Screen 3 ..................................................................................... 9 5 PC Application Installation Screen 4 ..................................................................................... 9 6 PC Application Installation Screen 5 .................................................................................... 10 7 PC Application Installation Screen 6 .................................................................................... 10 8 PC Application Installation Screen 7 .................................................................................... 11 9 PC Application Installation Screen 8 .................................................................................... 11 10 PC Application Installation Screen 9 .................................................................................... 12 11 PC Application Installation Screen 10 12 12 Hardware Wizard Screen 1 13 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 .................................................................................. .............................................................................................. Hardware Wizard Screen 2 .............................................................................................. Hardware Wizard Screen 3 .............................................................................................. Hardware Wizard Screen 4 .............................................................................................. Hardware Wizard Screen 5 .............................................................................................. Hardware Wizard Screen 6 .............................................................................................. Device Manager Screen .................................................................................................. EVM not connected Error Message ..................................................................................... Register Configuration - Channel Registers ........................................................................... Register Configuration – LOFF and RLD............................................................................... Register Configuration – GPIO .......................................................................................... Register Configuration – Respiration Registers ....................................................................... Register Configuration – Register Map ................................................................................. PC Application Analysis – SCOPE ...................................................................................... PC Application Analysis - Histogram.................................................................................... PC Application Analysis - FFT ........................................................................................... PC Application Analysis – ECG ......................................................................................... PC Application Analysis – ADS1292R Respiration (Low Pass Filter Enabled) ................................... PC Application Save ...................................................................................................... PC Application Live ECG for ADS1292R............................................................................... PC Application Live Respiration Channel .............................................................................. Simulator Connection ..................................................................................................... Switch Positions ........................................................................................................... Firmware Architecture..................................................................................................... Evaluation Mode Data Flow for ADS1292R............................................................................ Live Data Stream Mode Data Flow for ADS1292R ................................................................... Frequency Response for the IIR Filter .................................................................................. Frequency Response for the MBF Filter (Full View) .................................................................. Frequency Response for the MBF Filter (50Hz Notch) ............................................................... Frequency Response for the MBF Filter (Sharp cut off Around 150Hz) ........................................... Frequency Response for the Band Pass Filter ........................................................................ PC Application Firmware Upgrade - 1 .................................................................................. PC Application Firmware Upgrade - 2 .................................................................................. PC Application Firmware Upgrade - 3 .................................................................................. DB9 ECG Connector Pin Outs........................................................................................... USB Mini Connector Pin Outs ........................................................................................... SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated List of Figures 13 14 14 15 15 16 16 17 18 18 19 19 20 21 22 23 23 24 25 26 29 30 31 32 33 34 34 35 35 35 37 38 38 39 39 3 www.ti.com 4 48 ECG Cable Drawing....................................................................................................... 40 49 Top Layer Placement ..................................................................................................... 47 50 Bottom Layer Placement ................................................................................................. 48 List of Figures SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated User's Guide SLAU384A – December 2011 – Revised April 2012 ADS1x9xECG-FE Demonstration Kit This user's guide describes the characteristics, operation, and use of the ADS1x9xECG-FE. This demonstration kit models the ADS1192, ADS1292 and ADS1292R. The family of devices are two-channel, 16/24-bit, low-power, integrated analog front-end (AFE) designed for portable electrocardiogram (ECG) and respiration applications. The ADS1x9xECG-FE is intended for prototyping and evaluation. This user's guide includes a complete circuit description, schematic diagram, and Bill of Materials. 1 ADS1x9xECG-FE 1.1 Important Disclaimer Notice NOTICE: The ADS1x9x demonstration kits are intended for feasibility and evaluation testing only in laboratory and development environments. This product is not for diagnostic use. This product is not for use with a defibrillator: • The ADS1x9xECG-FE to be used only under these conditions: – The ADS1x9xECG-FE demonstration kit must not be used for diagnostic purposes. – – The ADS1x9xECG-FE demonstration kit is intended solely for evaluation and development purposes. It is not intended for use and may not be used as all or part of an end equipment product. – The ADS1x9xECG-FE demonstration kit should be used solely by qualified engineers and technicians who are familiar with the risks associated with handling electrical and mechanical components, systems and subsystems. – You are responsible for the safety of you and your employees and contractors when using or handling the ADS1x9x demonstration kit. Furthermore, you are fully responsible for the contact interface between the human body and electronics; consequently, you are responsible for preventing electrical hazards such as shock, electrostatic discharge, and electrical overstress of electric circuit components. Pentium, Celeron are trademarks of Intel Corporation. Windows is a registered trademark of Microsoft Corporation. All other trademarks are the property of their respective owners. