SBAS499C July   2012  – January 2017 ADS1299 , ADS1299-4 , ADS1299-6

PRODUCTION DATA.  

  1. Features
  2. Applications
  3. Description
  4. Revision History
  5. Device Comparison
  6. Pin Configuration and Functions
  7. Specifications
    1. 7.1 Absolute Maximum Ratings
    2. 7.2 ESD Ratings
    3. 7.3 Recommended Operating Conditions
    4. 7.4 Thermal Information
    5. 7.5 Electrical Characteristics
    6. 7.6 Timing Requirements: Serial Interface
    7. 7.7 Switching Characteristics: Serial Interface
    8. 7.8 Typical Characteristics
  8. Parametric Measurement Information
    1. 8.1 Noise Measurements
  9. Detailed Description
    1. 9.1 Overview
    2. 9.2 Functional Block Diagram
    3. 9.3 Feature Description
      1. 9.3.1 Analog Functionality
        1. 9.3.1.1 Input Multiplexer
          1. 9.3.1.1.1 Device Noise Measurements
          2. 9.3.1.1.2 Test Signals (TestP and TestN)
          3. 9.3.1.1.3 Temperature Sensor (TempP, TempN)
          4. 9.3.1.1.4 Supply Measurements (MVDDP, MVDDN)
          5. 9.3.1.1.5 Lead-Off Excitation Signals (LoffP, LoffN)
          6. 9.3.1.1.6 Auxiliary Single-Ended Input
        2. 9.3.1.2 Analog Input
        3. 9.3.1.3 PGA Settings and Input Range
          1. 9.3.1.3.1 Input Common-Mode Range
          2. 9.3.1.3.2 Input Differential Dynamic Range
          3. 9.3.1.3.3 ADC ΔΣ Modulator
          4. 9.3.1.3.4 Reference
      2. 9.3.2 Digital Functionality
        1. 9.3.2.1 Digital Decimation Filter
          1. 9.3.2.1.1 Sinc Filter Stage (sinx / x)
        2. 9.3.2.2 Clock
        3. 9.3.2.3 GPIO
        4. 9.3.2.4 ECG and EEG Specific Features
          1. 9.3.2.4.1 Input Multiplexer (Rerouting the BIAS Drive Signal)
          2. 9.3.2.4.2 Input Multiplexer (Measuring the BIAS Drive Signal)
          3. 9.3.2.4.3 Lead-Off Detection
            1. 9.3.2.4.3.1 DC Lead-Off
            2. 9.3.2.4.3.2 AC Lead-Off (One Time or Periodic)
          4. 9.3.2.4.4 Bias Lead-Off
          5. 9.3.2.4.5 Bias Drive (DC Bias Circuit)
            1. 9.3.2.4.5.1 Bias Configuration with Multiple Devices
    4. 9.4 Device Functional Modes
      1. 9.4.1 Start
        1. 9.4.1.1 Settling Time
      2. 9.4.2 Reset (RESET)
      3. 9.4.3 Power-Down (PWDN)
      4. 9.4.4 Data Retrieval
        1. 9.4.4.1 Data Ready (DRDY)
        2. 9.4.4.2 Reading Back Data
      5. 9.4.5 Continuous Conversion Mode
      6. 9.4.6 Single-Shot Mode
    5. 9.5 Programming
      1. 9.5.1 Data Format
      2. 9.5.2 SPI Interface
        1. 9.5.2.1 Chip Select (CS)
        2. 9.5.2.2 Serial Clock (SCLK)
        3. 9.5.2.3 Data Input (DIN)
        4. 9.5.2.4 Data Output (DOUT)
      3. 9.5.3 SPI Command Definitions
        1. 9.5.3.1  Sending Multi-Byte Commands
        2. 9.5.3.2  WAKEUP: Exit STANDBY Mode
        3. 9.5.3.3  STANDBY: Enter STANDBY Mode
        4. 9.5.3.4  RESET: Reset Registers to Default Values
        5. 9.5.3.5  START: Start Conversions
        6. 9.5.3.6  STOP: Stop Conversions
        7. 9.5.3.7  RDATAC: Read Data Continuous
        8. 9.5.3.8  SDATAC: Stop Read Data Continuous
        9. 9.5.3.9  RDATA: Read Data
        10. 9.5.3.10 RREG: Read From Register
        11. 9.5.3.11 WREG: Write to Register
    6. 9.6 Register Maps
      1. 9.6.1 User Register Description
        1. 9.6.1.1  ID: ID Control Register (address = 00h) (reset = xxh)
        2. 9.6.1.2  CONFIG1: Configuration Register 1 (address = 01h) (reset = 96h)
        3. 9.6.1.3  CONFIG2: Configuration Register 2 (address = 02h) (reset = C0h)
        4. 9.6.1.4  CONFIG3: Configuration Register 3 (address = 03h) (reset = 60h)
        5. 9.6.1.5  LOFF: Lead-Off Control Register (address = 04h) (reset = 00h)
        6. 9.6.1.6  CHnSET: Individual Channel Settings (n = 1 to 8) (address = 05h to 0Ch) (reset = 61h)
        7. 9.6.1.7  BIAS_SENSP: Bias Drive Positive Derivation Register (address = 0Dh) (reset = 00h)
        8. 9.6.1.8  BIAS_SENSN: Bias Drive Negative Derivation Register (address = 0Eh) (reset = 00h)
        9. 9.6.1.9  LOFF_SENSP: Positive Signal Lead-Off Detection Register (address = 0Fh) (reset = 00h)
        10. 9.6.1.10 LOFF_SENSN: Negative Signal Lead-Off Detection Register (address = 10h) (reset = 00h)
        11. 9.6.1.11 LOFF_FLIP: Lead-Off Flip Register (address = 11h) (reset = 00h)
        12. 9.6.1.12 LOFF_STATP: Lead-Off Positive Signal Status Register (address = 12h) (reset = 00h)
        13. 9.6.1.13 LOFF_STATN: Lead-Off Negative Signal Status Register (address = 13h) (reset = 00h)
        14. 9.6.1.14 GPIO: General-Purpose I/O Register (address = 14h) (reset = 0Fh)
        15. 9.6.1.15 MISC1: Miscellaneous 1 Register (address = 15h) (reset = 00h)
        16. 9.6.1.16 MISC2: Miscellaneous 2 (address = 16h) (reset = 00h)
        17. 9.6.1.17 CONFIG4: Configuration Register 4 (address = 17h) (reset = 00h)
  10. 10Applications and Implementation
    1. 10.1 Application Information
      1. 10.1.1 Unused Inputs and Outputs
      2. 10.1.2 Setting the Device for Basic Data Capture
        1. 10.1.2.1 Lead-Off
        2. 10.1.2.2 Bias Drive
      3. 10.1.3 Establishing the Input Common-Mode
      4. 10.1.4 Multiple Device Configuration
        1. 10.1.4.1 Cascaded Mode
        2. 10.1.4.2 Daisy-Chain Mode
    2. 10.2 Typical Application
      1. 10.2.1 Design Requirements
      2. 10.2.2 Detailed Design Procedure
      3. 10.2.3 Application Curves
  11. 11Power Supply Recommendations
    1. 11.1 Power-Up Sequencing
    2. 11.2 Connecting the Device to Unipolar (5 V and 3.3 V) Supplies
    3. 11.3 Connecting the Device to Bipolar (±2.5 V and 3.3 V) Supplies
  12. 12Layout
    1. 12.1 Layout Guidelines
    2. 12.2 Layout Example
  13. 13Device and Documentation Support
    1. 13.1 Documentation Support
      1. 13.1.1 Related Documentation
    2. 13.2 Related Links
    3. 13.3 Receiving Notification of Documentation Updates
    4. 13.4 Community Resources
    5. 13.5 Trademarks
    6. 13.6 Electrostatic Discharge Caution
    7. 13.7 Glossary
  14. 14Mechanical, Packaging, and Orderable Information

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発注情報

Detailed Description

Overview

The ADS1299-x is a low-noise, low-power, multichannel, simultaneously-sampling, 24-bit, delta-sigma (ΔΣ) analog-to-digital converter (ADC) with an integrated programmable gain amplifier (PGA). These devices integrate various EEG-specific functions that makes the family well-suited for scalable electrocardiogram (ECG), electroencephalography (EEG) applications. These devices can also be used in high-performance, multichannel, data acquisition systems by powering down the ECG or EEG-specific circuitry.

The devices have a highly-programmable multiplexer that allows for temperature, supply, input short, and bias measurements. Additionally, the multiplexer allows any input electrodes to be programmed as the patient reference drive. The PGA gain can be chosen from one of seven settings (1, 2, 4, 6, 8, 12, and 24). The ADCs in the device offer data rates from 250 SPS to 16 kSPS. Communication to the device is accomplished using an SPI-compatible interface. The device provides four general-purpose input/output (GPIO) pins for general use. Multiple devices can be synchronized using the START pin.

The internal reference generates a low noise 4.5 V internal voltage when enabled and the internal oscillator generates a 2.048-MHz clock when enabled. The versatile patient bias drive block allows the average of any electrode combination to be chosen in order to generate the patient drive signal. Lead-off detection can be accomplished by using a current source or sink. A one-time, in-band, lead-off option and a continuous, out-of-band, internal lead-off option are available.

Functional Block Diagram

ADS1299 ADS1299-4 ADS1299-6 ai_fbd_small_bas499.gif

Feature Description

This section contains details of the ADS1299-x internal functional elements. The analog blocks are discussed first, followed by the digital interface. Blocks implementing EEG-specific functions are covered at the end of this section.

Throughout this document, fCLK denotes the CLK pin signal frequency, tCLK denotes the CLK pin signal period, fDR denotes the output data rate, tDR denotes the output data time period, and fMOD denotes the frequency at which the modulator samples the input.

Analog Functionality

Input Multiplexer

The ADS1299-x input multiplexers are very flexible and provide many configurable signal-switching options. Figure 18 shows the multiplexer on a single channel of the device. Note that the device has either four (ADS1299-4), six (ADS1299-6) or eight (ADS1299) such blocks, one for each channel. SRB1, SRB2, and BIASIN are common to all blocks. INxP and INxN are separate for each of the four, six, or eight blocks. This flexibility allows for significant device and sub-system diagnostics, calibration, and configuration. Switch setting selections for each channel by writing the appropriate values to the CHnSET[3:0] register (see the CHnSET: Individual Channel Settings section for details) using the BIAS_MEAS bit in the CONFIG3 register and the SRB1 bit in the MISC1 register (see the CONFIG3: Configuration Register 3 subsection of the Register Maps section for details). See the Input Multiplexer section for further information regarding the EEG-specific features of the multiplexer.

