SNVS458D June   2007  – October 2016 LP55281

PRODUCTION DATA.  

  1. Features
  2. Applications
  3. Description
  4. Revision History
  5. Pin Configuration and Functions
  6. Specifications
    1. 6.1 Absolute Maximum Ratings
    2. 6.2 ESD Ratings
    3. 6.3 Recommended Operating Conditions
    4. 6.4 Thermal Information
    5. 6.5 Electrical Characteristics
    6. 6.6 SPI Timing Requirements
    7. 6.7 I2C Timing Requirements
    8. 6.8 Boost Converter Typical Characteristics
    9. 6.9 RGB Driver Typical Characteristics
  7. Detailed Description
    1. 7.1 Overview
    2. 7.2 Functional Block Diagram
    3. 7.3 Feature Description
      1. 7.3.1 Magnetic Boost DC-DC Converter
        1. 7.3.1.1 Boost Standby Mode
        2. 7.3.1.2 Boost Output Voltage Control
        3. 7.3.1.3 Boost Frequency Control
      2. 7.3.2 Functionality of RGB LED Outputs (R1-4, G1-4, B1-4)
        1. 7.3.2.1 PWM Control Timing
      3. 7.3.3 Audio Synchronization
        1. 7.3.3.1 Control of Audio Synchronization
        2. 7.3.3.2 ALED Driver
          1. 7.3.3.2.1 Adjustment of ALED Driver
      4. 7.3.4 LED Test Interface
        1. 7.3.4.1 LED Test Procedure
        2. 7.3.4.2 LED Test Time Estimation
      5. 7.3.5 7-V Shielding
    4. 7.4 Device Functional Modes
      1. 7.4.1 Modes Of Operation
    5. 7.5 Programming
      1. 7.5.1 SPI Interface
      2. 7.5.2 I2C Compatible Serial Bus Interface
        1. 7.5.2.1 Interface Bus Overview
        2. 7.5.2.2 Data Transactions
        3. 7.5.2.3 Acknowledge Cycle
        4. 7.5.2.4 Acknowledge After Every Byte Rule
        5. 7.5.2.5 Addressing Transfer Formats
        6. 7.5.2.6 Control Register Write Cycle
        7. 7.5.2.7 Control Register Read Cycle
    6. 7.6 Register Maps
  8. Application and Implementation
    1. 8.1 Application Information
    2. 8.2 Typical Application
      1. 8.2.1 Design Requirements
      2. 8.2.2 Detailed Design Procedure
        1. 8.2.2.1 Recommended External Components
          1. 8.2.2.1.1 Output Capacitor, COUT
          2. 8.2.2.1.2 List Of Recommended External Components
          3. 8.2.2.1.3 Input Capacitor, CIN
          4. 8.2.2.1.4 Output Diode, D1
          5. 8.2.2.1.5 Inductor, L
      3. 8.2.3 Application Curves
    3. 8.3 Initialization Set Up Example
  9. Power Supply Recommendations
  10. 10Layout
    1. 10.1 Layout Guidelines
      1. 10.1.1 Boost Output Capacitor Placement
      2. 10.1.2 Schottky Diode Placement
      3. 10.1.3 Inductor Placement
      4. 10.1.4 Boost Input Capacitor Placement
    2. 10.2 Layout Example
  11. 11Device and Documentation Support
    1. 11.1 Device Support
      1. 11.1.1 Third-Party Products Disclaimer
    2. 11.2 Related Documentation
    3. 11.3 Receiving Notification of Documentation Updates
    4. 11.4 Community Resources
    5. 11.5 Trademarks
    6. 11.6 Electrostatic Discharge Caution
    7. 11.7 Glossary
  12. 12Mechanical, Packaging, and Orderable Information

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7 Detailed Description

7.1 Overview

The LP55281 boost DC-DC converter generates a 4-V to 5.3-V supply voltage for the LEDs from single Li-Ion battery (3 V...4.5 V). The output voltage is controlled with an 8-bit register in 9 steps. The converter is a magnetic switching PWM mode DC-DC converter with a current limit. When timing resistor RT is 82 kΩ, the converter has three options for switching frequency: 1 MHz, 1.67 MHz, and 2 MHz (default). Timing resistor defines the internal oscillator frequency and thus directly affects boost frequency and all internally generated timing (RGB, ALED) of the circuit.