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 5 Overview www.ti.com 2 Overview 2.1 Introduction NOTE: From this point on, unless otherwise noted, ADS1x9x refers to ADS1192, ADS1292 and ADS1292R based demonstration kits. This user’s guide describes ADS1x9x software and hardware. The appendix contains the Bill of Materials and schematic design. The demonstration board shown in Figure 1 is provided to accomodate evaluation and system development activities related to ADS1x9x devices. Figure 1. ADS1x9xECG-FE Demonstration Kit The hardware is designed so all of the following ECG front end devices can be evaluated: 1. ADS1292 – 2 channels at 24 bits 2. ADS1292R – 2 channel at 24 bit with respiration 3. ADS1291 – 1 channel at 24 bit 4. ADS1191 – 1 channel at 16 bit 5. ADS1192 – 2 channel at 16 bit The board can be assembled with any of these chips. ADS1292, ADS1292R and ADS1192 demonstration kits are available. The MSP430 firmware and PC application are designed to automatically detect the installed part and configure to accommodate the part. Throughout this document, the term demonstration kit is synonymous with the ADS1x9xECG-FE. 2.2 Features Supported in this Version 1. Four electrode ECG cable support 2. View six ECG Leads: Lead I, Lead II, Lead III, Lead aVR, Lead aVL, Lead aVF and respiration channel (ADS1292R only) . 3. Two modes of operation: Evaluation and Live ECG / Respiration 4. Acquire data at up to 8 kHz in Evaluation mode 5. Current based Lead off detection 6. USB based power and PC application connectivity 7. Access to all ADS1x9x registers via an easy to use GUI. 6 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Software Installation www.ti.com 8. Built-in time domain, histogram, FFT and ECG / Resp related analysis on the PC application 9. Live ECG with heart rate calculation. 10. Live Respiration wave with respiration rate calculation 11. USB based firmware upgrade option 12. MSP430 Firmware debugging using ez430 USB emulator 3 Software Installation 3.1 Minimum Requirements Before installing the software, verify that your PC meets the minimum requirements outlined in this section 3.1.1 • • • • • • Required Setup for ADS1x9xECG-FE Demo Software IBM PC-compatible computer Pentium™ III/ Celeron™ 866 MHz or equivalent processor Minimum 256 MB of RAM (512 MB or greater recommended) Hard disk drive with at least 200 MB free space Microsoft Windows® XP SP2 operating system or Windows 7 operating system 1280 × 1024 or greater display screen resolution • • • Additional Requirements for use with Hardware ADS1x9xECG-FE Demonstration Kit USB to mini USB cable DB9 ECG Cable 3.1.2 3.2 Installing the Software (PC application) Before installing the software, make sure the ADS1x9xECG-FE is NOT connected to the PC. If using a machine with Windows 7, we recommend having administrator rights to avoid problems during installation. Unzip the installer file, and then find and double click setup.exe to install the software. Unless otherwise specified during the install process, the software installs at C:\Program Files\Texas Instruments\ADS1x9xEVM. It creates a program menu item ADS1x9xEVM under Programs → Texas Instruments → ADS1x9xevm to execute the software. The following steps ensure proper installation of the PC application. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 7 Software Installation www.ti.com Click on setup.exe and the following screen appears. Click “Next” Figure 2. PC Application Installation Screen 1 Accept the License Agreement and click “Next”. Figure 3. PC Application Installation Screen 2 8 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Software Installation www.ti.com Accept the License Agreement and click “Next”. Figure 4. PC Application Installation Screen 3 The LabVIEW application software is installed now. Click “Next” to install the Microsoft C++ 2008 Redistributable Package (x86). Figure 5. PC Application Installation Screen 4 SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 9 Software Installation www.ti.com If your system already has the Microsoft C++ 2008 Redistributable Package (x86) installed, then the following screen appears. Click “Cancel” to proceed. Figure 6. PC Application Installation Screen 5 Click “Finish” to complete the installation procedure. Figure 7. PC Application Installation Screen 6 10 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Software Installation www.ti.com If your system does not have the Microsoft C++ 2008 Redistributable Package (x86) installed, then the following screen appears. Click “Next”. Figure 8. PC Application Installation Screen 7 Accept the license terms and click “Install”. Figure 9. PC Application Installation Screen 8 SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 11 Software Installation www.ti.com Click “Finish” to complete the installation. Figure 10. PC Application Installation Screen 9 The following screen might appear for the first time installation. Restart the machine. Figure 11. PC Application Installation Screen 10 The PC application is now ready to use. 3.3 Installing the USB Drivers The communication interface between the ADS1x9xECG-FE board and PC is through USB using CDC profile. A onetime installation of the USB driver is required for the communication between ADS1x9xECGFE and PC application. The following steps will ensure proper installation of the USB drivers. 1. Plug-in USB to mini USB cable to P1 of ADS1x9xECG-FE and the other end to the USB port on the PC. 2. The operating system will prompt for USB driver for the “ADS1x9x - ECG Recorder” device. When the wizard comes up, select the options “No, not this time” as shown in Figure 12. Click “Next” 12 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Software Installation www.ti.com Figure 12. Hardware Wizard Screen 1 Select the option “Install from a list or specific locations (Advanced)” and click “Next”. Figure 13. Hardware Wizard Screen 2 As shown in Figure 14 navigate to the directory in which “MSP430-CDC.inf” file is located (C:\Program Files\Texas Instruments\ADS1x9xevm\USB Drivers). This file will be copied to the directory while installing the PC application. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 13 Software Installation www.ti.com Click “Next” Figure 14. Hardware Wizard Screen 3 Figure 15. Hardware Wizard Screen 4 14 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Software Installation www.ti.com For the following warning message click on “Continue Anyway” Figure 16. Hardware Wizard Screen 5 Click on Finish Figure 17. Hardware Wizard Screen 6 SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 15 Running the Software www.ti.com The ADS1x9xECG-FE now will get recognized as Virtual COM port under Device Manager as shown in Figure 18. Figure 18. Device Manager Screen The USB driver installation is now complete and ADS1x9xEVM is now ready to use. 4 Running the Software From the Start menu, select Programs>Texas Instruments>ADS1x9xevm to run the ADS1x9xEVM software. Unless the hardware has been disconnected, the user will observe messages that confirm that the connection has been established and the program will wait in idle mode for user input. If the connection to the ADS1x9xECG-FE board is not established, then the program will prompt the user to check the connection between the PC and ADS1x9xECG-FE and retry. Figure 19. EVM not connected Error Message 16 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Running the Software www.ti.com 4.1 Overview of the Features This section provides a quick overview of the various