ADS1299 ADS1299-4 ADS1299-6 ai_in_mux_bas499.gif
MAIN is equal to either MUX[2:0] = 000, MUX[2:0] = 110, or MUX[2:0] = 111.
Figure 18. Input Multiplexer Block for One Channel

Device Noise Measurements

Setting CHnSET[2:0] = 001 sets the common-mode voltage of [(VVREFP + VVREFN) / 2] to both channel inputs. This setting can be used to test inherent device noise in the user system.

Test Signals (TestP and TestN)

Setting CHnSET[2:0] = 101 provides internally-generated test signals for use in sub-system verification at power-up. This functionality allows the device internal signal chain to be tested out.

Test signals are controlled through register settings (see the CONFIG2: Configuration Register 2 subsection in the Register Maps section for details). TEST_AMP controls the signal amplitude and TEST_FREQ controls switching at the required frequency.

Temperature Sensor (TempP, TempN)

The ADS1299-x contains an on-chip temperature sensor. This sensor uses two internal diodes with one diode having a current density 16x that of the other, as shown in Figure 19. The difference in diode current densities yields a voltage difference proportional to absolute temperature.

As a result of the low thermal resistance of the package to the printed circuit board (PCB), the internal device temperature tracks PCB temperature closely. Note that self-heating of the ADS1299-x causes a higher reading than the temperature of the surrounding PCB.

The scale factor of Equation 3 converts the temperature reading to degrees Celsius. Before using this equation, the temperature reading code must first be scaled to microvolts.

Equation 3. ADS1299 ADS1299-4 ADS1299-6 q_temp_bas459.gif
ADS1299 ADS1299-4 ADS1299-6 ai_temp_sense_msr_bas459.gif Figure 19. Temperature Sensor Measurement in the Input

Supply Measurements (MVDDP, MVDDN)

Setting CHnSET[2:0] = 011 sets the channel inputs to different supply voltages of the device.
For channels 1, 2, 5, 6, 7, and 8, (MVDDP – MVDDN) is [0.5 × (AVDD + AVSS)].

For channels 3 and 4, (MVDDP – MVDDN) is DVDD / 4.

To avoid saturating the PGA when measuring power supplies, set the gain to 1.

Lead-Off Excitation Signals (LoffP, LoffN)

The lead-off excitation signals are fed into the multiplexer before the switches. The comparators that detect the lead-off condition are also connected to the multiplexer block before the switches. For a detailed description of the lead-off block, see the Lead-Off Detection section.

Auxiliary Single-Ended Input

The BIASIN pin is primarily used for routing the bias signal to any electrodes in case the bias electrode falls off. However, the BIASIN pin can be used as a multiple single-ended input channel. The signal at the BIASIN pin can be measured with respect to the voltage at the BIASREF pin using any of the eight channels. This measurement is done by setting the channel multiplexer setting to '010' and the BIAS_MEAS bit of the CONFIG3 register to '1'.

Analog Input

The analog inputs to the device connect directly to an integrated low-noise, low-drift, high input impedance, programmable gain amplifier. The amplifier is located following the individual channel multiplexer.

The ADS1299-x analog inputs are fully differential. The differential input voltage (VINxP – VINxN) can span from –VREF / gain to VREF / gain. See the Data Format section for an explanation of the correlation between the analog input and digital codes. There are two general methods of driving the ADS1299-x analog inputs: pseudo-differential or fully-differential, as shown in Figure 20, Figure 21, and Figure 22.

ADS1299 ADS1299-4 ADS1299-6 ai_drv_methods_sbas705.gif Figure 20. Methods of Driving the ADS1299-x: Pseudo-Differential or Fully Differential
ADS1299 ADS1299-4 ADS1299-6 ai_pseudo_diff_mode_bas705.gif Figure 21. Pseudo-Differential Input Mode
ADS1299 ADS1299-4 ADS1299-6 ai_fully_diff_mode_bas705.gif Figure 22. Fully-Differential Input Mode

Hold the INxN pin at a common voltage, preferably at mid supply, to configure the fully differential input for a pseudo-differential signal. Swing the INxP pin around the common voltage –VREF / gain to VREF / gain and remain within the absolute maximum specifications. The common-mode voltage (VCM) changes with varying signal level when the inputs are configured in pseudo-differential mode. Verify that the differential signal at the minimum and maximum points meets the common-mode input specification discussed in the Input Common-Mode Range section.

Configure the signals at INxP and INxN to be 180° out-of-phase centered around a common voltage to use a fully differential input method. Both the INxP and INxN inputs swing from the common voltage + ½ VREF / gain to the common voltage – ½ VREF / gain. The differential voltage at the maximum and minimum points is equal to –VREF / gain to VREF / gain and centered around a fixed common-mode voltage (VCM). Use the ADS1299-x in a differential configuration to maximize the dynamic range of the data converter. For optimal performance, the common voltage is recommended to be set at the midpoint of the analog supplies [(AVDD + AVSS) / 2].

PGA Settings and Input Range

The low-noise PGA is a differential input and output amplifier, as shown in Figure 23. The PGA has seven gain settings (1, 2, 4, 6, 8, 12, and 24) that can be set by writing to the CHnSET register (see the CHnSET: Individual Channel Settings subsection of the Register Maps section for details). The ADS1299-x has CMOS inputs and therefore has negligible current noise. Table 5 shows the typical bandwidth values for various gain settings. Note that Table 5 shows small-signal bandwidth. For large signals, performance is limited by PGA slew rate.

ADS1299 ADS1299-4 ADS1299-6 ai_pga_implement_bas499.gif Figure 23. PGA Implementation

Table 5. PGA Gain versus Bandwidth

GAIN NOMINAL BANDWIDTH AT ROOM TEMPERATURE (kHz)
1 662
2 332
4 165
6 110
8 83
12 55
24 27

The PGA resistor string that implements the gain has 39.6 kΩ of resistance for a gain of 12. This resistance provides a current path across the PGA outputs in the presence of a differential input signal. This current is in addition to the quiescent current specified for the device in the presence of a differential signal at the input.

Input Common-Mode Range

To stay within the linear operating range of the PGA, the input signals must meet certain requirements that are discussed in this section.

The outputs of the amplifiers in Figure 23 cannot swing closer to the supplies (AVSS and AVDD) than 200 mV. If the outputs of the amplifiers are driven to within 200 mV of the supply rails, then the amplifiers saturate and consequently become nonlinear. To prevent this nonlinear operating condition, the output voltages must not exceed the common-mode range of the front-end.

The usable input common-mode range of the front-end depends on various parameters, including the maximum differential input signal, supply voltage, PGA gain, and the 200 mV for the amplifier headroom. This range is described in Equation 4:

Equation 4. ADS1299 ADS1299-4 ADS1299-6 q_cm_rng_bas459.gif

where

For example:

If AVDD = 5 V, gain = 12, and VMAX_DIFF = 350 mV

Then 2.3 V < CM < 2.7 V

Input Differential Dynamic Range

The differential input voltage range (VINxP – VINxN) depends on the analog supply and reference used in the system. This range is shown in Equation 5.

Equation 5. ADS1299 ADS1299-4 ADS1299-6 q_fsr_bas459.gif

ADC ΔΣ Modulator

Each ADS1299-x channel has a 24-bit, ΔΣ ADC. This converter uses a second-order modulator optimized for low-noise applications. The modulator samples the input signal at the rate of (fMOD = fCLK / 2). As in the case of any ΔΣ modulator, the device noise is shaped until fMOD / 2, as shown in Figure 24. The on-chip digital decimation filters explained in the next section can be used to filter out the noise at higher frequencies. These on-chip decimation filters also provide antialias filtering. This ΔΣ converter feature drastically reduces the complexity of the analog antialiasing filters typically required with nyquist ADCs.

ADS1299 ADS1299-4 ADS1299-6 G001_BAS499.png Figure 24. Modulator Noise Spectrum Up To 0.5 × fMOD

Reference

Figure 25 shows a simplified block diagram of the ADS1299-x internal reference. The 4.5-V reference voltage is generated with respect to AVSS. When using the internal voltage reference, connect VREFN to AVSS.

ADS1299 ADS1299-4 ADS1299-6 ai_int_ref_bas499.gif
For VREF = 4.5 V: R1 = 9.8 kΩ, R2 = 13.4 kΩ, and R3 = 36.85 kΩ.
Figure 25. Internal Reference

The external band-limiting capacitors determine the amount of reference noise contribution. For high-end EEG systems, the capacitor values should be chosen such that the bandwidth is limited to less than 10 Hz so that the reference noise does not dominate system noise.

Alternatively, the internal reference buffer can be powered down and an external reference can be applied to VREFP. Figure 26 shows a typical external reference drive circuitry. Power-down is controlled by the PD_REFBUF bit in the CONFIG3 register. This power-down is also used to share internal references when two devices are cascaded. By default, the device wakes up in external reference mode.

ADS1299 ADS1299-4 ADS1299-6 ai_ext_ref_drvr_bas459.gif Figure 26. External Reference Driver

Digital Functionality

Digital Decimation Filter

The digital filter receives the modulator output and decimates the data stream. By adjusting the amount of filtering, tradeoffs can be made between resolution and data rate: filter more for higher resolution, filter less for higher data rates. Higher data rates are typically used in EEG applications for ac lead-off detection.

The digital filter on each channel consists of a third-order sinc filter. The sinc filter decimation ratio can be adjusted by the DR bits in the CONFIG1 register (see the Register Maps section for details). This setting is a global setting that affects all channels and, therefore, all channels operate at the same data rate in a device.

Sinc Filter Stage (sinx / x)

The sinc filter is a variable decimation rate, third-order, low-pass filter. Data are supplied to this section of the filter from the modulator at the rate of fMOD. The sinc filter attenuates the modulator high-frequency noise, then decimates the data stream into parallel data. The decimation rate affects the overall converter data rate.

Equation 6 shows the scaled Z-domain transfer function of the sinc filter.

Equation 6. ADS1299 ADS1299-4 ADS1299-6 q_hz_bas459.gif

The frequency domain transfer function of the sinc filter is shown in Equation 7.