The LP55281 boost converter uses pulse-skipping elimination to stabilize the noise spectrum. Even with light load or no load a minimum length current pulse is fed to the inductor. An active load is used to remove the excess charge from the output capacitor at very light loads. At very light load and when input and output voltages are very close to each other, the pulse skipping is not completely eliminated. Output voltage must be at least 0.5 V higher than input voltage to avoid pulse skipping. Reducing the switching frequency also reduces the required voltage difference.

Active load can be disabled with the EN_AUTOLOAD bit. Disabling increases the efficiency at light loads, but the downside is that pulse skipping will occur. The boost converter must be stopped when there is no load to minimize the current consumption.

The topology of the magnetic boost converter is called current programmed mode (CPM) control, where the inductor current is measured and controlled with the feedback. The user can program the output voltage of the boost converter. The output voltage control changes the resistor divider in the feedback loop.

Figure 10 shows the boost topology with the protection circuitry. Four different protection schemes are implemented:

  1. Overvoltage protection — limits the maximum output voltage
    • Keeps the output below breakdown voltage.
    • Prevents boost operation if battery voltage is much higher than desired output.
  2. Overcurrent protection — limits the maximum inductor current
    • Voltage over switching NMOS is monitored; too high voltages turn the switch off.
  3. Feedback break protection — prevents uncontrolled operation if FB pin gets disconnected.
  4. Duty cycle limiting, done with digital control.
LP55281 20201177.gif Figure 10. Boost Converter Topology

7.2 Functional Block Diagram

LP55281 20201174.gif

7.3 Feature Description

7.3.1 Magnetic Boost DC-DC Converter

7.3.1.1 Boost Standby Mode

User can stop the boost converter operation by writing the Enables register bit EN_BOOST low. When EN_BOOST is written high, the converter starts for 10 ms in PFM mode and then goes to PWM mode.

7.3.1.2 Boost Output Voltage Control

User can control the Boost output voltage by boost output 8-bit register.

BOOST OUTPUT [7:0] Register 0Fh BOOST OUTPUT VOLTAGE (TYPICAL)
Bin Hex
0000 0000 00 4 V
0000 0001 01 4.25 V
0000 0011 03 4.4 V
0000 0111 07 4.55 V
0000 1111 0F 4.7 V
0001 1111 1F 4.85 V
0011 1111 3F 5 V (default)
0111 1111 7F 5.15 V
1111 1111 FF 5.3 V
LP55281 20201197.gif Figure 11. Boost Output Voltage Control

7.3.1.3 Boost Frequency Control

Register-frequency selections (address 10h). Register default value after reset is 07h.

FRQ_SEL[2:0] FREQUENCY
1XX 2 MHz
01X 1.67 MHz
001 1 MHz

7.3.2 Functionality of RGB LED Outputs (R1-4, G1-4, B1-4)

The LP55281 device has 4 sets of RGB/color LED outputs. Each set has 3 outputs, which can be controlled individually with a 6-bit PWM control register. The pulsed current level for each LED output is set with a single external resistor RRGB and a 2-bit coarse adjustment bit for each LED output (see Table 1 and Table 2).

Table 1. LED Current Level Adjust

Rx_IPLS[7:6], Gx_IPLS[7:6], Bx_IPLS[7:6] SINK CURRENT PULSE (IMAX = 100 × 1.23 / RRGB) – IPLS
00 0.25 × IMAX
01 0.50 × IMAX
10 0.75 × IMAX
11 1.00 × IMAX

Table 2. LED PWM Control

Rx_PWM[5:0], Gx_PWM[5:0], Bx_PWM[5:0] AVERAGE SINK CURRENT PULSE RATIO (%)
000 000 0 0
000 001 1/63 × IPLS 1.6
000 010 2/63 × IPLS 3.2
... ... ...
111 110 62/63 × IPLS 98.4
111 111 63/63 × IPLS 100

Each RGB set must be enabled separately by setting EN_RGBx bit to 1. The device must be enabled (NSTBY = 1) before the RGB outputs can be activated.

When any of EN_RGBx bits are set to 1 and NSTBY = 1, the RGB driver takes a certain quiescent current from battery even if all PWM control bits are 0. The quiescent current is dependent on RRGB resistor, and can be calculated from formula IR_RGB = 1.23 V / RRGB.

7.3.2.1 PWM Control Timing

PWM frequency can be selected from 3 predefined values: 10 kHz, 20 kHz, and 40 kHz. The frequency is selected with FPWM1 and FPWM0 bits, see Table 3.