features and functions of the ADS1x9xECG-FE software package. The main tabs consist of: • About • ADC Register - Allows the user to configure all the ADS1x9x user registers • Analysis - Allows the user to view and analyze the raw data • Save - Allows the user to write data samples and analysis results to a file • Live ECG\RESP Display - Provides streaming ECG signals along with heart rate, lead off information and respiration 4.1.1 ADC Registers Tab The ADC register tab allows the user to configure the various registers of the ADS1x9x. Please see the ADS1x9x datasheet for register details of the chip. NOTE: The ADS1x9xECG-FE GUI only supports Continuous Conversion Mode. Single Shot Mode is not supported. Figure 20. Register Configuration - Channel Registers SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 17 Running the Software www.ti.com The LOFF and RLD tab consists of the settings to enable lead-off, selecting the channels for lead-off detection and deriving the Right Leg Drive signal. General options including clocking are also available on this tab. Figure 21. Register Configuration – LOFF and RLD The GPIO Registers tab consists of the GPIO settings. Figure 22. Register Configuration – GPIO 18 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Running the Software www.ti.com The Respiration Registers tab consists of the settings needed for respiration and RLD reference signals. The respiration controls are specific to the ADS1292R, they are not applicable for the ADS1192 and ADS1292. Figure 23. Register Configuration – Respiration Registers The Registers Map tab reads back the register bit values from the ADS1x9xECG-FE. The Refresh Registers button provided in this tab read back the register values from the ADS1x9xECG-FE at any time. Figure 24. Register Configuration – Register Map SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 19 Running the Software 4.1.2 www.ti.com Analysis Tab The Analysis tab consists of various analysis routines and displays. The following sub-tabs are available for the Analysis tab • Scope • Histogram • FFT • ECG\Resp Display The data is acquired from the EVM by clicking ACQUIRE button. The number of samples (block size) to be acquired must be given in the space provided. The CONTINUOUS button acquires the data from the EVM continuously in the designated block size. Scope Sub-Tab The Scope sub-tab displays the data in the time-domain. The units are converted from codes to volts using the voltage reference value set in the ADC Registers tab and are plotted as either input referred (output divided by PGA gain setting) or non-input referred using the checkbox located in the top right corner of the GUI. The Scope Analysis button activates a pop-up that displays the mean voltage, root mean square (RMS) voltage and peak to peak voltage for noise analysis. Figure 25. PC Application Analysis – SCOPE 20 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Running the Software www.ti.com The following main buttons/controls are available in this sub-tab Button/Control Description Scope Analysis Displays the mean, root mean square (RMS), and peak-to-peak for noise analysis of the acquired data Plot Channel selection button allow selecting All channels, Channel 1, or Channel 2 for display Histogram Sub-Tab The Histogram sub-tab displays the data in a histogram format for the two channels. The data is arranged in the total number of histogram bins set within the tab following acquisition. The Histogram Analysis button can be used to view the mean voltage, root mean square (RMS) voltage and peak to peak voltage for analysis. Figure 26. PC Application Analysis - Histogram The following buttons/controls are available in this sub-tab Button/Control Description Histogram Analysis Runs histogram of the selected channel(s) for the selected number of samples Plot Channel selection button allow selecting all channels or Channel 1 or Channel 2 for the display Histogram Bins Set the total number of bins to arrange the individual channels Display Plane(Right click on the display area and then select “Optional Plane” menu item) Various display planes can be selected for the histogram display. The options available are: • Nyquist • Nichols • S Plane • Z Plane SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 21 Running the Software www.ti.com FFT Sub-Tab The FFT sub-tab displays the data in the frequency domain by performing a FFT on the two channels. Details of the FFT, including SNR, THD, etc. can be viewed using the FFT Analysis button located in the bottom left corner of the display. Figure 27. PC Application Analysis - FFT Button / Control Description FFT Analysis Runs FFT analysis of the selected channel(s) and result will be shown on the pop-up window Plot Channel selection button allow selecting All channels, Channel 1, or Channel 2 for display AC Analysis Parameters Section Various AC analysis parameter configuration Coherent Frequency Calculator Provision for entering desired Ain Frequency Section User Defined Dynamic Range Section 22 Provision for selecting Low and High frequency ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Running the Software www.ti.com ECG\RESP Sub-Tab The ECG\RESP Display sub-tab displays the ECG data for Lead I, Lead II, Lead III, Lead aVR, Lead aVL, or Lead aVF for the ADS1192 and ADS1292. The ADS1292R only displays Lead I or Respiration data. Figure 28. PC Application Analysis – ECG Figure 29. PC Application Analysis – ADS1292R Respiration (Low Pass Filter Enabled) SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 23 Running the Software www.ti.com The following buttons/controls are available in this sub-tab: Button/Control Description Plot Set Option to select ECG Lead I, Lead II, Lead III, Lead aVR, Lead aVL, Lead aVF or Respiration Channel (ADS1292R only) High Pass Filter Provision for enabling a high pass filter with support for selecting the order of the filter and cut off frequency (1) Low Pass Filter Provision for enabling a low pass filter with support for selecting the order of the filter and cut off frequency (1) Notch Filter Provision for enabling a notch filter for 50Hz or 60Hz with support for selecting the order of the filter. This filter will be applied on the acquired data for the sampling rate of 500SPS (1) (1) Post- processing for filter done in GUI. Apart from the above specific buttons / control on each sub-tabs, the following options are available by right-clicking in the display area: 4.1.3 Display Options Description Auto scaling Both x-scale and y-scale auto scaling is possible. User can enable or disable this feature Export Data The displayed data can be exported to excel or Clipboard Annotation Provision Provision provided for creating and deleting annotation Visible Items selector Option to display x-scale, y-scale, Plot legends, x-scrollbar Plot legend options Plot legend gives various option to change the color of the plotting, various plotting styles etc Save Tab The Save tab provides provisions to save the analysis or data to a file. By default, the data is saved to C:\Program Files\Texas Instruments\ADS1x9xevm\saved. Use the Directory to Save Files option to select the folder where data is to be saved. In the pop up window, navigate to the folder where the file is to be saved and select Use Current Folder. Then select Save to File to save the file. Figure 30. PC Application Save The following options are provided in the Save tab. 24 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Running the Software www.ti.com Button/Control Description Scope Analysis For saving scope analysis result. The result will be saved in the file “Device__Analysis.xls”. FFT Analysis For saving FFT analysis result. The result will be saved in the file “Device__Analysis.xls”. Histogram Analysis For saving histogram analysis result. The result will be saved in the file “Device__Analysis.xls”. Register Setting All the current register values will be read from the EVM and stored. The result will be saved in the file “Device__Analysis.xls”. Data - Codes Acquired data sample values will be stored to the file “Device_ _Codes.xls” Data - Volts Acquired data sample’s voltage values will be stored to the file “Device_ _Volts.xls” FFT Data Acquired data sample’s FFT values will be stored to the file “Device_ _FFT.xls” Histogram Data Acquired data sample’s histogram values will be stored to the file “Device_ _Histogram.xls” The Record Number saves files with the provided number in the file name. There are options to select Channel 1 and Channel 2 while saving the corresponding data to the file. User notes also can be added to the file by typing the notes in the User Comments control. 