Equation 7. ADS1299 ADS1299-4 ADS1299-6 q_hf_bas499.gif

where

The sinc filter has notches (or zeroes) that occur at the output data rate and multiples thereof. At these frequencies, the filter has infinite attenuation. Figure 27 shows the sinc filter frequency response and Figure 28 shows the sinc filter roll-off. With a step change at input, the filter takes 3 × tDR to settle. After a rising edge of the START signal, the filter takes tSETTLE time to give the first data output. The settling time of the filters at various data rates are discussed in the Start subsection of the SPI Interface section. Figure 29 and Figure 30 show the filter transfer function until fMOD / 2 and fMOD / 16, respectively, at different data rates. Figure 31 shows the transfer function extended until 4 × fMOD. The ADS1299-x pass band repeats itself at every fMOD. The input R-C antialiasing filters in the system should be chosen such that any interference in frequencies around multiples of fMOD are attenuated sufficiently.

ADS1299 ADS1299-4 ADS1299-6 ai_sinc_fresp_bas459.gif
Figure 27. Sinc Filter Frequency Response
ADS1299 ADS1299-4 ADS1299-6 G027_SBAS499.png
Figure 29. Transfer Function of On-Chip Decimation Filters Until fMOD / 2
ADS1299 ADS1299-4 ADS1299-6 G029_SBAS499.png
Figure 31. Transfer Function of On-Chip Decimation Filters
Until 4 fMOD for DR[2:0] = 000 and DR[2:0] = 110
ADS1299 ADS1299-4 ADS1299-6 ai_sinc_rolloff_bas459.gif
Figure 28. Sinc Filter Roll-Off
ADS1299 ADS1299-4 ADS1299-6 G028_SBAS499.png
Figure 30. Transfer Function of On-Chip Decimation Filters Until fMOD / 16

Clock

The ADS1299-x provides two methods for device clocking: internal and external. Internal clocking is ideally suited for low-power, battery-powered systems. The internal oscillator is trimmed for accuracy at room temperature. Accuracy varies over the specified temperature range; see the Electrical Characteristics. Clock selection is controlled by the CLKSEL pin and the CLK_EN register bit.

The CLKSEL pin selects either the internal or external clock. The CLK_EN bit in the CONFIG1 register enables and disables the oscillator clock to be output in the CLK pin. A truth table for these two pins is shown in Table 6. The CLK_EN bit is useful when multiple devices are used in a daisy-chain configuration. During power-down, the external clock is recommended be shut down to save power.

Table 6. CLKSEL Pin and CLK_EN Bit

CLKSEL PIN CONFIG1.CLK_EN BIT CLOCK SOURCE CLK PIN STATUS
0 X External clock Input: external clock
1 0 Internal clock oscillator 3-state
1 1 Internal clock oscillator Output: internal clock oscillator

GPIO

The ADS1299-x has a total of four general-purpose digital I/O (GPIO) pins available in normal mode of operation. The digital I/O pins are individually configurable as either inputs or outputs through the GPIOC bits register. The GPIOD bits in the GPIO register control the pin level. When reading the GPIOD bits, the data returned are the logic level of the pins, whether they are programmed as inputs or outputs. When the GPIO pin is configured as an input, a write to the corresponding GPIOD bit has no effect. When configured as an output, a write to the GPIOD bit sets the output value.

If configured as inputs, these pins must be driven (do not float). The GPIO pins are set as inputs after power-on or after a reset. Figure 32 shows the GPIO port structure. The pins should be shorted to DGND if not used.

ADS1299 ADS1299-4 ADS1299-6 ai_gpio_bas459.gif Figure 32. GPIO Port Pin

ECG and EEG Specific Features

Input Multiplexer (Rerouting the BIAS Drive Signal)

The input multiplexer has EEG-specific functions for the bias drive signal. The BIAS signal is available at the BIASOUT pin when the appropriate channels are selected for BIAS derivation, feedback elements are installed external to the chip, and the loop is closed. This signal can either be fed after filtering or fed directly into the BIASIN pin, as shown in Figure 33. This BIASIN signal can be multiplexed into any input electrode by setting the MUX bits of the appropriate channel set registers to '110' for P-side or '111' for N-side. Figure 33 shows the BIAS signal generated from channels 1, 2, and 3 and routed to the N-side of channel 8. This feature can be used to dynamically change the electrode that is used as the reference signal to drive the patient body.

ADS1299 ADS1299-4 ADS1299-6 ai_in_mux_ecg1_bas499.gif
Typical values for example only.
Figure 33. Example of BIASOUT Signal Configured to be Routed to IN8N

Input Multiplexer (Measuring the BIAS Drive Signal)

Also, the BIASOUT signal can be routed to a channel (that is not used for the calculation of BIAS) for measurement. Figure 34 shows the register settings to route the BIASIN signal to channel 8. The measurement is done with respect to the voltage on the BIASREF pin. If BIASREF is chosen to be internal, then BIASREF is at [(AVDD + AVSS) / 2]. This feature is useful for debugging purposes during product development.

ADS1299 ADS1299-4 ADS1299-6 ai_in_mux_ecg2_bas499.gif
Typical values for example only.
Figure 34. BIASOUT Signal Configured to be Read Back by Channel 8

Lead-Off Detection

Patient electrode impedances are known to decay over time. These electrode connections must be continuously monitored to verify that a suitable connection is present. The ADS1299-x lead-off detection functional block provides significant flexibility to the user to choose from various lead-off detection strategies. Though called lead-off detection, this is in fact an electrode-off detection.

The basic principle is to inject an excitation current and measure the voltage to determine if the electrode is off. As shown in the lead-off detection functional block diagram in Figure 35, this circuit provides two different methods of determining the state of the patient electrode. The methods differ in the frequency content of the excitation signal. Lead-off can be selectively done on a per channel basis using the LOFF_SENSP and LOFF_SENSN registers. Also, the internal excitation circuitry can be disabled and just the sensing circuitry can be enabled.

ADS1299 ADS1299-4 ADS1299-6 ai_lod_fbd_bas499.gif Figure 35. Lead-Off Detection

DC Lead-Off

In this method, the lead-off excitation is with a dc signal. The dc excitation signal can be chosen from either an external pull-up or pull-down resistor or an internal current source or sink, as shown in Figure 36. One side of the channel is pulled to supply and the other side is pulled to ground. The pull-up and pull-down current can be swapped (as shown in Figure 36b and Figure 36c) by setting the bits in the LOFF_FLIP register. In case of a current source or sink, the magnitude of the current can be set by using the ILEAD_OFF[1:0] bits in the LOFF register. The current source or sink gives larger input impedance compared to the 10-MΩ pull-up or pull-down resistor.

ADS1299 ADS1299-4 ADS1299-6 ai_dc_leadoff_opt_bas499.gif Figure 36. DC Lead-Off Excitation Options

Sensing of the response can be done either by searching the digital output code from the device or by monitoring the input voltages with an on-chip comparator. If either electrode is off, the pull-up and pull-down resistors saturate the channel. Searching the output code determines if either the P-side or the N-side is off. To pinpoint which one is off, the comparators must be used. The input voltage is also monitored using a comparator and a 3-bit DAC whose levels are set by the COMP_TH[2:0] bits in the LOFF register. The output of the comparators are stored in the LOFF_STATP and LOFF_STATN registers. These registers are available as a part of the output data stream. (See the Data Output (DOUT) subsection of the SPI Interface section.) If dc lead-off is not used, the lead-off comparators can be powered down by setting the PD_LOFF_COMP bit in the CONFIG4 register.

An example procedure to turn on dc lead-off is given in the Lead-Off section.

AC Lead-Off (One Time or Periodic)

In this method, an in-band ac signal is used for excitation. The ac signal is generated by alternatively providing a current source and sink at the input with a fixed frequency. The frequency can be chosen by the FLEAD_OFF[1:0] bits in the LOFF register. The excitation frequency is chosen to be one of the two in-band frequency selections (7.8 Hz or 31.2 Hz). This in-band excitation signal is passed through the channel and measured at the output.

Sensing of the ac signal is done by passing the signal through the channel to be digitized and then measured at the output. The ac excitation signals are introduced at a frequency that is in the band of interest. The signal can be filtered out separately and processed. By measuring the magnitude of the output at the excitation signal frequency, the electrode impedance can be calculated.

For continuous lead-off, an out-of-band ac current source or sink must be externally applied to the inputs. This signal can then be digitally processed to determine the electrode impedance.

Bias Lead-Off

BIAS Lead-Off Detection During Normal Operation

During normal operation, the ADS1299-x BIAS lead-off at power-up function cannot be used because the BIAS amplifier must be powered off.

BIAS Lead Off Detection At Power-Up

This feature is included in the ADS1299-x for use in determining whether the bias electrode is suitably connected. At power-up, the ADS1299-x uses a current source and comparator to determine the BIAS electrode connection status, as shown in Figure 37. The reference level of the comparator is set to determine the acceptable BIAS impedance threshold.

ADS1299 ADS1299-4 ADS1299-6 ai_rld_lod_pwrup_bas499.gif Figure 37. BIAS Lead-Off Detection at Power-Up

When the BIAS amplifier is powered on, the current source has no function. Only the comparator can be used to sense the voltage at the output of the BIAS amplifier. The comparator thresholds are set by the same LOFF[7:5] bits used to set the thresholds for other negative inputs.

Bias Drive (DC Bias Circuit)

Use the bias circuitry to counter the common-mode interference in a EEG system as a result of power lines and other sources, including fluorescent lights. The bias circuit senses the common-mode voltage of a selected set of electrodes and creates a negative feedback loop by driving the body with an inverted common-mode signal. The negative feedback loop restricts the common-mode movement to a narrow range, depending on the loop gain. Stabilizing the entire loop is specific to the individual user system based on the various poles in the loop. The ADS1299-x integrates the muxes to select the channel and an operational amplifier. All the amplifier terminals are available at the pins, allowing the user to choose the components for the feedback loop. The circuit in Figure 38 shows the overall functional connectivity for the bias circuit.

ADS1299 ADS1299-4 ADS1299-6 ai_rld_select_small_bas499.gif
Typical values.
Figure 38. Bias Drive Amplifier Channel Selection

The reference voltage for the bias drive can be chosen to be internally generated [(AVDD + AVSS) / 2] or provided externally with a resistive divider. The selection of an internal versus external reference voltage for the bias loop is defined by writing the appropriate value to the BIASREF_INT bit in the CONFIG2 register.