Table 3. PWM Frequency

FPWM1 FPWM0 PWM FREQUENCY (fPWM)
0 0 9.92 kHz
0 1 19.84 kHz
1 0 39.68 kHz
1 1 39.68 kHz

Each RGB set has equivalent internal PWM timing between R, G, and B: R has a fixed start time, G has a fixed mid-pulse time, and B has a fixed-pulse end time. PWM start time for each RGB set is different in order to minimize the instantaneous current loading due to the current sink switch on transition. See Figure 12 for details.

LP55281 20201117.gif Figure 12. Timing Diagram

7.3.3 Audio Synchronization

The ALED output can be synchronized to incoming audio with an audio-synchronization feature. Audio synchronization synchronizes ALED based on the peak amplitude of the input signal. Programmable gain and automatic gain control function are also available for adjustment of input signal amplitude to light response. Control of ALED brightness refreshing frequency is done with four different frequency configurations. The digitized input signal has DC component that is removed by a digital DC-remover (–3 dB at 500 Hz). LP55281 has a 2-channel audio (stereo) input for audio synchronization, as shown in Figure 13. The inputs accept signals in the range of 0 V to 1.6 V peak-to-peak, and these signals are mixed into a single wave so that they can be filtered simultaneously.

LP55281 audio synchronization is mainly realized digitally, and it consists of the following signal path blocks (see Figure 13):

  • Input buffer
  • AD converter
  • Automatic gain control (AGC) and manually programmable gain
  • Peak detector
LP55281 20201119.gif Figure 13. ALED Audio Synchronization

7.3.3.1 Control of Audio Synchronization

Table 4 describes the controls required for audio synchronization. ALED brightness control through serial interface is not available when audio synchronization is enabled.

Table 4. Audio Synchronization Control (Registers 0Dh And 0Eh)

NAME BIT DESCRIPTION
GAIN_SEL[2:0] Register 0Dh
Bits 7-5		 Input signal gain control. Gain has a range from 0 dB to -46 dB.
[000] = 0 dB, [001] = –6 dB, [010] = –12 dB, [011] = –18 dB,
[100] = -24 dB, [101] = -31 dB, [110] = -37 dB, [111] = –46 dB
DC_FREQ Register 0Dh
Bit 4		 Control of the high-pass filter's corner frequency:
0 = 80 Hz
1 = 510 Hz
EN_AGC Register 0Dh
Bits 3		 Automatic gain control. Set EN_AGC = 1 to enable automatic control or 0 to disable. When EN_AGC is disabled, the audio input signal gain value is defined by GAIN_SEL.
EN_SYNC Register 0Dh
Bits 2		 Audio synchronization enabled. Set EN_SYNC = 1 to enable audio synchronization or 0 to disable.
SPEED_CTRL[1:0] Register 0Dh
Bits 1-0		 Control for refreshing frequency. Sets the typical refreshing rate for the ALED output
[00] = FASTEST, [01] = 15 Hz, [10] = 7.6 Hz, [11] = 3.8 Hz
THRESHOLD[3:0] Register 0Eh
Bits 3-0		 Control for the audio input threshold. Sets the typical threshold for the audio inputs signals. May be needed if there is noise on the audio lines.

Table 5. Audio Input Threshold Setting (Register 0Eh)

THRESHOLD[3:0] THRESHOLD LEVEL (mV, typical)
0000 Disabled
0001 0.2
0010 0.4
... ...
1110 2.5
1111 2.7

Table 6. Typical Gain Values vs Audio Input Amplitude

AUDIO INPUT AMPLITUDE mVP-P GAIN VALUE (dB)
0 to 10 0
0 to 20 –6
0 to 40 –12
1 to 85 –18
3 to 170 –24
5 to 400 –31
10 to 800 –37
20 to 1600 –46

7.3.3.2 ALED Driver

The LP55281 device has a single ALED driver. It is a constant current sink with an 8-bit control. ALED driver can be used as a DC current sink or an audio synchronized current sink. Note, that when the audio synchronization function is enabled, the 8-bit current control register has no effect.

ALED driver is enabled when audio synchronization is enabled (EN_SYNC = 1) or when ALED[7:0] control byte has other than 00h value.

LP55281 20201107.gif Figure 14. ALED Driver

7.3.3.2.1 Adjustment of ALED Driver

Adjustment of the ALED driver current (Register 0Ch) is described in Table 7.