4.1.4 Live ECG / RESP Display Tab Live ECG and respiration data are shown on the Live ECG/RESP Display tab. This tab also shows the heart rate, respiration rate and lead-off information. Figure 31. PC Application Live ECG for ADS1292R SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 25 Running the Software www.ti.com Figure 32. PC Application Live Respiration Channel Live ECG display or respiration display is started by clicking on Start Data Streaming and can be stopped by clicking on Stop Data Streaming. The following buttons/controls are available in this sub-tab: Buttons/Control Description Lead selection The following can be selected for the live display ● ECG Lead I ● ECG Lead II ● ECG Lead III ● ECG Lead aVR ● ECG Lead aVL ● ECG Lead aVF ● Respiration Channel (ADS1292R only) Signal BW Signal bandwidth can be selected to either 40 Hz or 150 Hz. The filter on the EVM board is automatically enabled based on the selection made. Notch filter Provision for selecting either 50-Hz or 60-Hz notch filter. The filter on the EVM board is automatically enabled based on the selection made. Auto scaling (Right-click on the display area) Both x-scale and y-scale auto scaling is possible. User can enable or disable this feature. Export data (Right-click on the display area) The displayed data can be exported to EXCEL™ or the clipboard. Visible items selector (Right-click on the display area) Option to display x-scale, y-scale, plot legends, x-scrollbar. Plot legend options (Right-click on the plot legend) Plot legend gives various option to change the color of the plot, various plotting styles, etc. The Lead-off Status is interpreted as shown in the table below. 26 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Hardware Introduction www.ti.com Leads Lead Off Status LL off IN2P is red RA off IN2N and IN1N are red LA off IN1P is red Monitoring lead-off information is achieved by polling the Status byte in the data-word after each conversion. Within the ADS1x9xECG-FE software, there are two ways to view the Lead-Off Status. Within the Live ECG\RESP tab, the information about the lead status is shown in the upper right corner of the GUI. Within the Analysis tab, a pop-up window showing the status can be viewed by clicking on the Show/Poll Lead-Off Status button. 5 ADS1x9xECG-FE Hardware Introduction The key features of the ADS1x9x analog front end demonstration board are: • Based on MSP430F5529 • ADS1192 and ADS1292 suitable for six leads of ECG: Lead I, Lead II, Lead III, Lead aVR, Lead aVL, or Lead aVF • ADS1292R suitable for one lead of ECG (Lead I) and respiration channel • Low power consumption (350 Micro Watt/channel) • Data Rate ranges from 125 SPS to 8 kSPS • Unipolar Operation • Lead off detection circuitry • On chip oscillator and reference • On chip RLD amplifier • SPI data interface • 8Gb NAND Flash support The ADS1x9xECG-FE can be used as a demo board for standard six lead ECG and respiration channel using four electrode inputs. Defibrillator protection and patient protection circuitry are not provided on the ADS1x9xECG-FE board. The printed circuit board (PCB) and schematic are shown in Appendix C. MSP430F5529 (U7) is the micro-controller used on the board. For more details of the MSP430F5529 please visit http://focus.ti.com/docs/prod/folders/print/msp430f5529.html The following sections explain the main hardware components available on the ADS1x9xECG-FE. 5.1 Power Supply ADS1x9x can operate from 2.7 V to 5.25 V analog supply (AVDD/AVSS) and 1.65 to 3.6V (DVDD) digital supply. In this design the ADS1x9x is operated at 3 V analog and 3.3 V digital. The power for the board is derived from the USB input (P1) through a forward biased diode (D3) to avoid reverse current flow. The USB data bus is ESD protected using TI’s ESD protection diode array TPD4E004DRYR (U2). The USB VBUS is fed to the integrated Li-ion linear charger and system powerpath management module, BQ24032ARHLR (U8), which generates greater than 4.2V output (VCC_BAT). This output is then fed to TI’s low-power linear voltage regulator, TPS73033 (U16), for generating regulated 3.3V for digital section of the board. The 3V supply for the analog section is derived from VCC_BAT using TI’s low dropout voltage regulator TPS73201 (U10). The inductors L3, L4, L5 and L7 are used to minimize the power supply noise induced by the power supply regulators. The test points TP25, TP32 are provided to make sure the power supplied to the board is correct. The corresponding voltages are given in the table below. The analog power supply (ADS_AVDD) is also brought out on connector P3. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 27 ADS1x9xECG-FE Hardware Introduction 5.2 www.ti.com Sl NO Test Point Description 1 TP25 3.3 V 2 TP32 ADS_AVDD, 3.0 V Clock The ADS1x9x includes an on-chip circuit which generates a 512 kHz clock, ±2% over temperature. For application requiring higher accuracy the ADS1x9x can also use an external clock signal. The demonstration kit provides the firmware option to select either an internal or external clock for testing. The demonstration kit also provides the option to generate an external clock for the ADC from the MSP430 or onboard oscillator. Oscillators O2 (24MHz) and O3 (32.768 KHz) are used by the micro-controller. Clock Type 5.3 R21 R24 Clock SEL Internal Clock Not Installed Not Installed Mount R77 to Drive “high” on ADC_CLK_SCL OR Set P2.3 of MSP430 to Drive “high” on ADC_CLK_SCL. External Clock Not Installed Installed Mount R76 to Drive “low” on ADC_CLK_SCL OR Clear P2.3 of MSP430 to Drive “low” on ADC_CLK_SCL. Memory ADS1x9xECG-FE has 8GB NAND Flash memory (U14) installed for data storage. 5.4 Accessing ADS1x9x Digital Signals ADS1x9x SPI interface with MSP430 can be accessed through the test points given in the table below: 5.5 Sl NO. Signal Test Points 1 ADC_CS TP24 2 ADC_START TP56 3 ADC_DOUT TP47 4 ADC_SCLK TP11 5 ADC_DIN TP46 6 ADC_DRDY TP52 7 ADC_RESET TP53 8 CLK TP42 GPIO Test Points There are two GPIO connections between the ADS1x9x and the MSP430 micro-controller, which are accessible through the test points given in the table below: 5.6 Sl NO. Signal Test Points 1 ADC_GPIO1 TP15 2 ADC_GPIO2 TP16 Analog Inputs The ADS1x9xECG-FE gives the user the option to feed in the standard ECG/Respiration signals from a patient simulator to the DB9 connector (P5). The output from any typical patient simulator can be directly fed into the DB9 connector. For all measurements in this user guide a Fluke medSim 300B simulator was used as shown in Figure 33. 28 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Hardware Introduction www.ti.com Figure 33. Simulator Connection 5.7 USB Interface The ADS1x9xECG-FE has a mini USB interface for PC application connectivity requiring a standard mini USB to USB cable for connection. ADS1x9xECG-FE is designed to work in the slave mode. 5.8 Onboard Key Interface The ADS1x9xECG-FE board has four switches. Figure 34 details the position of each switch. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 29 Evaluation of ECG and Respiration Specific Functions www.ti.com SW1 SW3 SW2 SW4 Figure 34. Switch Positions The function of each switch is defined in the following table: 5.9 Switch Number Description SW1 This switch is used to enable boot strap loader (BSL) MSP430 firmware. SW2 Unused SW3 This switch is used for hard reset of the board. The board will reset and start again with the firmware loaded. SW4 Unused Visual Indication The demonstration kit has two LEDs to indicate various operating states. The flashing green LED (D2) indicates the ADS1x9xECG-FE is in the idle state and steady blue LED (D1) indicates the micro-controller is busy in servicing requests from the PC application. 6 Evaluation of ECG and Respiration Specific Functions The micro-controller receives the two-channel data from ADC through the SPI interface to send to the PC. The software is designed to handle the following activities: • Data acquisition • ADC Lead off detection • DC signal removal • Multi band pass filtering • ECG lead formation • QRS (HR) detection • RR Detection • USB communication • Firmware upgrade through USB The high level architecture of the firmware implementation for the ADS1292R is given below: 30 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Evaluation of ECG and Respiration Specific Functions www.ti.com Start ADS1292R DRDY interrupt . ADS1292R SPI interrupt . Initialize Peripherals & System parameters. USB Receive and Transmit DMA Handler 1. Read ADS1292R data 2. Filter raw ECG data 3. Compute HR and RR. 4. Store packet to memory. 5. Update status on LED. ADS1292R Data Recording Main loop : States ADS1292R IDLE 1. Monitor user commands. ADS1292R REG Configuration 1. Update/read reg. 2. Interface with PC app. 3. Update status LED’s ADS1292R Data streaming ADS1292R Data dumping 1. Read ADS1x9x data 2. Process raw data 3. Compute HR and RR. 4. Stream data to PC application through USB. 5. Update status on LED. 1. Read packet from memory. 2. Transfer data to PC application through USB. 3. Update Status on LED’s. ADS1292R Firmware upgrade 1. Force firmware to BSL code. 2. Upgrade Firmware. 3. Reset firmware. Figure 35. Firmware Architecture The PC application consists of a LabVIEW front-end GUI with a back-end DLL written using C++. The DLL interfaces with the Windows USB driver and communicates to the demonstration kit. The LabVIEW front end GUI uses function calls to communicate with the demonstration kit through the DLL. There are two general operating modes available in the system. 1. Evaluation Mode (Analysis Mode) 2. Live Data Streaming Mode 6.1 Evaluation Mode (Analysis Mode) The Analysis Mode is used for the following requests: 1. Register setting 2. Register read 3. Data acquire Firmware configures the ADC registers with default values during power on. Users can change the register settings through the PC application GUI. The register setting request from the PC is processed by the firmware and the appropriate register set command will be sent to the ADC. During the data acquire request, the firmware will process the number of samples to be acquired as set in the GUI. The firmware instructs the ADC to start the data conversion in continuous mode. Based on the sampling rate configured, the ADC generates data ready pulses (DRDY) which are used by the microcontroller to indicate when to read data back. The data is stored in the onboard flash memory and later sent to the PC application in individual packets. Each packet contains 8 samples which are 24bits in length. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 31 Evaluation of ECG and Respiration Specific Functions www.ti.com Data Acquisition SPI SPI Interrupt 2 Channel Data Reader Data Packetize Module (CH1 and CH2) ADC data DRDY Interrupt Decode PC Commands ADS1292R Configuration Module USB ADS1292R DATA FLOW DIAGRAM: Evaluation Mode USB ECG and Respiration PC Application Figure 36. Evaluation Mode Data Flow for ADS1292R 6.2 Live Data Streaming Mode The Live ECG / Live Respiration data streaming can be started from the PC applicationLive ECG \ RESP Display tab by clicking Start Data Streaming. The PC application will set the sampling rate to 500SPS before requesting the firmware to start the live data streaming. The firmware will instruct the converter to run in continuous conversion mode, monitoring the DRDY interrupt for notification as to when new data is ready. Based on the interrupt, the firmware reads the data from the ADC. The firmware applies the following filters on the data read: 1. DC removal IIR filter 2. Multiband-pass FIR filter with 50/60 Hz notch (user selectable) or band-pass filter The filtered signal is used for detecting the heart rate, respiration rate and deriving ECG leads. Filters are applied only for live data streaming mode. The system data flow diagram for live data stream mode is given in Figure 37. 32 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Evaluation of ECG and Respiration Specific Functions Data Acquisition Lead Off Status Respiration Rate Algorithm (RR) CH1 RR Decode PC Commands QRS Algorithm (HR) CH2 Respiration signal Lead Off Status ECG signal ADC data DRDY Interrupt 1 ECG Lead DRDY Interrupt FIR Filters for ECG (CH2) & Respiration (CH1) IIR Filter (DC Removal) HR SPI SPI Interrupt 2 ChannelData Reader Lead Off Status From ADC 1 RESPIRATION CH. www.ti.com Lead Off Status Memory USB USB ADS1292R DATA FLOW DIAGRAM: PROCESSED ECG and RESPIRATION PC Application Figure 37. Live Data Stream Mode Data Flow for ADS1292R 6.2.1 Filters IIR Filter - DC signal removal 1st Order IIR filter is used to remove the DC component from the acquired data. The following transfer function is used for the filter: H(z) = Y(z) 1 - z -1 = X(z) 1 - az -1 (1) To provide DC attenuation at 22dB, the value of alpha is chosen as 0.992. The IIR filter output is scaled down to 16-bit and then provided to the FIR filter. The frequency response for the IIR filter is shown in Figure 38. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 33 Evaluation of ECG and Respiration Specific Functions www.ti.com Figure 38. Frequency Response for the IIR Filter Multiband-pass Filter Multiband-pass filter (MBF) is used for removing unwanted signals and power line noise from the live data. The MBF digital filter is a 161 order FIR filter with Hamming window having cut-off at 150Hz and notch at 50/60 Hz. The notch frequency is selectable from the PC application. This filter provides a very sharp cutoff around 150 Hz with attenuation more than 30 dB at the stop band. The notch at 50/60 Hz provides attenuation of more than 30 dB. Sampling frequency is 500 samples/ second. The frequency response of the filter with a 50 Hz notch is shown in Figure 39, Figure 40, and Figure 41. Figure 39. Frequency Response for the MBF Filter (Full View) 34 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Evaluation of ECG and Respiration Specific Functions www.ti.com Figure 40. Frequency Response for the MBF Filter (50Hz Notch) Figure 41. Frequency Response for the MBF Filter (Sharp cut off Around 150Hz) Band Pass Filter PC application allows the selection of a 161 order muscle artifact filter, which has a passband of 0.67 Hz to 40 Hz. This filter provides a sharp cut-off at 40 Hz with attenuation of 30 dB at the stop band. The frequency response for the filter is shown in Figure 42. Figure 42. Frequency Response for the Band Pass Filter SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 35 Evaluation of ECG and Respiration Specific Functions 6.2.2 www.ti.com Lead Derivation The demonstration kit is configured to generate two ECG leads (Lead I and Lead II) from the four electrodes using two channels of the ADS1192 and ADS1292 data. The other four ECG leads are computed from Lead I and Lead II using the following equations: Lead III = Lead II - Lead I Lead aVR = - Lead II + 0.5 * Lead III Lead aVL = Lead I - 0.5 * Lead II Lead aVF = Lead III + 0.5 * Lead The ADS1292R demonstration kit is configured to generate one ECG lead (Lead I) and one respiration channel from the four electrodes using the two channels. 