If the bias function is not used, the amplifier can be powered down using the PD_BIAS bit (see the CONFIG3: Configuration Register 3 subsection of the Register Maps section for details). Use the PD_BIAS bit to power-down all but one of the bias amplifiers when daisy-chaining multiple ADS1299-x devices.

The BIASIN pin functionality is explained in the Input Multiplexer section. An example procedure to use the bias amplifier is shown in the Bias Drive section.

Bias Configuration with Multiple Devices

Figure 39 shows multiple devices connected to the bias drive.

ADS1299 ADS1299-4 ADS1299-6 ai_rld_connex_multi_bas499.gif Figure 39. BIAS Drive Connection for Multiple Devices

Device Functional Modes

Start

Pull the START pin high for at least 2 tCLK periods, or send the START command to begin conversions. When START is low and the START command has not been sent, the device does not issue a DRDY signal (conversions are halted).

When using the START command to control conversions, hold the START pin low. The ADS1299-x features two modes to control conversions: continuous mode and single-shot mode. The mode is selected by SINGLE_SHOT (bit 3 of the CONFIG4 register). In multiple device configurations, the START pin is used to synchronize devices (see the Multiple Device Configuration subsection of the SPI Interface section for more details).

Settling Time

The settling time (tSETTLE) is the time required for the converter to output fully-settled data when the START signal is pulled high. When START is pulled high, DRDY is also pulled high. The next DRDY falling edge indicates that data are ready. Figure 40 shows the timing diagram and Table 7 lists the settling time for different data rates. The settling time depends on fCLK and the decimation ratio (controlled by the DR[2:0] bits in the CONFIG1 register). When the initial settling time has passed, the DRDY falling edge occurs at the set data rate, tDR. If data is not read back on DOUT and the output shift register needs to update, DRDY goes high for 4 tCLK before returning back low indicating new data is ready. Table 7 lists the settling time as a function of tCLK. Note that when START is held high and there is a step change in the input signal, 3 × tDR is required for the filter to settle to the new value. Settled data are available on the fourth DRDY pulse.

ADS1299 ADS1299-4 ADS1299-6 ai_tim_settle_bas499.gif Figure 40. Settling Time

Table 7. Settling Time for Different Data Rates

DR[2:0] NORMAL MODE UNIT
000 521 tCLK
001 1033 tCLK
010 2057 tCLK
011 4105 tCLK
100 8201 tCLK
101 16393 tCLK
110 32777 tCLK

Reset (RESET)

There are two methods to reset the ADS1299-x: pull the RESET pin low, or send the RESET command. When using the RESET pin, make sure to follow the minimum pulse duration timing specifications before taking the pin back high. The RESET command takes effect on the eighth SCLK falling edge of the command. After a reset, 18 tCLK cycles are required to complete initialization of the configuration registers to default states and start the conversion cycle. Note that an internal reset is automatically issued to the digital filter whenever the CONFIG1 register is set to a new value with a WREG command.

Power-Down (PWDN)

When PWDN is pulled low, all on-chip circuitry is powered down. To exit power-down mode, take the PWDN pin high. Upon exiting from power-down mode, the internal oscillator and the reference require time to wake up. During power-down, the external clock is recommended to be shut down to save power.

Data Retrieval

Data Ready (DRDY)

DRDY is an output signal which transitions from high to low indicating new conversion data are ready. The CS signal has no effect on the data ready signal. DRDY behavior is determined by whether the device is in RDATAC mode or the RDATA command is used to read data on demand. (See the RDATAC: Read Data Continuous and RDATA: Read Data subsections of the SPI Command Definitions section for further details).

When reading data with the RDATA command, the read operation can overlap the next DRDY occurrence without data corruption.

The START pin or the START command places the device either in normal data capture mode or pulse data capture mode.

Figure 41 shows the relationship between DRDY, DOUT, and SCLK during data retrieval (in case of an ADS1299). DOUT is latched out at the SCLK rising edge. DRDY is pulled high at the SCLK falling edge. Note that DRDY goes high on the first SCLK falling edge, regardless of whether data are being retrieved from the device or a command is being sent through the DIN pin.

ADS1299 ADS1299-4 ADS1299-6 ai_tim_drdy_datartrvl_bas499.gif Figure 41. DRDY with Data Retrieval (CS = 0)

Reading Back Data

Data retrieval can be accomplished in one of two methods:

  1. RDATAC: the read data continuous command sets the device in a mode that reads data continuously without sending commands. See the RDATAC: Read Data Continuous section for more details.
  2. RDATA: the read data command requires that a command is sent to the device to load the output shift register with the latest data. See the RDATA: Read Data section for more details.

Conversion data are read by shifting data out on DOUT. The MSB of the data on DOUT is clocked out on the first SCLK rising edge. DRDY returns high on the first SCLK falling edge. DIN should remain low for the entire read operation.

The number of bits in the data output depends on the number of channels and the number of bits per channel. For the 8-channel ADS1299, the number of data outputs is [(24 status bits + 24 bits × 8 channels) = 216 bits]. The format of the 24 status bits is: (1100 + LOFF_STATP + LOFF_STATN + bits[4:7] of the GPIO register). The data format for each channel data are twos complement and MSB first. When channels are powered down using the user register setting, the corresponding channel output is set to '0'. However, the channel output sequence remains the same.

The ADS1299-x also provides a multiple readback feature. Data can be read out multiple times by simply giving more SCLKs in RDATAC mode, in which case the MSB data byte repeats after reading the last byte. The DAISY_EN bit in the CONFIG1 register must be set to '1' for multiple readbacks.

Continuous Conversion Mode

Conversions begin when the START pin is taken high or when the START command is sent. As shown in Figure 42, the DRDY output goes high when conversions are started and goes low when data are ready. Conversions continue indefinitely until the START pin is taken low or the STOP command is transmitted. When the START pin is pulled low or the STOP command is issued, the conversion in progress is allowed to complete. Figure 43 and Table 8 illustrate the required DRDY timing to the START pin or the START and STOP commands when controlling conversions in this mode. The tSDSU timing indicates when to take the START pin low or when to send the STOP command before the DRDY falling edge to halt further conversions. The tDSHD timing indicates when to take the START pin low or send the STOP command after a DRDY falling edge to complete the current conversion and halt further conversions. To keep the converter running continuously, the START pin can be permanently tied high.

When switching from Single-Shot mode to Continuous Conversion mode, bring the START signal low and back high or send a STOP command followed by a START command. This conversion mode is ideal for applications that require a fixed continuous stream of conversions results.

ADS1299 ADS1299-4 ADS1299-6 ai_tim_cont_conv_bas499.gif
START and STOP commands take effect on the seventh SCLK falling edge.
Figure 42. Continuous Conversion Mode
ADS1299 ADS1299-4 ADS1299-6 ai_tim_start-drdy_bas499.gif
START and STOP commands take effect on the seventh SCLK falling edge at the end of the command.
Figure 43. START to DRDY Timing

Table 8. Timing Characteristics for Figure 43(1)

MIN UNIT
tSDSU START pin low or STOP command to DRDY setup time to halt further conversions 16 tCLK
tDSHD START pin low or STOP command to complete current conversion 16 tCLK
START and STOP commands take effect on the seventh SCLK falling edge at the end of the command.

Single-Shot Mode

Single-shot mode is enabled by setting the SINGLE_SHOT bit in the CONFIG4 register to '1'. In single-shot mode, the ADS1299-x performs a single conversion when the START pin is taken high or when the START command is sent. As shown in Figure 44, when a conversion is complete, DRDY goes low and further conversions are stopped. Regardless of whether the conversion data are read or not, DRDY remains low. To begin a new conversion, take the START pin low and then back high, or send the START command again. When switching from Continuous Conversion mode to Single-Shot mode, bring the START signal low and back high or send a STOP command followed by a START command.

ADS1299 ADS1299-4 ADS1299-6 ai_tim_drdy_pulse_bas459.gif Figure 44. DRDY with No Data Retrieval in Single-Shot Mode

This conversion mode is ideal for applications that require non-standard or non-continuous data rates. Issuing a START command or toggling the START pin high resets the digital filter, effectively dropping the data rate by a factor of four. This mode leaves the system more susceptible to aliasing effects, requiring more complex analog or digital filtering. Loading on the host processor increases because the processor must toggle the START pin or send a START command to initiate a new conversion cycle.

Programming

Data Format

The device provides 24 bits of data in binary twos complement format. The size of one code (LSB) is calculated using Equation 8.

Equation 8. 1 LSB = (2 × VREF / Gain) / 224 = +FS / 223

A positive full-scale input produces an output code of 7FFFFFh and the negative full-scale input produces an output code of 800000h. The output clips at these codes for signals exceeding full-scale. Table 9 summarizes the ideal output codes for different input signals. All 24 bits toggle when the analog input is at positive or negative full-scale.

Table 9. Ideal Output Code versus Input Signal

INPUT SIGNAL, VIN
(INxP - INxN)
IDEAL OUTPUT CODE(1)
≥ FS 7FFFFFh
+FS / (223 – 1) 000001h
0 000000h
–FS / (223 – 1) FFFFFFh
≤ –FS (223 / 223 – 1) 800000h
Excludes effects of noise, linearity, offset, and gain error.

SPI Interface

The SPI-compatible serial interface consists of four signals: CS, SCLK, DIN, and DOUT. The interface reads conversion data, reads and writes registers, and controls ADS1299-x operation. The data-ready output, DRDY (see the Data Ready (DRDY) section), is used as a status signal to indicate when data are ready. DRDY goes low when new data are available.

Chip Select (CS)

The CS pin activates SPI communication. CS must be low before data transactions and must stay low for the entire SPI communication period. When CS is high, the DOUT pin enters a high-impedance state. Therefore, reading and writing to the serial interface are ignored and the serial interface is reset. DRDY pin operation is independent of CS. DRDY still indicates that a new conversion has completed and is forced high as a response to SCLK, even if CS is high.

Taking CS high deactivates only the SPI communication with the device and the serial interface is reset. Data conversion continues and the DRDY signal can be monitored to check if a new conversion result is ready. A master device monitoring the DRDY signal can select the appropriate slave device by pulling the CS pin low. After the serial communication is finished, always wait four or more tCLK cycles before taking CS high.