Table 7. ALED Driver Current

ALED[7:0] DRIVER CURRENT, mA (typical)
0000 0000 0
0000 0001 0.06
0000 0010 0.1
... ...
1111 1101 14.8
1111 1110 14.9
1111 1111 15

With values other than those in Table 7, the current value can be calculated to be (15 mA / 255) × ALED[7:0], where ALED[7:0] is value in decimals.

LP55281 20201120.gif Figure 15. Principle of LED Connection to ADC

7.3.4 LED Test Interface

All LED pin voltages and boost output voltage in LP55281 can be measured and value can be read through the SPI/I2C compatible interface. MUX_LED[3:0] bits in the LED test register (address 12h) are used to select one of the LED outputs or boost output for measurement. The selected output is connected to the internal ADC through a 55-kΩ resistor divider. The AD conversion is activated by setting the EN_LTEST bit to 1. The first conversion is ready after 128 µs from this. The result can be read from the ADC output register (address 13h). The device executes the AD conversions automatically once in every 128 µs period, as long as the EN_LTEST bit is 1.

User can set the preferred DC current level with the LED driver controls. The PWM of the RGB drivers must be set to 100% — otherwise random variation can appear on results. Note that the 55-kΩ resistor divider causes small additional current through the LED under measurement.

ADC result can be converted into a voltage value (of the selected pin) by multiplying the ADC result (in decimals) with 27.345 mV (value of LSB). The calculated voltage value is the voltage between the selected pin and ground. The internal LDO voltage is used as a reference voltage for the conversion. The accuracy of LDO is ± 3%, which is defining the overall accuracy. The non-linearity and offset figures are both better than 2LSB.

Table 8. LED Multiplexing (Register 12h)

MUX_LED[3:0] CONNECTION
0000 R1
0001 G1
0010 B1
0011 R2
0100 G2
0101 B2
0110 R3
0111 G3
1000 B3
1001 R4
1010 G4
1011 B4
1100 ALED
1101
1110
1111 Boost output

7.3.4.1 LED Test Procedure

An example of LED test sequence is presented here. Note that user can use incremental write sequence on I2C. The test sequence consists of the basic setup and measurement phases for all RGB LEDs and boost voltage.

Basic setup phase for the device:

  1. Give reset to LP55281 (by power on, NRST pin or write any data to register 60h)
  2. Set the preferred value for RED1 (write 3Fh, 7Fh, BFh or FFh to register 00h)
  3. Set the preferred value for GREEN1 (write 3Fh, 7Fh, BFh or FFh to register 01h)
  4. Set the preferred value for BLUE1 (write 3Fh, 7Fh, BFh or FFh to register 02h)
  5. Set the preferred value for RED2 (write 3Fh, 7Fh, BFh or FFh to register 03h)
  6. Set the preferred value for GREEN2 (write 3Fh, 7Fh, BFh or FFh to register 04h)
  7. Set the preferred value for BLUE2 (write 3Fh, 7Fh, BFh or FFh to register 05h)
  8. Set the preferred value for RED3 (write 3Fh, 7Fh, BFh or FFh to register 06h)
  9. Set the preferred value for GREEN3 (write 3Fh, 7Fh, BFh or FFh to register 07h)
  10. Set the preferred value for BLUE3 (write 3Fh, 7Fh, BFh or FFh to register 08h)
  11. Set the preferred value for RED4 (write 3Fh, 7Fh, BFh or FFh to register 09h)
  12. Set the preferred value for GREEN4 (write 3Fh, 7Fh, BFh or FFh to register 0Ah)
  13. Set the preferred value for BLUE4 (write 3Fh, 7Fh, BFh or FFh to register 0Bh)
  14. Set the preferred value for ALED (write 01h - FFh to register 0Ch)
  15. Dummy write: 00h to register 0Dh (Only if the incremental write sequence is used)
  16. Dummy write: 00h to register 0Eh (Only if the incremental write sequence is used)
  17. Set preferred boost voltage (write 00h - FFh to register 0Fh)
  18. Set preferred boost frequency (write 00h - 07h to register 10h, PWM frequency can be anything)
  19. Enable boost and RGB drivers (write CFh to register 11h)
  20. Wait 20 ms for the device and boost start-up

Measurement phase:

  1. Enable LED test and select output (write 1xh to register 12h)
  2. Wait for 128 µs
  3. Read ADC output (read register 13h)
  4. Go to step 1 of measurement phase and define next output to be measured as many times as needed
  5. Disable LED test (write 00h to register 12h) or give reset to the device (see step 1 in basic setup phase)

7.3.4.2 LED Test Time Estimation

Assuming the maximum clock frequencies used in SPI or I2C-compatible interfaces, Table 9 predicts the overall test sequence time for the test procedure shown above. This estimation gives the shortest time possible. Incremental write is assumed with I2C. Reset and LED test disable are not included.