6.2.3 QRS and Respiration Rate Detection QRS detection is based on first derivative of the Lead I ECG signal and threshold. Once five consecutive QRS are detected, the heart rate is calculated by taking average of the five RR intervals. The following steps are involved for calculating heart rate: 1. Calculate first derivative of the Lead I ECG signal samples. The first derivative for any sample is calculated as y0(n) = |x(n+1) – x(–1)| Where, y0(n) is the first derivative. x (n+1) is the sample value for (n + 1) th sample. x (n – 1) is the sample value for (n – 1) th sample. 2. The initial two seconds of the first derivative is stored in a buffer and the maximum value (P) in this buffer is obtained. 3. Calculate the threshold as 0.7 x P. 4. Whenever a derivative crosses the threshold, the ECG sample index (S1) of that particular sample is marked. 5. The QRS peak is detected by scanning the next 40 derivatives (MAXIMA_SEARCH_WINDOW = 40) and obtaining the maxima (M1) .This maxima (M1) value is stored in another buffer. 6. After detecting a QRS peak, the next 50 samples (SKIP_WINDOW = 50) are skipped to take care of the minimum RR interval that can occur in the case of maximum detectable heart rate (i.e. 240 BPM). 7. Next five QRS peaks are detected by repeating steps 4 to 7. 8. RR interval is calculated as the number of samples between two consecutive QRS peaks. 9. Heart rate is calculated using the below formula HR per Minute = (60 * Sampling Rate)/ (Average RR interval for 5 consecutive RR intervals ) 10. Threshold also gets recalculated from the QRS peak values detected. 36 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated USB-Based Firmware Upgrade www.ti.com Respiration rate for boards with the ADS1292R installed is calculated from the respiration waveform using the similar algorithm mentioned above. USB Receive and transmit module The processed ECG and Respiration data including the heart rate, lead-off status, and respiration rate is communicated to the PC, packet by packet, through the ECG interface. The packet contains 14 samples of data, each being 16bits in width. 7 USB-Based Firmware Upgrade The firmware on the ADS1x9xECG-FE can be changed from the PC application by selecting the Firmware Upgrade option on the PC application. At the end of the firmware upgrade, the system issues a reset command and will reload with new firmware. The firmware upgrade process steps are represented in the below screen shots: 1. Select PC application menu File> Load Firmware Figure 43. PC Application Firmware Upgrade - 1 2. The firmware upgrade application window and the application will detect the connected ADS1x9xECGFE. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 37 Connector Interface www.ti.com Figure 44. PC Application Firmware Upgrade - 2 3. Browse and select the firmware binary file (.txt file) and click “Upgrade Firmware” Figure 45. PC Application Firmware Upgrade - 3 NOTE: The default firmware will be available at C:\Program Files\Texas Instruments\ADS1x9xevm\Firmware. 4. Device will reset and come up with new firmware with itself. 8 Connector Interface The following connectors used for external interface to ADS1x9x ECG recorder board. • DB9 • USB mini connector 38 ADS1x9xECG-FE Demonstration Kit SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated www.ti.com 8.1 Connector Interface DB9 ECG Electrode Connector Figure 46. DB9 ECG Connector Pin Outs NO Description ERA 2 ELA 3 ELL 4 ERL 5 NC No Connect 6 NC No Connect 7 NC No Connect 8,9 8.2 Signal 1 ECG_SHD_DRV USB Mini Connector Figure 47. USB Mini Connector Pin Outs NO Signal Description 1 VBUS USB power 5 V 2 D– USB DM 3 D+ USB DP 4 ID NC 5 GND GND SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated ADS1x9xECG-FE Demonstration Kit 39 www.ti.com Appendix A ECG Cable Details The DB9 ECG connector uses the following pin out. Pin Electrode Name 1 RA 2 LA 3 LL 4 RL 5 Open 6 Open 7 Open 8 Shield 9 Shield Figure 48. ECG Cable Drawing The ECG cable can be ordered through http://www.biometriccables.com/ using the part number N26082011. 40 ECG Cable Details SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated www.ti.com Appendix B ADS1x9x EVM Bill of Materials (BOM) The following pages show the bill of materials table, landscaped for readability. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback ADS1x9x EVM Bill of Materials (BOM) Copyright © 2011–2012, Texas Instruments Incorporated 41 Appendix B www.ti.com Table 1. Bill of Materials Quantity Item ADS1292R ADS1292 ADS1192 1 1 1 1 2 0 0 0 ANT1 Not Installed Not Installed Description Printed Wiring Board Manufacturer Part Number TI 6525569 3 0 0 0 C1 ,C2, C3, C4, C5, C11, C12, C20, C26, C51, C54, C55, C57, C61, C69, C71, C73, C74, C78, C79, C80, C83, C89, C90, C91, C92 4 10 10 10 C6, C34, C35, C36, C38, C41, CAP CER 10UF 6.3V X5R 20% 0603 C43, C65, C70, C85 AVX 06036D106MAT2A 5 4 4 4 C7, C8, C21, C25 AVX 04025U100CAT2A TDK C1005X7R1C104K CAP CER 4700PF 10V 0402 LOW DIST Taiyo Yuden LMK105SD472KV-F CAP CER 4700PF 10V 0402 LOW DIST Taiyo Yuden LMK105SD472KV-F CAP CER 0.047UF 10V 10% X7R 0402 Murata GRM155R71A473KA01D CAP CERM 1.0UF 10% 6.3V X5R 0402 AVX 04026D105KAT2A CAP CER 10PF 50V NP0 RF 0402 6 18 18 18 C9, C13, C15, C19, C28, C31, C33, C39, C44, C52, C63, CAP CER 0.1UF 16V X7R 0402 C64,C67, C72, C76, C77, C84, C87 7 2 2 2 C10 0 1 1 1 0 0 8 42 Ref Des C24 9 8 8 8 C14, C18, C22, C27, C40, C58, C86, C88 10 0 0 0 C16, C59, C62 Not Installed 11 2 2 2 C17, C66 CAP CER 0.22UF 16V X7R 0402 Murata GRM155R71C224KA12D 12 1 1 1 C23 CAP CER 1500PF 50V X7R 0402 AVX 04025C152JAT2A 13 2 2 2 C29, C30 CAP CER 12PF 5% 50V NP0 0402 AVX 04025A120JAT2A 14 1 1 1 C32 CAP CER 0.47UF 16V X5R 0402 TDK C1005X5R1C474K 15 3 3 3 C37, C81, C82 CAP CER 2.2UF 4.0V X5R 20% 0402 AVX 04024D225MAT2A 16 2 2 2 C42, C75 CAP CERM 10000PF 5% 16V X7R 0402 AVX 0402YC103JAT2A 17 2 0 0 C45, C47 CAP CERM 2200PF 10% 50V X7R 0402 AVX 04025C222KAT2A 18 2 0 0 CAP CER 0.1UF 16V X7R 0402 TDK C1005X7R1C104K 19 0 2 2 RES 0.0 OHM 1/10W 0402 SMD Panasonic ERJ-2GE0R00X 20 2 0 0 CAP CERM 2200PF 10% 50V X7R 0402 AVX 04025C222KAT2A 21 0 2 2 RES 0.0 OHM 1/10W 0402 SMD Panasonic ERJ-2GE0R00X 22 1 1 1 C53 CAP CER 4.7UF 6.3V X5R 0402 Murata GRM155R60J475ME87D 23 2 2 2 C56, C60 CAP CERM 47PF 5% 50V NP0 0402 AVX 04025A470JAT2A 24 1 1 1 C68 CAP TANT 22UF 6.3V 20% 0805 AVX TACH226M006XTA 25 1 1 1 D1 LED 470NM BLUE CLEAR 0603 SMD Rohm SMLE12BC7TT86 26 1 1 1 D2 LED 565NM GRN DIFF 0603 SMD Lumex SML-LX0603GW-TR 27 1 1 1 D3 DIODE SCHOTTKY 400MW 20V SOD123 Diodes Inc SD103CW-13-F 28 0 0 0 D4 Not Installed 29 0 0 0 L1, L2 Not Installed C46,C48 C49, C50 ADS1x9x EVM Bill of Materials (BOM) SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Appendix B www.ti.com Table 1. Bill of Materials (continued) Quantity Item ADS1292R ADS1292 ADS1192 30 1 1 1 L3 Ref Des FERRITE CHIP 120 OHM 2000MA 0603 Description Murata Manufacturer BLM18PG121SN1D Part Number 31 2 2 2 L4,L7 FILTER CHIP 220 OHM 2A 0603 Murata BLM18EG221SN1D 32 1 1 1 L5 INDUCTOR POWER 3.3UH 1.3A SMD TDK VLF4012AT-3R3M1R3 33 0 0 0 L6 Not Installed 34 0 0 0 O1 Not Installed 35 1 1 1 O2 CRYSTAL 24.0000MHZ 10PF SMD Abracon ABM3B-24.000MHZ-10-1-U-T 