Serial Clock (SCLK)

SCLK provides the clock for serial communication. SCLK is a Schmitt-trigger input, but TI recommends keeping SCLK as free from noise as possible to prevent glitches from inadvertently shifting the data. Data are shifted into DIN on the falling edge of SCLK and shifted out of DOUT on the rising edge of SCLK.

The absolute maximum SCLK limit is specified in Figure 1. When shifting in commands with SCLK, make sure that the entire set of SCLKs is issued to the device. Failure to do so can result in the device serial interface being placed into an unknown state requiring CS to be taken high to recover.

For a single device, the minimum speed required for SCLK depends on the number of channels, number of bits of resolution, and output data rate. (For multiple cascaded devices, see the Cascaded Mode subsection of the Multiple Device Configuration section.)

For example, if the ADS1299 is used in a 500-SPS mode (8 channels, 24-bit resolution), the minimum SCLK speed is 110 kHz.

Data retrieval can be accomplished either by placing the device in RDATAC mode or by issuing an RDATA command for data on demand. The SCLK rate limitation in Equation 9 applies to RDATAC. For the RDATA command, the limitation applies if data must be read in between two consecutive DRDY signals. Equation 9 assumes that there are no other commands issued in between data captures.

Equation 9. ADS1299 ADS1299-4 ADS1299-6 q_tsclk_bas499.gif

Data Input (DIN)

DIN is used along with SCLK to send data to the device. Data on DIN are shifted into the device on the falling edge of SCLK.

The communication of this device is full-duplex in nature. The device monitors commands shifted in even when data are being shifted out. Data that are present in the output shift register are shifted out when sending in a command. Therefore, make sure that whatever is being sent on the DIN pin is valid when shifting out data. When no command is to be sent to the device when reading out data, send the NOP command on DIN. Make sure that the tSDECODE timing is met in the Sending Multi-Byte Commands section when sending multiple byte commands on DIN.

Data Output (DOUT)

DOUT is used with SCLK to read conversion and register data from the device. Data are clocked out on the rising edge of SCLK, MSB first. DOUT goes to a high-impedance state when CS is high. Figure 45 shows the ADS1299 data output protocol.

ADS1299 ADS1299-4 ADS1299-6 ai_tim_spi_bus_out_bas459.gif Figure 45. SPI Bus Data Output

SPI Command Definitions

The ADS1299-x provides flexible configuration control. The commands, summarized in Table 10, control and configure device operation. The commands are stand-alone, except for the register read and write operations that require a second command byte plus data. CS can be taken high or held low between commands but must stay low for the entire command operation (especially for multi-byte commands). System commands and the RDATA command are decoded by the device on the seventh SCLK falling edge. The register read and write commands are decoded on the eighth SCLK falling edge. Be sure to follow SPI timing requirements when pulling CS high after issuing a command.

Table 10. Command Definitions

COMMAND DESCRIPTION FIRST BYTE SECOND BYTE
System Commands
WAKEUP Wake-up from standby mode 0000 0010 (02h)
STANDBY Enter standby mode 0000 0100 (04h)
RESET Reset the device 0000 0110 (06h)
START Start and restart (synchronize) conversions 0000 1000 (08h)
STOP Stop conversion 0000 1010 (0Ah)
Data Read Commands
RDATAC Enable Read Data Continuous mode.
This mode is the default mode at power-up.(2)
0001 0000 (10h)
SDATAC Stop Read Data Continuously mode 0001 0001 (11h)
RDATA Read data by command; supports multiple read back. 0001 0010 (12h)
Register Read Commands
RREG Read n nnnn registers starting at address r rrrr 001r rrrr (2xh)(1) 000n nnnn(1)
WREG Write n nnnn registers starting at address r rrrr 010r rrrr (4xh)(1) 000n nnnn(1)
n nnnn = number of registers to be read or written – 1. For example, to read or write three registers, set n nnnn = 0 (0010). r rrrr = starting register address for read or write commands.
When in RDATAC mode, the RREG command is ignored.

Sending Multi-Byte Commands

The ADS1299-x serial interface decodes commands in bytes and requires 4 tCLK cycles to decode and execute. Therefore, when sending multi-byte commands (such as RREG or WREG), a 4 tCLK period must separate the end of one byte (or command) and the next.

Assuming CLK is 2.048 MHz, then tSDECODE (4 tCLK) is 1.96 µs. When SCLK is 16 MHz, one byte can be transferred in 500 ns. This byte transfer time does not meet the tSDECODE specification; therefore, a delay must be inserted so the end of the second byte arrives 1.46 µs later. If SCLK is 4 MHz, one byte is transferred in 2 µs. Because this transfer time exceeds the tSDECODE specification, the processor can send subsequent bytes without delay. In this later scenario, the serial port can be programmed to move from single-byte transfers per cycle to multiple bytes.

WAKEUP: Exit STANDBY Mode

The WAKEUP command exits low-power standby mode; see the STANDBY: Enter STANDBY Mode subsection of the SPI Command Definitions section. Time is required when exiting standby mode (see the Electrical Characteristics for details). There are no SCLK rate restrictions for this command and can be issued at any time. Any following commands must be sent after a delay of 4 tCLK cycles.

STANDBY: Enter STANDBY Mode

The STANDBY command enters low-power standby mode. All parts of the circuit are shut down except for the reference section. The standby mode power consumption is specified in the Electrical Characteristics. There are no SCLK rate restrictions for this command and can be issued at any time. Do not send any other commands other than the wakeup command after the device enters standby mode.

RESET: Reset Registers to Default Values

The RESET command resets the digital filter cycle and returns all register settings to default values. See the Reset (RESET) subsection of the SPI Interface section for more details. There are no SCLK rate restrictions for this command and can be issued at any time. 18 tCLK cycles are required to execute the RESET command. Avoid sending any commands during this time.

START: Start Conversions

The START command starts data conversions. Tie the START pin low to control conversions by command. If conversions are in progress, this command has no effect. The STOP command stops conversions. If the START command is immediately followed by a STOP command, then there must be a 4-tCLK cycle delay between them. When the START command is sent to the device, keep the START pin low until the STOP command is issued. (See the Start subsection of the SPI Interface section for more details.) There are no SCLK rate restrictions for this command and can be issued at any time.

STOP: Stop Conversions

The STOP command stops conversions. Tie the START pin low to control conversions by command. When the STOP command is sent, the conversion in progress completes and further conversions are stopped. If conversions are already stopped, this command has no effect. There are no SCLK rate restrictions for this command and can be issued at any time.

RDATAC: Read Data Continuous

The RDATAC command enables conversion data output on each DRDY without the need to issue subsequent read data commands. This mode places the conversion data in the output register and may be shifted out directly. The read data continuous mode is the device default mode; the device defaults to this mode on power-up.

RDATAC mode is cancelled by the Stop Read Data Continuous command. If the device is in RDATAC mode, a SDATAC command must be issued before any other commands can be sent to the device. There are no SCLK rate restrictions for this command. However, subsequent data retrieval SCLKs or the SDATAC command should wait at least 4 tCLK cycles before completion (see the Sending Multi-Byte Commands section). RDATAC timing is illustrated in Figure 46. As depicted in Figure 46, there is a keep out zone of 4 tCLK cycles around the DRDY pulse where this command cannot be issued in. If no data are retrieved from the device, DOUT and DRDY behave similarly in this mode. To retrieve data from the device after the RDATAC command is issued, make sure either the START pin is high or the START command is issued. Figure 46 shows the recommended way to use the RDATAC command. RDATAC is ideally-suited for applications such as data loggers or recorders, where registers are set one time and do not need to be reconfigured.

ADS1299 ADS1299-4 ADS1299-6 ai_tim_rdatac_use_bas499.gif
tUPDATE = 4 / fCLK. Do not read data during this time.
Figure 46. RDATAC Usage

SDATAC: Stop Read Data Continuous

The SDATAC command cancels the Read Data Continuous mode. There are no SCLK rate restrictions for this command, but the next command must wait for 4 tCLK cycles before completion.

RDATA: Read Data

The RDATA command loads the output shift register with the latest data when not in Read Data Continuous mode. Issue this command after DRDY goes low to read the conversion result. There are no SCLK rate restrictions for this command, and there is no wait time needed for the subsequent commands or data retrieval SCLKs. To retrieve data from the device after the RDATA command is issued, make sure either the START pin is high or the START command is issued. When reading data with the RDATA command, the read operation can overlap the next DRDY occurrence without data corruption. Figure 47 shows the recommended way to use the RDATA command. RDATA is best suited for ECG- and EEG-type systems, where register settings must be read or changed often between conversion cycles.

ADS1299 ADS1299-4 ADS1299-6 ai_tim_rdata_use_bas499.gif Figure 47. RDATA Usage

RREG: Read From Register

This command reads register data. The Register Read command is a two-byte command followed by the register data output. The first byte contains the command and register address. The second command byte specifies the number of registers to read – 1.

First command byte: 001r rrrr, where r rrrr is the starting register address.

Second command byte: 000n nnnn, where n nnnn is the number of registers to read – 1.

The 17th SCLK rising edge of the operation clocks out the MSB of the first register, as shown in Figure 48. When the device is in read data continuous mode, an SDATAC command must be issued before the RREG command can be issued. The RREG command can be issued any time. However, because this command is a multi-byte command, there are SCLK rate restrictions depending on how the SCLKs are issued to meet the tSDECODE timing. See the Serial Clock (SCLK) subsection of the SPI Interface section for more details. Note that CS must be low for the entire command.

ADS1299 ADS1299-4 ADS1299-6 com_rreg_bas499.gif Figure 48. RREG Command Example: Read Two Registers Starting from Register 00h (ID Register)
(BYTE 1 = 0010 0000, BYTE 2 = 0000 0001)

WREG: Write to Register

This command writes register data. The Register Write command is a two-byte command followed by the register data input. The first byte contains the command and register address. The second command byte specifies the number of registers to write – 1.

First command byte: 010r rrrr, where r rrrr is the starting register address.

Second command byte: 000n nnnn, where n nnnn is the number of registers to write – 1.

After the command bytes, the register data follows (in MSB-first format), as shown in Figure 49. The WREG command can be issued any time. However, because this command is a multi-byte command, there are SCLK rate restrictions depending on how the SCLKs are issued to meet the tSDECODE timing. See the Serial Clock (SCLK) subsection of the SPI Interface section for more details. Note that CS must be low for the entire command.