Table 9. LED Test Time

TEST PHASE TIME (ms)
I2C SPI
Setup 0.528 0.024
Boost start-up 20 20
14 measurements 4.137 1.831
Total time 24.7 21.9

7.3.5 7-V Shielding

To shield the LP55281 device from high-input voltages (6 V to 7.2 V), the use of an external 2.8-V LDO is required. This 2.8-V voltage protects internally the device against high voltage condition. The recommended connection is shown in the picture below. Internally both logic and analog circuitry works at 2.8-V supply voltage. Both supply voltage pins should have separate filtering capacitors. TI recommends pulling down the external LDO voltage when it is disabled in order to minimize the leakage current of the LED outputs.

LP55281 20201121.gif Figure 16. LP55281 With 7-V Shielding

In cases where high voltage is not an issue, the alternative connection is shown below.

LP55281 20201122.gif Figure 17. LP55281 Without 7-V Shielding

7.4 Device Functional Modes

7.4.1 Modes Of Operation

    RESET: In the RESET mode all the internal registers are reset to the default values and the device goes to STANDBY mode after reset. NSTBY control bit is low after reset by default. Reset is entered always if Reset Register is written, internal Power On Reset is active, or NRST pin is pulled down externally. The LP55281 can be reset by writing any data to the Reset Register (address 60H). Power On Reset (POR) will activate during the device startup or when the supply voltage VDD2 falls below 1.5 V. Once VDD2 rises above 1.5V, POR inactivates, and the device continues to the STANDBY mode.
    STANDBY: The STANDBY mode is entered if the register bit NSTBY is LOW. This is the low power consumption mode, when all circuit functions are disabled. Registers can be written in this mode and the control bits are effective immediately after startup.
    STARTUP: When NSTBY bit is written high, the INTERNAL STARTUP SEQUENCE powers up all the needed internal blocks (VREF, Oscillator, etc.). To ensure the correct oscillator initialization, a 10 ms delay is generated by the internal state-machine. If the device temperature rises too high, the Thermal Shutdown (TSD) disables the device operation and STARTUP mode is entered until no thermal shutdown is present.
    BOOST STARTUP: Soft start for boost output is generated in the BOOST STARTUP mode. The boost output is raised in PWM mode during the 10 ms delay generated by the state-machine. The Boost startup is entered from Internal Startup Sequence if EN_BOOST is HIGH or from Normal mode when EN_BOOST is written HIGH. During the 10 ms Boost Startup time all LED outputs are switched off to ensure smooth startup.
    NORMAL: During NORMAL mode the user controls the device using the Control Registers. The registers can be written in any sequence and any number of bits can be altered in a register in one write.
LP55281 20201175.gif

7.5 Programming

The LP55281 supports two different interface modes:

User can define the serial interface by IF_SEL pin. If IF_SEL = 0, I2C mode is selected.

7.5.1 SPI Interface

The LP55281 is compatible with SPI serial-bus specification and it operates as a slave. The transmission consists of 16-bit write and read cycles. One cycle consists of a 7 address bits, 1 read/write (RW) bit and 8 data bits. RW bit high state defines a write cycle and low a read cycle. SO output is normally in high-impedance state and it is active only when data is sent out during a read cycle. A pullup resistor may be needed in SO line if a floating logic signal can cause unintended current consumption in the input circuits where SO is connected. The Address and Data are transmitted MSB first. The slave select signal (SS) must be low during the cycle transmission. SS resets the interface when high and it has to be taken high between successive cycles. Data is clocked in on the rising edge of the clock signal (SCK), while data is clocked out on the falling edge of SCK.

LP55281 20201123.gif Figure 18. SPI Write Cycle
LP55281 20201124.gif Figure 19. SPI Read Cycle

7.5.2 I2C Compatible Serial Bus Interface

7.5.2.1 Interface Bus Overview

The I2C compatible synchronous serial interface provides access to the programmable functions and registers on the device. This protocol uses a two-wire interface for bidirectional communications between the devices connected to the bus. The two interface lines are the serial data line (SDA) and the serial clock line (SCL). These lines should be connected to a positive supply, via a pullup resistor and remain HIGH even when the bus is idle.