36 1 1 1 O3 CRYSTAL 32.768KHZ 12.5PF SMD Abracon ABS07-32.768KHZ-T 37 1 1 1 P1 CONN RCPT MINIUSB B 5POS SMD R/A Molex Inc 513870530 38 0 0 0 P2 Not Installed 39 1 1 1 P3 3 pin Connector Samtec SSW-103-02-S-S-RA 40 0 0 0 P4 Not Installed 41 1 1 1 P5 CONN D-SUB RCPT R/A 9POS GOLD/FL TE Connectivity 1734354-1 42 0 0 0 P6 Not Installed 43 1 1 1 Q1 TRANSISTOR NPN 25V 50MA SOT-23 On Semi MMBT5089LT1G Not Installed 44 0 0 0 R1, R3, R5, R6, R7, R8, R9, R13, R15, R17, R21, R22, R24, R25, R28, R39, R41, R42, R47, R65, R67, R68, R74, R76, R78, R79, R80, R81, R83, R86, R88, R89, R90, R91, R92, R93, R96, R103 45 0 0 0 R2 Not Installed RES 0.0 OHM .33W 0805 SMD Vishay/Dale CRCW08050000Z0EAHP 46 7 7 7 R4, R46, R60, R97, R108, R111, R114 47 2 2 2 R10, R36 RES 1.0M OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ105X 48 3 3 3 R11, R12, R20 RES 33 OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ330X 49 1 1 1 R14 RES 1.40K OHM 1/10W 1% 0402 SMD Panasonic ERJ-2RKF1401X 1 0 0 R16 1 1 1 R73 RES 51K OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ513X 0 1 1 R85 15 15 15 R18, R19, R29, R30, R31, R32, R33, R34, R38, R48, R52, R53, R77, R94, R95 RES 10K OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ103X RES 0.0 OHM 1/10W 0402 SMD Panasonic ERJ-2GE0R00X RES 100K OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ104X 50 51 52 22 22 22 R23, R26, R27, R37, R40, R44, R45, R49, R51, R54, R55, R75, R84, R98, R99, R100, R102, R105, R106, R109, R110, R113 53 2 2 2 R35, R117 SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback ADS1x9x EVM Bill of Materials (BOM) Copyright © 2011–2012, Texas Instruments Incorporated 43 Appendix B www.ti.com Table 1. Bill of Materials (continued) Quantity Item ADS1292R ADS1292 ADS1192 54 3 3 3 R43, R101,R107 RES 1.0K OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ102X 55 1 1 1 R50 RES 33K OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ333X 56 1 1 1 R56 RES 130 OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ131X 57 1 1 1 R57 RES 220 OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ221X 58 1 1 1 R58 RES 47K OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ473X 59 1 1 1 R59 RES 46.4K OHM 1/10W 1% 0402 SMD Panasonic ERJ-2RKF4642X 60 1 1 1 R61 RES 30.9K OHM 1/10W 1% 0402 SMD Panasonic ERJ-2RKF3092X 61 4 0 0 R62, R64, R66, R72 RES 10.0M OHM 1/16W 1% 0402 SMD Panasonic CRCW040210M0FKED 62 2 0 0 RES 0.0 OHM 1/10W 0402 SMD Panasonic ERJ-2GE0R00X 63 0 2 2 RES 51K OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ513X 64 2 0 0 R69, R70 RES 40K OHM 0.15W 0.1% 0603 Vishay/Thin Film PAT0603E4002BST1 65 2 2 2 R82, R115 RES 100 OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ101X 66 0 0 0 R87 Not Installed 67 1 1 1 R104 RES 4.7K OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ472X 68 1 1 1 R112 RES 10 OHM 1/10W 5% 0402 SMD Panasonic ERJ-2GEJ100X 69 2 2 2 R116, R118 RES 0.0 OHM 1/10W 0402 SMD Panasonic ERJ-2GE0R00X 70 2 2 2 SW1,SW4 SWITCH LT 6MM 160GF 5MM HEIGHT Panasonic EVQ-21505R 71 2 2 2 SW2,SW3 SWITCH TACT 2.36MM SILVR G-WING C&K Components KT11P2SM34LFS 72 0 0 0 TP1-TP60 73 0 0 0 U1 Not Installed 74 1 1 1 U2 4-Channel ESD-Protection Array Texas Instruments TPD4E004DRYR 75 0 0 0 U3 Not Installed 76 0 0 0 U4 Not Installed 77 1 0 0 2 channel Analog to Digital Converter (24 bit with resp) Texas Instruments ADS1292RIPBS 2 channel Analog to Digital Converter (24 bit) Texas Instruments ADS1292IPBS 2 channel Analog to Digital Converter (16 bit) Texas Instruments ADS1192IPBS 44 Ref Des R63, R71 U5 Description Manufacturer Part Number 78 0 1 0 79 0 0 1 80 1 1 1 U7 MSP Microcontroller Texas Instruments MSP430F5529IPNR 81 1 1 1 U8 Power-Path Management IC Texas Instruments BQ24032ARHLR 82 1 1 1 U9 2 bit Voltage Level Shfter Texas Instruments TXS0102DCTR 83 1 1 1 U10 3V Low-Dropout Regulator Texas Instruments TPS73201DBVT 84 0 0 0 U11 Not Installed 85 0 0 0 U12 Not Installed 86 0 0 0 U13 Not Installed 87 1 1 1 U14 8Gb NAND Flash Micron MT29F8G08ABABAWP:B 88 0 0 0 U15 Not Installed ADS1x9x EVM Bill of Materials (BOM) SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Appendix B www.ti.com Table 1. Bill of Materials (continued) Quantity Item ADS1292R ADS1292 ADS1192 89 1 1 1 U16 Ref Des 3.3V Linear Regulator Description 90 0 0 0 U17 Not Installed 91 1 1 1 U18 Manufacturer Part Number Texas Instruments TPS73033DBVR 3.3V supervisors Texas Instruments TPS3825-33DBVT Battery Assembly 92 0 0 0 Connector on battery CONN HOUSING 2POS .100 W/O RAMP Molex 22012021 93 0 0 0 Connector on battery CONN TERM CRIMP 18-24AWG TIN Molex 8030303 94 0 0 0 Battery 4.2V Li Ion Battery Power Stream GM065080 95 0 0 0 Battery Cable 22 AWG red color cable 96 0 0 0 Battery Cable 22 AWG black color cable SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback ADS1x9x EVM Bill of Materials (BOM) Copyright © 2011–2012, Texas Instruments Incorporated 45 www.ti.com Appendix C PCB Layout and Schematics C.1 PCB Layout The following pages show the PCB layout, landscaped for readability. 46 PCB Layout and Schematics SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated PCB Layout www.ti.com Figure 49. Top Layer Placement SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback PCB Layout and Schematics Copyright © 2011–2012, Texas Instruments Incorporated 47 PCB Layout www.ti.com Figure 50. Bottom Layer Placement 48 PCB Layout and Schematics SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated Schematics www.ti.com C.2 Schematics The schematics are appended to the end of this data sheet. SLAU384A – December 2011 – Revised April 2012 Submit Documentation Feedback Copyright © 2011–2012, Texas Instruments Incorporated PCB Layout and Schematics 49 5 4 3 Power Module Battery D 2 1 USB To PC D Application Power Data C 1.ADS1292R - 24 bit 2 Ch -- 1 Ch ECG -- 1 Ch Respiration BT Module USB I2C C 2.ADS1292 - 24 bit 2 Ch -- 2 Ch ECG 3.ADS1192 - 16 bit 2 Ch -- 2 Ch ECG UART SPI JTAG B B GPIO Flash Memory GPIO SPI LEDs & Keys Micro SD Optional Must have modules A A Title Block Diagram Size B Date: 5 4 3 2 Document Number ADS1x9xECG FE Thursday, August 04, 2011 Rev A Sheet 1 1 of 7 5 4 3 2 1 ADS_AVDD DNI C71 NI Place the decoupling capacitors close to power pins in layout ADS_DVDD 5 U15 R41 D + 3 NI 2 - 4 R35 C14 C15 100K 1uF 0.1uF 1uF R37 TP15 ERL 0E C69 R36 C23 1M ADS_DVDD C60 C56 47pF 47pF AVSS C49 2.2nF 1 AVSS 1 0.1uF 1 1 1 TP42 TP52 TP53 TP47 1 23 24 25 26 0E 0E 0E 0E 0E 0E 0E R54 R55 R26 R23 R27 R44 R45 ADC_CS ADC_START ADC_DIN ADC_SCLK ADC_DOUT ADC_DRDY ADC_RESET ADC_CLK ADS_DVDD 2 PGA1N 1 VCAP1 VCAP2 11 27 C24 4.7nF O1 C58 1uF C4 NI 4 VDD ENB 1 OUT GND 2 TP34 AVSS R70 External Clock R77 C90 NI AVSS C R2 NI C22 1uF ADS_DVDD TP38 DNI 0E RESP_MOD_P 40K R21 R69 40K C6 C9 10uF 0.1uF RESP_MOD_M AVSS B NI NI 10K ADC_CLK_SCL AVSS C87 C45 2.2nF C19 3 R62 10M (1%) C47 2.2nF PGA2N ADS1292R R63 0.1uF 7 18 16 19 20 21 22 15 17 DNI C89 NI R64 10M (1%) PGA2P 12 13 14 R72 PGA1P ADS_AVDD C46 0E C10 4.7nF 0E 10M (1%) R118 8 NI R71 ADS_AVDD IN1P IN1N RESP_MODP/IN3P RESP_MODN/IN3N C88 2.2nF C91 AVSS C50 0E 0.1uF IN2P IN2N 4 3 31 32 DNI R66 10M (1%) C48 6 5 NI 51K 1 1 51K DNI 1uF 0.1uF R85 ELL R73 C92 CS# START DIN SCLK DOUT DRDY# PWDN#/RESET# CLK AVDD AVSS CLKSEL NI VREFP VREFN R16 DVDD DGND GPIO2/RCLK2 GPIO1/RCLK1 DNI ADS_AVDD B RLDINV RLDOUT RLDIN/RLDREF U5 100K 482016042 R116 28 30 29 R117 ERL ELL ELA ERA 9 10 11 10 C 1 TP24 ADC_GPIO2 ADC_GPIO1 R34 10K TP56 R32 10K P5 5 9 4 8 3 7 2 6 1 C18 1 1.5nF AVSS TP11 NI TP46 1 TP16 ECG_SHD_DRV 1 NI 1 D R76 DNI NI Note: For two channel ECG Do the following modification 1) Mount 51K resistor in place of R71 and R63 A 2) Mount 0 Ohm resistors in place of C48, C46, C49 and C50 ADS_DVDD VCC_3_3 3) Make following components DNI R66, R64, R72, R62, C47,C45,R70 and R69 R4 A 