ADS1299 ADS1299-4 ADS1299-6 com_wreg_bas499.gif Figure 49. WREG Command Example: Write Two Registers Starting from 00h (ID Register)
(BYTE 1 = 0100 0000, BYTE 2 = 0000 0001)

Register Maps

Table 11 describes the various ADS1299-x registers.

Table 11. Register Assignments

ADDRESS REGISTER DEFAULT SETTING REGISTER BITS
7 6 5 4 3 2 1 0
Read Only ID Registers
00h ID xxh REV_ID[2:0] 1 DEV_ID[1:0] NU_CH[1:0]
Global Settings Across Channels
01h CONFIG1 96h 1 DAISY_EN CLK_EN 1 0 DR[2:0]
02h CONFIG2 C0h 1 1 0 INT_CAL 0 CAL_AMP0 CAL_FREQ[1:0]
03h CONFIG3 60h PD_REFBUF 1 1 BIAS_MEAS BIASREF_INT PD_BIAS BIAS_LOFF_
SENS
BIAS_STAT
04h LOFF 00h COMP_TH[2:0] 0 ILEAD_OFF[1:0] FLEAD_OFF[1:0]
Channel-Specific Settings
05h CH1SET 61h PD1 GAIN1[2:0] SRB2 MUX1[2:0]
06h CH2SET 61h PD2 GAIN2[2:0] SRB2 MUX2[2:0]
07h CH3SET 61h PD3 GAIN3[2:0] SRB2 MUX3[2:0]
08h CH4SET 61h PD4 GAIN4[2:0] SRB2 MUX4[2:0]
09h CH5SET (1) 61h PD5 GAIN5[2:0] SRB2 MUX5[2:0]
0Ah CH6SET (1) 61h PD6 GAIN6[2:0] SRB2 MUX6[2:0]
0Bh CH7SET (2) 61h PD7 GAIN7[2:0] SRB2 MUX7[2:0]
0Ch CH8SET (2) 61h PD8 GAIN8[2:0] SRB2 MUX8[2:0]
0Dh BIAS_SENSP 00h BIASP8(2) BIASP7(2) BIASP6(1) BIASP5(1) BIASP4 BIASP3 BIASP2 BIASP1
0Eh BIAS_SENSN 00h BIASN8(2) BIASN7(2) BIASN6(1) BIASN5(1) BIASN4 BIASN3 BIASN2 BIASN1
0Fh LOFF_SENSP 00h LOFFP8(2) LOFFP7(2) LOFFP6(1) LOFFP5(1) LOFFP4 LOFFP3 LOFFP2 LOFFP1
10h LOFF_SENSN 00h LOFFM8(2) LOFFM7(2) LOFFM6(1) LOFFM5(1) LOFFM4 LOFFM3 LOFFM2 LOFFM1
11h LOFF_FLIP 00h LOFF_FLIP8(2) LOFF_FLIP7(2) LOFF_FLIP6(1) LOFF_FLIP5(1) LOFF_FLIP4 LOFF_FLIP3 LOFF_FLIP2 LOFF_FLIP1
Lead-Off Status Registers (Read-Only Registers)
12h LOFF_STATP 00h IN8P_OFF IN7P_OFF IN6P_OFF IN5P_OFF IN4P_OFF IN3P_OFF IN2P_OFF IN1P_OFF
13h LOFF_STATN 00h IN8M_OFF IN7M_OFF IN6M_OFF IN5M_OFF IN4M_OFF IN3M_OFF IN2M_OFF IN1M_OFF
GPIO and OTHER Registers
14h GPIO 0Fh GPIOD[4:1] GPIOC[4:1]
15h MISC1 00h 0 0 SRB1 0 0 0 0 0
16h MISC2 00h 0 0 0 0 0 0 0 0
17h CONFIG4 00h 0 0 0 0 SINGLE_
SHOT
0 PD_LOFF_
COMP
0
Register or bit only available in the ADS1299-6 and ADS1299. Register bits set to 0h or 00h in the ADS1299-4.
Register or bit only available in the ADS1299. Register bits set to 0h or 00h in the ADS1299-4 and ADS1299-6.

User Register Description

The read-only ID control register is programmed during device manufacture to indicate device characteristics.

ID: ID Control Register (address = 00h) (reset = xxh)

Figure 50. ID Control Register
7 6 5 4 3 2 1 0
REV_ID[2:0] 1 DEV_ID[1:0] NU_CH[1:0]
R-xh R-1h R-3h R-xh
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 12. ID Control Register Field Descriptions

Bit Field Type Reset Description
7:5 REV_ID[2:0] R xh Reserved.
These bits indicate the revision of the device and are subject to change without notice.
4 Reserved R 1h Reserved.
Always read 1.
3:2 DEV_ID[1:0] R 3h Device Identification.
These bits indicates the device.
11 : ADS1299-x
1:0 NU_CH[1:0] R xh Number of Channels.
These bits indicates number of channels.
00 : 4-channel ADS1299-4
01 : 6-channel ADS1299-6
10 : 8-channel ADS1299

CONFIG1: Configuration Register 1 (address = 01h) (reset = 96h)

This register configures the DAISY_EN bit, clock, and data rate.

Figure 51. CONFIG1: Configuration Register 1
7 6 5 4 3 2 1 0
1 DAISY_EN CLK_EN 1 0 DR[2:0]
R/W-1h R/W-0h R/W-0h R/W-1h R/W-0h R/W-6h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 13. Configuration Register 1 Field Descriptions

Bit Field Type Reset Description
7 Reserved R/W 1h Reserved
Always write 1h
6 DAISY_EN R/W 0h Daisy-chain or multiple readback mode
This bit determines which mode is enabled.
0 : Daisy-chain mode
1 : Multiple readback mode
5 CLK_EN R/W 0h CLK connection(1)
This bit determines if the internal oscillator signal is connected to the CLK pin when the CLKSEL pin = 1.
0 : Oscillator clock output disabled
1 : Oscillator clock output enabled
4:3 Reserved R/W 2h Reserved
Always write 2h
2:0 DR[2:0] R/W 6h Output data rate
These bits determine the output data rate of the device. fMOD = fCLK / 2.
000 : fMOD / 64 (16 kSPS)
001 : fMOD / 128 (8 kSPS)
010 : fMOD / 256 (4 kSPS)
011 : fMOD / 512 (2 kSPS)
100 : fMOD / 1024 (1 kSPS)
101 : fMOD / 2048 (500 SPS)
110 : fMOD / 4096 (250 SPS)
111 : Reserved (do not use)
Additional power is consumed when driving external devices.

CONFIG2: Configuration Register 2 (address = 02h) (reset = C0h)

This register configures the test signal generation. See the Input Multiplexer section for more details.

Figure 52. CONFIG2: Configuration Register 2
7 6 5 4 3 2 1 0
1 1 0 INT_CAL 0 CAL_AMP CAL_FREQ[1:0]
R/W-1h R/W-1h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 14. Configuration Register 2 Field Descriptions

Bit Field Type Reset Description
7:5 Reserved R/W 6h Reserved
Always write 6h
4 INT_CAL R/W 0h TEST source
This bit determines the source for the test signal.
0 : Test signals are driven externally
1 : Test signals are generated internally
3 Reserved R/W 0h Reserved
Always write 0h
2 CAL_AMP R/W 0h Test signal amplitude
These bits determine the calibration signal amplitude.
0 : 1 × –(VREFP – VREFN) / 2400
1 : 2 × –(VREFP – VREFN) / 2400
1:0 CAL_FREQ[1:0] R/W 0h Test signal frequency
These bits determine the calibration signal frequency.
00 : Pulsed at fCLK / 221
01 : Pulsed at fCLK / 220
10 : Do not use
11 : At dc

CONFIG3: Configuration Register 3 (address = 03h) (reset = 60h)

Configuration register 3 configures either an internal or exteral reference and BIAS operation.

Figure 53. CONFIG3: Configuration Register 3
7 6 5 4 3 2 1 0
PD_REFBUF 1 1 BIAS_MEAS BIASREF_INT PD_BIAS BIAS_LOFF_
SENS
BIAS_STAT
R/W-0h R/W-1h R/W-1h R/W-0h R/W-0h R/W-0h R/W-0h R-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 15. Configuration Register 3 Field Descriptions

Bit Field Type Reset Description
7 PD_REFBUF R/W 0h

Power-down reference buffer


This bit determines the power-down reference buffer state.
0 : Power-down internal reference buffer
1 : Enable internal reference buffer
6:5 Reserved R/W 3h Reserved
Always write 3h.
4 BIAS_MEAS R/W 0h BIAS measurement
This bit enables BIAS measurement. The BIAS signal may be measured with any channel.
0 : Open
1 : BIAS_IN signal is routed to the channel that has the MUX_Setting 010 (VREF)
3 BIASREF_INT R/W 0h BIASREF signal
This bit determines the BIASREF signal source.
0 : BIASREF signal fed externally
1 : BIASREF signal (AVDD + AVSS) / 2 generated internally
2 PD_BIAS R/W 0h BIAS buffer power
This bit determines the BIAS buffer power state.
0 : BIAS buffer is powered down
1 : BIAS buffer is enabled
1 BIAS_LOFF_SENS R/W 0h BIAS sense function
This bit enables the BIAS sense function.
0 : BIAS sense is disabled
1 : BIAS sense is enabled
0 BIAS_STAT R 0h BIAS lead-off status
This bit determines the BIAS status.
0 : BIAS is connected
1 : BIAS is not connected

LOFF: Lead-Off Control Register (address = 04h) (reset = 00h)

The lead-off control register configures the lead-off detection operation.

Figure 54. LOFF: Lead-Off Control Register
7 6 5 4 3 2 1 0
COMP_TH2[2:0] 0 ILEAD_OFF[1:0] FLEAD_OFF[1:0]
R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 16. Lead-Off Control Register Field Descriptions

Bit Field Type Reset Description
7:5 COMP_TH[2:0] R/W 0h

Lead-off comparator threshold


Comparator positive side
000 : 95%
001 : 92.5%
010 : 90%
011 : 87.5%
100 : 85%
101 : 80%
110 : 75%
111 : 70%
Comparator negative side
000 : 5%
001 : 7.5%
010 : 10%
011 : 12.5%
100 : 15%
101 : 20%
110 : 25%
111 : 30%
4 Reserved R/W 0h Reserved
Always write 0h.
3:2 ILEAD_OFF[1:0] R/W 0h Lead-off current magnitude
These bits determine the magnitude of current for the current lead-off mode.
00 : 6 nA
01 : 24 nA
10 : 6 µA
11 : 24 µA
1:0 FLEAD_OFF[1:0] R/W 0h Lead-off frequency
These bits determine the frequency of lead-off detect for each channel.
00 : DC lead-off detection
01 : AC lead-off detection at 7.8 Hz (fCLK / 218)
10 : AC lead-off detection at 31.2 Hz (fCLK / 216)
11 : AC lead-off detection at fDR / 4

CHnSET: Individual Channel Settings (n = 1 to 8) (address = 05h to 0Ch) (reset = 61h)

The CH[1:8]SET control register configures the power mode, PGA gain, and multiplexer settings channels. See the Input Multiplexer section for details. CH[2:8]SET are similar to CH1SET, corresponding to the respective channels.