For every device on the bus is assigned a unique address and it acts as a master or a slave, depending on whether it generates or receives the SCL. When LP55281 is connected in parallel with other I2C compatible devices, the LP55281 supply voltages VDD1, VDD2 and VDDIO must be active. Supplies are required to make sure that the LP55281 does not disturb the SDA and SCL lines.

7.5.2.2 Data Transactions

One data bit is transferred during each clock pulse. Data is sampled during the high state of the SCL. Consequently, throughout the clock's high period, the data should remain stable. Any changes on the SDA line during the high states of the SCL and in the middle of the transaction, aborts the current transaction. New data should be sent during the low SCL state. This protocol permits a single data line to transfer both command/control information and data using the synchronous serial clock.

LP55281 20201149.gif Figure 20. Data Validity

Each data transaction is composed of a start condition, a number of byte transfers (set by the software) and a stop condition to terminate the transaction. Every byte written to the SDA bus must be 8 bits long and is transferred with the most significant bit first. After each byte, an acknowledge signal must follow. The following sections provide further details of this process.

LP55281 20201152.gif Figure 21. Acknowledge Signal

The Master device on the bus always generates the start and stop conditions (control codes). After a start condition is generated, the bus is considered busy and it retains this status until a certain time after a stop condition is generated. A high-to-low transition of the data line (SDA), while the clock (SCL) is high, indicates a Start Condition. A low-to-high transition of the SDA line, while the SCL is high, indicates a stop condition.

LP55281 20201150.gif Figure 22. Start And Stop Conditions

In addition to the first start condition, a repeated start condition can be generated in the middle of a transaction. This allows another device to be accessed or a register read cycle.

7.5.2.3 Acknowledge Cycle

The acknowledge cycle consists of two signals: the acknowledge clock pulse the master sends with each byte transferred, and the acknowledge signal sent by the receiving device.

The master generates the acknowledge clock pulse on the ninth clock pulse of the byte transfer. The transmitter releases the SDA line (permits it to go high) to allow the receiver to send the acknowledge signal. The receiver must pull down the SDA line during the acknowledge clock pulse and ensure that SDA remains low during the high period of the clock pulse, thus signaling the correct reception of the last data byte and its readiness to receive the next byte.

7.5.2.4 Acknowledge After Every Byte Rule

The master generates an acknowledge clock pulse after each byte transfer. The receiver sends an acknowledge signal after every byte received.

There is one exception to theacknowledge after every byte rule. When the master is the receiver, it must indicate to the transmitter an end of data by not-acknowledging (negative acknowledge) the last byte clocked out of the slave. This negative acknowledge still includes the acknowledge clock pulse (generated by the master), but the SDA line is not pulled down.

7.5.2.5 Addressing Transfer Formats

Each device on the bus has a unique slave address. The LP55281 operates as a slave device with 7-bit address. LP55281 I2C address is pin selectable from two different choices. The LP55281 address is 4Ch (SI/A0 = 0) or 4Dh (SI/A0 = 1) as selected with SI/A0 pin. If eighth bit is used for programming, the 8th bit is 1 for read and 0 for write.

Before any data is transmitted, the master transmits the address of the slave being addressed. The slave device should send an acknowledge signal on the SDA line, once it recognizes its address.

The slave address is the first seven bits after a start condition. The direction of the data transfer (R/W) depends on the bit sent after the slave address (the eighth bit).

When the slave address is sent, each device in the system compares this slave address with its own. If there is a match, the device considers itself addressed and sends an acknowledge signal. Depending upon the state of the R/W bit (1 for read, 0 for write), the device acts as a transmitter or a receiver.

LP55281 20201151.gif Figure 23. I2C Device Address

7.5.2.6 Control Register Write Cycle

  • Master device generates start condition
  • Master device sends slave address (7 bits) and the data direction bit (r/w=0).
  • Slave device sends acknowledge signal if the slave address is correct.
  • Master sends control register address (8 bits).
  • Slave sends acknowledge signal.
  • Master sends data byte to be written to the addressed register.
  • Slave sends acknowledge signal.
  • If master will send further data bytes, the control register address will be incremented by one after acknowledge signal
  • Write cycle ends when the master creates stop condition.