0E L3 Title BLM18PG121SN1P ADS1292 Size B Date: 5 4 3 2 Document Number ADS1x9xECG FE Thursday, August 04, 2011 Rev A Sheet 1 2 of 7 5 4 3 2 1 D D ADS_AVDD TP32 VCC_BAT L5 1 OUT IN 5 C 3.3uH 0E C36 10uF 1 U10 R60 C C40 1uF 3 2 R59 EN GND C37 2.2uF 46.4K NR/FB C38 10uF C41 10uF C39 0.1uF 4 AVSS TPS73201 R61 30.9K C42 0.01uF R46 0E B B AVSS A A Title ADS1292 Power Supply Size B Date: 5 4 3 2 Document Number ADS1x9xECG FE Thursday, August 04, 2011 Rev A Sheet 1 3 of 7 U14 TP41 DNI D 1 TP37 C64 0.1uF 1 1K C63 0.1uF TP33 1K C43 10uF 12 37 R107 TP36 TP59 TP10 1 1 R101 1 SD CARD 1 TP54 2 VCC_3_3 VCC_3_3 NI DNI C DNU1 DNU2 DNU3 NC17 NC16 NC15 NC18 MT298G08AAAWP 1 20 21 22 35 34 33 39 FLASH_IO0 FLASH_IO1 FLASH_IO2 FLASH_IO3 FLASH_IO4 FLASH_IO5 FLASH_IO6 FLASH_IO7 R68 R67 R65 C62 NI NI NI C78 NI NI P2 1 2 3 4 5 6 7 8 USD_CS SPI_SIMO SPI_SCLK SPI_SOMI RSV1 CS DI VCC CLK VSS DO RSV2 NI C 4 3 2 1 R93 29 30 31 32 41 42 43 44 40 45 46 47 48 28 27 25 26 5 4 3 2 1 I/O0 I/O1 I/O2 I/O3 I/O4 I/O5 I/O6 I/O7 NC19 NC20 NC21 NC22 NC23 NC14 NC13 NC11 NC12 NC5 NC4 NC3 NC2 NC1 IO4 IO3 IO2 IO1 TP55 1 R94 10K CE# CE2# CLE ALE WE# RE# R/B# R/B2# NC6 NC7 NC8 NC9 NC10 WP# VSS VSS PRE/VSS2 VCC_3_3 9 10 16 17 18 8 7 6 11 14 15 23 24 19 13 36 38 0E 0E 0E 0E 0E 0E 0E 0E R110 R106 R105 R98 R99 R109 R100 R102 FLASH_CE FLASH_CE2 FLASH_CLE FLASH_ALE FLASH_WE FLASH_RE FLASH_RB FLASH_RB2 VCC VCC 1 1 D 3 1 TP58 TP57 4 1 TP30 5 GND IO5 IO6 IO7 IO8 9 U11 NI 5 6 7 8 R75 0E B B SW1 R82 100E VUSB PUR EVQ-21505R 5% tol R14 1.4K 1% tol D3 VBUS USB_DM USB_DP R12 R11 1 2 3 4 5 + C7 10pF U2 C52 0.1uF 1 2 4 5 C8 10pF C53 4.7uF VBUS DD+ ID GND SHIELD1 SHIELD2 8 9 10 11 6 7 8 9 10 11 0513870530 IO1 IO2 IO3 IO4 R10 1M 5% tol P1 SD103AW-13-F 33E 33E A 6 VCC GND A 3 TPD4E004DRYR Title USB, Micro SD, USB Interfaces Size B Date: 5 4 3 2 Document Number ADS1x9xECG FE Thursday, August 04, 2011 Rev A Sheet 1 4 of 7 4 3 2 1 MSP_DVDD TP29 TP26 5 O2 C21 10pF 1 2 U9 3 4 3 4 ABM3B-24.000MHZ XT2OUT 1 1 2 1 XT2IN SBWTCLK SBWTDIO C25 10pF SBWTCLK TDO TDI TMS TCK D XT2OUT XT2IN VUSB C65 10uF C67 0.1uF AVCC1 AVSS1 FLASH_IO4 FLASH_IO5 FLASH_IO6 FLASH_IO7 FLASH_CE FLASH_CLE FLASH_ALE FLASH_WE FLASH_RE FLASH_CE2 C29 12pF XIN XOUT O3 ABS07-32.768KHZ-T MSP_DVDD C30 12pF ADC_RESET ADC_START ADC_CS C34 10uF 1 2 3 4 5 6 7 8 57 58 P6_4/CB4/A4 P6_5/CB5/A5 P6_6/CB6/A6 P6_7/CB7/A7 P7_0/CB8/A12 P7_1/CB9/A13 P7_2/CB10/A14 P7_3/CB11/A15 P7_4/TB0_2 P7_5/TB0_3 12 13 P5_4/XIN P5_5/XOUT 15 16 17 P8_0 P8_1 P8_2 18 DVCC1 19 20 DVSS1 VCORE 69 70 71 72 73 74 75 76 77 78 79 80 68 61 67 62 63 64 65 66 C13 0.1uF C32 470nF 6 5 4 3 2 1 VCC GND C84 0.1uF C86 1uF NC VCC CLK I/O GND NC D P4 851-93-006-20-001000 R19 10K P3_4/UCA0RXD/UCA0SOMI P3_5/TB0_5 P3_6/TB0_6 P3_7/TB0OUTH/SVMOUT P4_0/PM_UCB1STE/PM_UCA1CLK P4_1/PM_UCB1SIMO/PM_UCB1SDA P4_2/PM_UCB1SOMI/PM_UCB1SCL P4_3/PM_UCB1CLK/PM_UCA1STE 41 42 43 44 45 46 47 48 P4_4/PM_UCA1TXD/PM_UCA1SIMO P4_5/PM_UCA1RXD/PM_UCA1SOMI P4_6/PM_NONE P4_7/PM_NONE P5_6/TB0_0 P5_7/TB0_1 P7_6/TB0_4 P5_0/A8/VREF+/VEREF+ P5_1/A9/VREFN/VEREFN P7_7/TB0CLK/MCLK 51 52 53 54 55 56 59 9 10 60 DVCC2 50 DVSS2 49 R18 10K 0E R84 R20 BT_RX BAT_SCL BAT_SDA USD_CS SPI_SCLK 33E 1 1 1 C TDO TDI TMS TCK TP43 TP39 TP40 1 1 1 1 TP21 TP23 TP27 TP28 SPI_SIMO SPI_SOMI STAT2 STAT1 BT_CS1 BT_RTS R57 R56 220E 130E MSP_DVDD 1 LED1 LED2 1 TP9 TP45 C31 0.1uF B 21 22 23 24 25 26 27 28 31 30 29 32 33 34 35 36 37 38 39 40 B 1 8 6 SYS_RESET P1_0/TA0CLK/ACLK P1_1/TA0_0 P1_2/TA0_1 P1_3/TA0_2 P1_4/TA0_3 P1_5/TA0_4 P1_6/TA1CLK/CBOUT P1_7/TA1_0 P2_2/TA2CLK/SMCLK P2_1/TA1_2 P2_0/TA1_1 P2_3/TA2_0 P2_4/TA2_1 P2_5/TA2_2 P2_6/RTCCLK/DMAE0 P2_7/UCB0STE/UCA0CLK P3_0/UCB0SIMO/UCB0SDA P3_1/UCB0SOMI/UCB0SCL P3_2/UCB0CLK/UCA0STE P3_3/UCA0TXD/UCA0SIMO C 7 B2 B1 OE Q1 MMBT5089LT1G MSP_DVDD P5_2/XT2IN P5_3/XT2OUT TEST/SBWTCK PJ_0/TDO PJ_1/TDI/TCLK PJ_2/TMS PJ_3/TCK RST/NMI/SBWTDIO P6_0/CB0/A0 P6_1/CB1/A1 P6_2/CB2/A2 P6_3/CB3/A3 11 C33 0.1uF 14 VCCB TXS0102DCTR C83 NI AVSS2 VSSU V18 PU_0/DP PUR PU_1/DM VBUS VUSB C35 10uF A2 A1 GND DNI C17 220nF U7 4 5 2 R58 47K FLASH_IO0 FLASH_IO1 FLASH_IO2 FLASH_IO3 MSP_AVDD VCCA R40 0E SBWTDIO VBUS USB_DM PUR USB_DP C66 220nF 3 R83 MSP430F5529IPNR BT_TX VCC_3_3 MSP_DVDD L7 BLM21PG220SN1B D1 LED2 ADC_DOUT SMLE12BC7TT86 BLM21PG220SN1B VCC_3_3 BT_SLOW_CLK LED1 VCC_3_3 ADC_SCLK MSP_AVDD L4 D2 SMLE12EC6TT86 NI ADC_DRDY FLASH_RB BT_NSHUTDOWN FLASH_RB2 BT_CTS ADC_DIN KEY1 KEY2 C85 10uF ADC_CLK R113 R49 R24 DNI POW_CE 1 KEY2 3 2 1 NI KEY1 EVQ-21505R ADC_GPIO2 TP50 ADC_GPIO1 ADC_CLK_SCL 0E 0E SW4 R95 10K 1 C76 0.1uF TP18 4 SW2 KT11P2SM34LFS A A Title MSP430 Size B Date: 5 4 3 2 Document Number ADS1x9xECG FE Thursday, August 04, 2011 Rev A Sheet 1 5 of 7 5 4 3 R103 NI 1 RBI 2 3 VCC VSS P6 1 2 R47 NI U17 PGM 10 GPIO 9 SRP 8 BAT_P BAT_M D NI 1 TP51 TP20 1 PACK_P D 1 TP17 DNI Battery Fuel Gauge 2 R92 NI R96 NI R87 TP25 NI NI 4 BAT_SCL R90 NI 5 BAT_SDA SDA 1 7 D4 C77 0.1uF TP13 1 IN 3 EN NI BAT OUT 5 NR 4 C75 0.01uF TPS73033 C82 2.2uF C73 NI 6 C26 NI 11 NI VSS1 SRN R91 0E R88 SCL VCC_3_3 U16 R97 1 C74 NI VCC_BAT GND C80 NI 3.3V Power Supply R89 2 1 C79 NI 1 NI NI TP22 C C VCC_3_3 3.3V Voltage Supervisor POW_CE C271uF PSEL POW_CE ACPG USBPG R51 0E 1 8 9 18 19 LDO PSEL CE ACPG# USBPG#_/_VBSEL TS 12 TS ISET1 ISET2 10 7 ISET1 ISET2 STAT2 STAT1 DPPM VSS 13 11 3 2 STAT2 STAT1 VCC_3_3 DNI R42 R29 R39 DNI A R52 R53 R38 R30 R31 TS NI ISET1 10K ISET2 NI PSEL 10K 10K 10K 10K 10K R48 R43 R28 R33 BQ24032ARHLR TP48 TP49 1 1 STAT2 STAT1 BAT2 BAT1 10K 1K NI 10K 6 5 U18 4.7K 1 C28 0.1uF USB TMR TP C72 0.1uF SW3 15 16 17 20 14 21 C70 10uF OUT3 OUT2 OUT1 3 2 R112 4 5 VDD 4 MR# 10E KT11P2SM34LFS PACK_P TP60 C20 NI VBUS B R104 1 C16 NI C44 0.1uF VCC_BAT AC RESET# 1 RESET 3 R115 C81 2.2uF 1 U8 4 GND TP31 DNI SYS_RESET 100E 2 Battery Management TPS3825 B C68 22uF R50 ADS_AVDD 33K P3 SSW-103-02-S-S-RA 0E R108 DNI AVSS ACPG USBPG POW_CE STAT2 STAT1 R111 R114 0E 0E 3 3 1 1 2 2 A Title Power Supply Size B Date: 5 4 3 2 Document Number ADS1x9xECG FE Thursday, August 04, 2011 Rev A Sheet 1 6 of 7 5 4 3 1 TP8 DNI VCC_3_3 1 TP5 2 L6 U1 ANT1 D 1 D L1 R9 R8 R7 R6 NI NI 6 5 4 3 NI NI HCI_TX HCI_RX HCI_RTS HCI_CTS RF 13 1 1 VDD_IO 22 NI BT_CS1 SPI_SCLK SPI_SIMO SPI_SOMI C3 R79 NI R80 R81 NI NI 12 9 11 10 CS# SCLK MOSI MISO/GDO1 VDD 18 VDCOUP1 VDCOUP2 7 15 GDO2 GDO0 14 13 NC4 NC5 NC6 DNC4 DNC5 DNC6 19 21 20 24 23 22 NI VCC_3_3 23 21 CL1_5_LDO_IN MLDO_IN MLDO_OUT NI R5 SLOW_CLK I2C_SCL I2C_SDA 8 11 15 10 C2 NI SLOW_CLK_IN R3 TP3 TP2 1 1 9 24 16 1 2 3 4 5 6 NI IO2 IO1 NC DNC1 DNC2 DNC3 NC1 NC2 NC3 GND GND TP6 TP7 AUD_FSYNC AUD_CLK AUD_IN AUD_OUT NI NI U12 L2 C1 NI VCC_1_8 7 19 18 17 R78 NI NI NI C57 GDO2 1 TP44 R1 C NSHUTD 16 SHUTDOWN NI C TX_DBG NI TP35 1 12 14 20 GND GND GND GND 2 1 TP4 TP1 1 NI 8 17 PAN_TX PAN_RX PAN_RTS PAN_CTS C59 NI VCC_3_3 VCC_1_8 U13 NI C55 VCC_3_3 16 3 4 5 6 BT_TX BT_RTS BT_RX BT_IN_CTS 1 2 9 R25 NI NI VCCA A1 A2 A3 A4 DIR1 DIR2 OE# OUT 4 3 EN GND NC1 NC2 2 5 C5 C51 NI NI 1.8V VCC_3_3 C54 NI U4 GND R17 NI VCCB 15 B1 B2 B3 B4 14 13 12 11 DIR3 DIR4 B PAN_RX PAN_CTS PAN_TX PAN_RTS U3 C61 NI 7 8 R15 NI SLOW_CLK SHUTDOWN 1 VCCA 5 DIR 2 3 4 VCCB 8 B1 B2 7 6 R86 C12 NI A1 A2 GND GDO2 BT_CTS R13 NI DNI R86 R22 NI BT_IN_CTS BT_SLOW_CLK BT_NSHUTDOWN 10 C11 NI IN 1 NI VCC_1_8 VCC_1_8 B 6 1 NI R74 R13 Description NI Mount NI Do Not Mount Do Not Mount When PANI315 Bluetooth module is used (Default) Mount When A1101R09A Bluetooth module is used A A Title Bluetooth Module Size B Date: 5 4 3 2 Document Number ADS1x9xECG FE Thursday, August 04, 2011 Rev A Sheet 1 7 of 7 Evaluation Board/Kit Important Notice Texas Instruments (TI) provides the enclosed product(s) under the following conditions: This evaluation board/kit is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION, OR EVALUATION PURPOSES ONLY 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