Figure 55. CHnSET: Individual Channel Settings Register
7 6 5 4 3 2 1 0
PDn GAINn[2:0] SRB2 MUXn[2:0]
R/W-0h R/W-6h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 17. Individual Channel Settings (n = 1 to 8) Field Descriptions

Bit Field Type Reset Description
7 PDn R/W 0h

Power-down


This bit determines the channel power mode for the corresponding channel.
0 : Normal operation
1 : Channel power-down.
When powering down a channel, TI recommends that the channel be set to input short by setting the appropriate MUXn[2:0] = 001 of the CHnSET register.
6:4 GAINn[2:0] R/W 6h PGA gain
These bits determine the PGA gain setting.
000 : 1
001 : 2
010 : 4
011 : 6
100 : 8
101 : 12
110 : 24
111 : Do not use
3 SRB2 R/W 0h SRB2 connection
This bit determines the SRB2 connection for the corresponding channel.
0 : Open
1 : Closed
2:0 MUXn[2:0] R/W 1h Channel input
These bits determine the channel input selection.
000 : Normal electrode input
001 : Input shorted (for offset or noise measurements)
010 : Used in conjunction with BIAS_MEAS bit for BIAS measurements.
011 : MVDD for supply measurement
100 : Temperature sensor
101 : Test signal
110 : BIAS_DRP (positive electrode is the driver)
111 : BIAS_DRN (negative electrode is the driver)

BIAS_SENSP: Bias Drive Positive Derivation Register (address = 0Dh) (reset = 00h)

This register controls the selection of the positive signals from each channel for bias voltage (BIAS) derivation. See the Bias Drive (DC Bias Circuit) section for details.

Registers bits[5:4] are not available for the ADS1299-4. Register bits[7:6] are not available for the ADS1299-4, or ADS1299-6. Set unavailable bits for the associated device to 0 when writing to the register.

Figure 56. BIAS_SENSP: BIAS Positive Signal Derivation Register
7 6 5 4 3 2 1 0
BIASP8 BIASP7 BIASP6 BIASP5 BIASP4 BIASP3 BIASP2 BIASP1
R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 18. BIAS Positive Signal Derivation Field Descriptions

Bit Field Type Reset Description
7 BIASP8 R/W 0h IN8P to BIAS
Route channel 8 positive signal into BIAS derivation
0 : Disabled
1 : Enabled
6 BIASP7 R/W 0h IN7P to BIAS
Route channel 7 positive signal into BIAS derivation
0 : Disabled
1 : Enabled
5 BIASP6 R/W 0h IN6P to BIAS
Route channel 6 positive signal into BIAS derivation
0 : Disabled
1 : Enabled
4 BIASP5 R/W 0h IN5P to BIAS
Route channel 5 positive signal into BIAS derivation
0 : Disabled
1 : Enabled
3 BIASP4 R/W 0h IN4P to BIAS
Route channel 4 positive signal into BIAS derivation
0 : Disabled
1 : Enabled
2 BIASP3 R/W 0h IN3P to BIAS
Route channel 3 positive signal into BIAS derivation
0 : Disabled
1 : Enabled
1 BIASP2 R/W 0h IN2P to BIAS
Route channel 2 positive signal into BIAS channel
0 : Disabled
1 : Enabled
0 BIASP1 R/W 0h IN1P to BIAS
Route channel 1 positive signal into BIAS channel
0 : Disabled
1 : Enabled

BIAS_SENSN: Bias Drive Negative Derivation Register (address = 0Eh) (reset = 00h)

This register controls the selection of the negative signals from each channel for bias voltage (BIAS) derivation. See the Bias Drive (DC Bias Circuit) section for details.

Registers bits[5:4] are not available for the ADS1299-4. Register bits[7:6] are not available for the ADS1299-4, or ADS1299-6. Set unavailable bits for the associated device to 0 when writing to the register.

Figure 57. BIAS_SENSN: BIAS Negative Signal Derivation Register
7 6 5 4 3 2 1 0
BIASN8 BIASN7 BIASN6 BIASN5 BIASN4 BIASN3 BIASN2 BIASN1
R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 19. BIAS Negative Signal Derivation Field Descriptions

Bit Field Type Reset Description
7 BIASN8 R/W 0h IN8N to BIAS
Route channel 8 negative signal into BIAS derivation
0 : Disabled
1 : Enabled
6 BIASN7 R/W 0h IN7N to BIAS
Route channel 7 negative signal into BIAS derivation
0 : Disabled
1 : Enabled
5 BIASN6 R/W 0h IN6N to BIAS
Route channel 6 negative signal into BIAS derivation
0 : Disabled
1 : Enabled
4 BIASN5 R/W 0h IN5N to BIAS
Route channel 5 negative signal into BIAS derivation
0 : Disabled
1 : Enabled
3 BIASN4 R/W 0h IN4N to BIAS
Route channel 4 negative signal into BIAS derivation
0 : Disabled
1 : Enabled
2 BIASN3 R/W 0h IN3N to BIAS
Route channel 3 negative signal into BIAS derivation
0 : Disabled
1 : Enabled
1 BIASN2 R/W 0h IN2N to BIAS
Route channel 2 negative signal into BIAS derivation
0 : Disabled
1 : Enabled
0 BIASN1 R/W 0h IN1N to BIAS
Route channel 1 negative signal into BIAS derivation
0 : Disabled
1 : Enabled

LOFF_SENSP: Positive Signal Lead-Off Detection Register (address = 0Fh) (reset = 00h)

This register selects the positive side from each channel for lead-off detection. See the Lead-Off Detection section for details. The LOFF_STATP register bits are only valid if the corresponding LOFF_SENSP bits are set to 1.

Registers bits[5:4] are not available for the ADS1299-4. Register bits[7:6] are not available for the ADS1299-4, or ADS1299-6. Set unavailable bits for the associated device to 0 when writing to the register.

Figure 58. LOFF_SENSP: Positive Signal Lead-Off Detection Register
7 6 5 4 3 2 1 0
LOFFP8 LOFFP7 LOFFP6 LOFFP5 LOFFP4 LOFFP3 LOFFP2 LOFFP1
R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 20. Positive Signal Lead-Off Detection Field Descriptions

Bit Field Type Reset Description
7 LOFFP8 R/W 0h IN8P lead off
Enable lead-off detection on IN8P
0 : Disabled
1 : Enabled
6 LOFFP7 R/W 0h IN7P lead off
Enable lead-off detection on IN7P
0 : Disabled
1 : Enabled
5 LOFFP6 R/W 0h IN6P lead off
Enable lead-off detection on IN6P
0 : Disabled
1 : Enabled
4 LOFFP5 R/W 0h IN5P lead off
Enable lead-off detection on IN5P
0 : Disabled
1 : Enabled
3 LOFFP4 R/W 0h IN4P lead off
Enable lead-off detection on IN4P
0 : Disabled
1 : Enabled
2 LOFFP3 R/W 0h IN3P lead off
Enable lead-off detection on IN3P
0 : Disabled
1 : Enabled
1 LOFFP2 R/W 0h IN2P lead off
Enable lead-off detection on IN2P
0 : Disabled
1 : Enabled
0 LOFFP1 R/W 0h IN1P lead off
Enable lead-off detection on IN1P
0 : Disabled
1 : Enabled

LOFF_SENSN: Negative Signal Lead-Off Detection Register (address = 10h) (reset = 00h)

This register selects the negative side from each channel for lead-off detection. See the Lead-Off Detection section for details. The LOFF_STATN register bits are only valid if the corresponding LOFF_SENSN bits are set to 1.

Registers bits[5:4] are not available for the ADS1299-4. Register bits[7:6] are not available for the ADS1299-4, or ADS1299-6. Set unavailable bits for the associated device to 0 when writing to the register.

Figure 59. LOFF_SENSN: Negative Signal Lead-Off Detection Register
7 6 5 4 3 2 1 0
LOFFM8 LOFFM7 LOFFM6 LOFFM5 LOFFM4 LOFFM3 LOFFM2 LOFFM1
R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 21. Negative Signal Lead-Off Detection Field Descriptions

Bit Field Type Reset Description
7 LOFFM8 R/W 0h IN8N lead off
Enable lead-off detection on IN8N
0 : Disabled
1 : Enabled
6 LOFFM7 R/W 0h IN7N lead off
Enable lead-off detection on IN7N
0 : Disabled
1 : Enabled
5 LOFFM6 R/W 0h IN6N lead off
Enable lead-off detection on IN6N
0 : Disabled
1 : Enabled
4 LOFFM5 R/W 0h IN5N lead off
Enable lead-off detection on IN5N
0 : Disabled
1 : Enabled
3 LOFFM4 R/W 0h IN4N lead off
Enable lead-off detectionn on IN4N
0 : Disabled
1 : Enabled
2 LOFFM3 R/W 0h IN3N lead off
Enable lead-off detectionion on IN3N
0 : Disabled
1 : Enabled
1 LOFFM2 R/W 0h IN2N lead off
Enable lead-off detectionction on IN2N
0 : Disabled
1 : Enabled
0 LOFFM1 R/W 0h IN1N lead off
Enable lead-off detectionction on IN1N
0 : Disabled
1 : Enabled

LOFF_FLIP: Lead-Off Flip Register (address = 11h) (reset = 00h)

This register controls the direction of the current used for lead-off derivation. See the Lead-Off Detection section for details.