7.5.2.7 Control Register Read Cycle

  • Master device generates a start condition.
  • Master device sends slave address (7 bits) and the data direction bit (r/w=0).
  • Slave device sends acknowledge signal if the slave address is correct.
  • Master sends control register address (8 bits).
  • Slave sends acknowledge signal.
  • Master device generates repeated start condition.
  • Master sends the slave address (7 bits) and the data direction bit (r/w=1).
  • Slave sends acknowledge signal if the slave address is correct.
  • Slave sends data byte from addressed register.
  • If the master device sends acknowledge signal, the control register address will be incremented by one. Slave device sends data byte from addressed register.
  • Read cycle ends when the master does not generate acknowledge signal after data byte and generates stop condition.
ADDRESS MODE
Data Read <Start Condition>
<Slave Address><r/w = 0>[Ack]
<Register Address>[Ack]
<Repeated Start Condition>
<Slave Address><r/w = 1>[Ack]
[Register Data]<Ack or NAck>
...additional reads from subsequent register address possible
<Stop Condition>
Data Write <Start Condition>
<Slave Address><r/w = 0>[Ack]
<Register Address>[Ack]
<Register Data>[Ack]
...additional writes to subsequent register address possible
<Stop Condition>

< > Data from master, [ ] data from slave

LP55281 20201194.gif Figure 24. Register READ Format

When a READ function is to be accomplished, a WRITE function must precede the READ function, as shown in the Read Cycle waveform.

LP55281 20201193.gif Figure 25. Register WRITE Format
  • w = write (SDA = 0)
  • r = read (SDA = 1)
  • ack = acknowledge (SDA pulled down by either master or slave)
  • rs = repeated start
  • id = 7-bit device address

7.6 Register Maps

Following table summarizes the registers and their default values

Address Register D7 D6 D5 D4 D3 D2 D1 D0
00h RED1 R1 - IPLS[7:6] R1_PWM[5:0]
0 0 0 0 0 0 0 0
01h GREEN1 G1 - IPLS[7:6] G1_PWM[5:0]
0 0 0 0 0 0 0 0
02h BLUE1 B1 - IPLS[7:6] B1_PWM[5:0]
0 0 0 0 0 0 0 0
03h RED2 R2 - IPLS[7:6] R2_PWM[5:0]
0 0 0 0 0 0 0 0
04h GREEN2 G2 - IPLS[7:6] G2_PWM[5:0]
0 0 0 0 0 0 0 0
05h BLUE2 B2 - IPLS[7:6] B2_PWM[5:0]
0 0 0 0 0 0 0 0
06h RED3 R3 - IPLS[7:6] R3_PWM[5:0]
0 0 0 0 0 0 0 0
07h GREEN3 G3 - IPLS[7:6] G3_PWM[5:0]
0 0 0 0 0 0 0 0
08h BLUE3 B3 - IPLS[7:6] B3_PWM[5:0]
0 0 0 0 0 0 0 0
09h RED4 R4 - IPLS[7:6] R4_PWM[5:0]
0 0 0 0 0 0 0 0
0Ah GREEN4 G4 - IPLS[7:6] G4_PWM[5:0]
0 0 0 0 0 0 0 0
0Bh BLUE4 B4 - IPLS[7:6] B4_PWM[5:0]
0 0 0 0 0 0 0 0
0Ch ALED ALED[7:0]
0 0 0 0 0 0 0 0
0Dh Audio Sync CTRL1 GAIN_SEL[2:0] DC_FREQ EN_AGC EN_SYNC SPEED_CTRL[1:0]
0 0 0 0 0 0 1 1
0Eh Audio Sync CTRL2 THRESHOLD[3:0]
0 0 0 0
0Fh Boost Output Boost[7:0]
0 0 1 1 1 1 1 1
10h Frequency Selections FPWM1 FPWM0 FRQ_SEL[2:0]
0 0 1 1 1
11h Enables NSTBY EN_BOOST EN_AUTOLOAD EN_RGB4 EN_RGB3 EN_RGB2 EN_RGB1
0 0 0 0 0 0 0
12h LED Test EN_LTEST MUX_LED[3:0]
0 0 0 0 0
13h(1) ADC Output DATA[7:0]
0 0 0 0 0 0 0 0
r/o r/o r/o r/o r/o r/o r/o r/o
60h Reset Writing any data to Reset Register resets LP55281
(1) r/o = read-only