Figure 60. LOFF_FLIP: Lead-Off Flip Register
7 6 5 4 3 2 1 0
LOFF_FLIP8 LOFF_FLIP7 LOFF_FLIP6 LOFF_FLIP5 LOFF_FLIP4 LOFF_FLIP3 LOFF_FLIP2 LOFF_FLIP1
R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 22. Lead-Off Flip Register Field Descriptions

Bit Field Type Reset Description
7 LOFF_FLIP8 R/W 0h Channel 8 LOFF polarity flip
Flip the pull-up or pull-down polarity of the current source on channel 8 for lead-off detection.
0 : No flip = IN8P is pulled to AVDD and IN8N pulled to AVSS
1 : Flipped = IN8P is pulled to AVSS and IN8N pulled to AVDD
6 LOFF_FLIP7 R/W 0h Channel 7 LOFF polarity flip
Flip the pull-up or pull-down polarity of the current source on channel 7 for lead-off detection.
0 : No flip = IN7P is pulled to AVDD and IN7N pulled to AVSS
1 : Flipped = IN7P is pulled to AVSS and IN7N pulled to AVDD
5 LOFF_FLIP6 R/W 0h Channel 6 LOFF polarity flip
Flip the pull-up or pull-down polarity of the current source on channel 6 for lead-off detection.
0 : No flip = IN6P is pulled to AVDD and IN6N pulled to AVSS
1 : Flipped = IN6P is pulled to AVSS and IN6N pulled to AVDD
4 LOFF_FLIP5 R/W 0h Channel 5 LOFF polarity flip
Flip the pull-up or pull-down polarity of the current source on channel 5 for lead-off detection.
0 : No flip = IN5P is pulled to AVDD and IN5N pulled to AVSS
1 : Flipped = IN5P is pulled to AVSS and IN5N pulled to AVDD
3 LOFF_FLIP4 R/W 0h Channel 4 LOFF polarity flip
Flip the pull-up or pull-down polarity of the current source on channel 4 for lead-off detection.
0 : No flip = IN4P is pulled to AVDD and IN4N pulled to AVSS
1 : Flipped = IN4P is pulled to AVSS and IN4N pulled to AVDD
2 LOFF_FLIP3 R/W 0h Channel 3 LOFF polarity flip
Flip the pull-up or pull-down polarity of the current source on channel 3 for lead-off detection.
0 : No flip = IN3P is pulled to AVDD and IN3N pulled to AVSS
1 : Flipped = IN3P is pulled to AVSS and IN3N pulled to AVDD
1 LOFF_FLIP2 R/W 0h Channel 2 LOFF Polarity Flip
Flip the pull-up or pull-down polarity of the current source on channel 2 for lead-off detection.
0 : No flip = IN2P is pulled to AVDD and IN2N pulled to AVSS
1 : Flipped = IN2P is pulled to AVSS and IN2N pulled to AVDD
0 LOFF_FLIP1 R/W 0h Channel 1 LOFF Polarity Flip
Flip the pull-up or pull-down polarity of the current source on channel 1 for lead-off detection.
0 : No flip = IN1P is pulled to AVDD and IN1N pulled to AVSS
1 : Flipped = IN1P is pulled to AVSS and IN1N pulled to AVDD

LOFF_STATP: Lead-Off Positive Signal Status Register (address = 12h) (reset = 00h)

This register stores the status of whether the positive electrode on each channel is on or off. See the Lead-Off Detection section for details. Ignore the LOFF_STATP values if the corresponding LOFF_SENSP bits are not set to 1.

When the LOFF_SENSEP bits are 0, the LOFF_STATP bits should be ignored.

Figure 61. LOFF_STATP: Lead-Off Positive Signal Status Register (Read-Only)
7 6 5 4 3 2 1 0
IN8P_OFF IN7P_OFF IN6P_OFF IN5P_OFF IN4P_OFF IN3P_OFF IN2P_OFF IN1P_OFF
R-0h R-0h R-0h R-0h R-0h R-0h R-0h R-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 23. Lead-Off Positive Signal Status Field Descriptions

Bit Field Type Reset Description
7 IN8P_OFF R 0h Channel 8 positive channel lead-off status
Status of whether IN8P electrode is on or off
0 : Electrode is on
1 : Electrode is off
6 IN7P_OFF R 0h Channel 7 positive channel lead-off status
Status of whether IN7P electrode is on or off
0 : Electrode is on
1 : Electrode is off
5 IN6P_OFF R 0h Channel 6 positive channel lead-off status
Status of whether IN6P electrode is on or off
0 : Electrode is on
1 : Electrode is off
4 IN5P_OFF R 0h Channel 5 positive channel lead-off status
Status of whether IN5P electrode is on or off
0 : Electrode is on
1 : Electrode is off
3 IN4P_OFF R 0h Channel 4 positive channel lead-off status
Status of whether IN4P electrode is on or off
0 : Electrode is on
1 : Electrode is off
2 IN3P_OFF R 0h Channel 3 positive channel lead-off status
Status of whether IN3P electrode is on or off
0 : Electrode is on
1 : Electrode is off
1 IN2P_OFF R 0h Channel 2 positive channel lead-off status
Status of whether IN2P electrode is on or off
0 : Electrode is on
1 : Electrode is off
0 IN1P_OFF R 0h Channel 1 positive channel lead-off status
Status of whether IN1P electrode is on or off
0 : Electrode is on
1 : Electrode is off

LOFF_STATN: Lead-Off Negative Signal Status Register (address = 13h) (reset = 00h)

This register stores the status of whether the negative electrode on each channel is on or off. See the Lead-Off Detection section for details. Ignore the LOFF_STATN values if the corresponding LOFF_SENSN bits are not set to 1.

When the LOFF_SENSEN bits are 0, the LOFF_STATP bits should be ignored.

Figure 62. LOFF_STATN: Lead-Off Negative Signal Status Register (Read-Only)
7 6 5 4 3 2 1 0
IN8N_OFF IN7N_OFF IN6N_OFF IN5N_OFF IN4N_OFF IN3N_OFF IN2N_OFF IN1N_OFF
R-0h R-0h R-0h R-0h R-0h R-0h R-0h R-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 24. Lead-Off Negative Signal Status Field Descriptions

Bit Field Type Reset Description
7 IN8N_OFF R 0h Channel 8 negative channel lead-off status
Status of whether IN8N electrode is on or off
0 : Electrode is on
1 : Electrode is off
6 IN7N_OFF R 0h Channel 7 negative channel lead-off status
Status of whether IN7N electrode is on or off
0 : Electrode is on
1 : Electrode is off
5 IN6N_OFF R 0h Channel 6 negative channel lead-off status
Status of whether IN6N electrode is on or off
0 : Electrode is on
1 : Electrode is off
4 IN5N_OFF R 0h Channel 5 negative channel lead-off status
Status of whether IN5N electrode is on or off
0 : Electrode is on
1 : Electrode is off
3 IN4N_OFF R 0h Channel 4 negative channel lead-off status
Status of whether IN4N electrode is on or off
0 : Electrode is on
1 : Electrode is off
2 IN3N_OFF R 0h Channel 3 negative channel lead-off status
Status of whether IN3N electrode is on or off
0 : Electrode is on
1 : Electrode is off
1 IN2N_OFF R 0h Channel 2 negative channel lead-off status
Status of whether IN2N electrode is on or off
0 : Electrode is on
1 : Electrode is off
0 IN1N_OFF R 0h Channel 1 negative channel lead-off status
Status of whether IN1N electrode is on or off
0 : Electrode is on
1 : Electrode is off

GPIO: General-Purpose I/O Register (address = 14h) (reset = 0Fh)

The general-purpose I/O register controls the action of the three GPIO pins. When RESP_CTRL[1:0] is in mode 01 and 11, the GPIO2, GPIO3, and GPIO4 pins are not available for use.

Figure 63. GPIO: General-Purpose I/O Register
7 6 5 4 3 2 1 0
GPIOD[4:1] GPIOC[4:1]
R/W-0h R/W-Fh
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 25. General-Purpose I/O Field Descriptions

Bit Field Type Reset Description
7:4 GPIOD[4:1] R/W 0h GPIO data
These bits are used to read and write data to the GPIO ports.
When reading the register, the data returned correspond to the state of the GPIO external pins, whether they are programmed as inputs or as outputs. As outputs, a write to the GPIOD sets the output value. As inputs, a write to the GPIOD has no effect. GPIO is not available in certain respiration modes.
3:0 GPIOC[4:1] R/W Fh GPIO control (corresponding GPIOD)
These bits determine if the corresponding GPIOD pin is an input or output.
0 : Output
1 : Input

MISC1: Miscellaneous 1 Register (address = 15h) (reset = 00h)

This register provides the control to route the SRB1 pin to all inverting inputs of the four, six, or eight channels (ADS1299-4, ADS1299-6, or ADS1299).

Figure 64. MISC1: Miscellaneous 1 Register
7 6 5 4 3 2 1 0
0 0 SRB1 0 0 0 0 0
R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 26. Miscellaneous 1 Register Field Descriptions

Bit Field Type Reset Description
7:6 Reserved R/W 0h Reserved
Always write 0h
5 SRB1 R/W 0h Stimulus, reference, and bias 1
This bit connects the SRB1 to all 4, 6, or 8 channels inverting inputs
0 : Switches open
1 : Switches closed
4:0 Reserved R/W 0h Reserved
Always write 0h

MISC2: Miscellaneous 2 (address = 16h) (reset = 00h)

This register is reserved for future use.

Figure 65. MISC1: Miscellaneous 1 Register
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 0
R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 27. Miscellaneous 1 Register Field Descriptions

Bit Field Type Reset Description
7:0 Reserved R/W 0h Reserved
Always write 0h

CONFIG4: Configuration Register 4 (address = 17h) (reset = 00h)

This register configures the conversion mode and enables the lead-off comparators.

Figure 66. CONFIG4: Configuration Register 4
7 6 5 4 3 2 1 0
0 0 0 0 SINGLE_SHOT 0 PD_LOFF_ COMP 0
R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset

Table 28. Configuration Register 4 Field Descriptions

Bit Field Type Reset Description
7:4 Reserved R/W 0h Reserved
Always write 0h
3 SINGLE_SHOT R/W 0h Single-shot conversion
This bit sets the conversion mode.
0 : Continuous conversion mode
1 : Single-shot mode
2 Reserved R/W 0h Reserved
Always write 0h
1 PD_LOFF_COMP R/W 0h Lead-off comparator power-down
This bit powers down the lead-off comparators.
0 : Lead-off comparators disabled
1 : Lead-off comparators enabled
0 Reserved R/W 0h Reserved
Always write 0h