ZHCSCI8 May   2014

PRODUCTION DATA.  

  1. 特性
  2. 应用范围
  3. 说明
  4. 简化电路原理图
  5. 修订历史记录
  6. Pin Configuration and Functions
  7. Specifications
    1. 7.1 Absolute Maximum Ratings
    2. 7.2 Handling Ratings
    3. 7.3 Recommended Operating Conditions
    4. 7.4 Thermal Information
    5. 7.5 Electrical Characteristics
    6. 7.6 Typical Characteristics
  8. Detailed Description
    1. 8.1 Overview
    2. 8.2 Functional Block Diagram
    3. 8.3 Feature Description
      1. 8.3.1  Dynamic Rectifier Control
      2. 8.3.2  Dynamic Power Scaling
      3. 8.3.3  VO_REG Calculations
      4. 8.3.4  RILIM Calculations
      5. 8.3.5  Adapter Enable Functionality
      6. 8.3.6  Turning Off the Transmitter
        1. 8.3.6.1 End Power Transfer (EPT)
      7. 8.3.7  Communication Current Limit
      8. 8.3.8  PD_DET and TMEM
      9. 8.3.9  TS/CTRL
      10. 8.3.10 I2C Communication
      11. 8.3.11 Input Overvoltage
    4. 8.4 Device Functional Modes
    5. 8.5 Register Maps
  9. Applications and Implementation
    1. 9.1 Application Information
    2. 9.2 Typical Applications
      1. 9.2.1 WPC Power Supply 5-V Output With 1-A Maximum Current and I2C
        1. 9.2.1.1 Design Requirements
        2. 9.2.1.2 Detailed Design Procedure
          1. 9.2.1.2.1 Output Voltage Set Point
          2. 9.2.1.2.2 Output and Rectifier Capacitors
            1. 9.2.1.2.2.1 TMEM
          3. 9.2.1.2.3 Maximum Output Current Set Point
          4. 9.2.1.2.4 TERM Pin
          5. 9.2.1.2.5 I2C
          6. 9.2.1.2.6 Communication Current Limit
          7. 9.2.1.2.7 Receiver Coil
          8. 9.2.1.2.8 Series and Parallel Resonant Capacitors
          9. 9.2.1.2.9 Communication, Boot, and Clamp Capacitors
        3. 9.2.1.3 Application Performance Plots
      2. 9.2.2 bq5102x Standalone in System Board or Back Cover
  10. 10Power Supply Recommendations
  11. 11Layout
    1. 11.1 Layout Guidelines
    2. 11.2 Layout Example
  12. 12器件和文档支持
    1. 12.1 相关链接
    2. 12.2 Trademarks
    3. 12.3 Electrostatic Discharge Caution
    4. 12.4 Glossary
  13. 13机械封装和可订购信息

封装选项

机械数据 (封装 | 引脚)
散热焊盘机械数据 (封装 | 引脚)
订购信息

8 Detailed Description

8.1 Overview

WPC-based wireless power systems consist of a charging pad (primary, transmitter) and the secondary-side equipment (receiver). There are coils placed in the charging pad and secondary equipment, which magnetically couple to each other when the receiver is placed on the transmitter. Power is transferred from the primary to the secondary by transformer action between the coils. The receiver can achieve control over the amount of power transferred by requesting the transmitter to change the field strength by changing the frequency, or duty cycle, or voltage rail energizing the primary coil.

The receiver equipment communicates with the primary by modulating the load seen by the primary. This load modulation results in a change in the primary coil current or primary coil voltage, or both, which is measured and demodulated by the transmitter.

A WPC system communication is digital — packets are transferred from the secondary to the primary. Differential bi-phase encoding is used for the packets. The bit rate is 2 kb/s. Various types of communication packets are defined. These include identification and authentication packets, error packets, control packets, power usage packets, and end power transfer packets, among others.

desc_overview_SLUSBX1.gifFigure 7. Dual Mode Wireless Power System Indicating the Functional Integration of the bq5102x Family

The bq5102x device integrates fully-compliant WPC v1.1 communication protocol in order to streamline the wireless power receiver designs (no extra software development required). Other unique algorithms such as Dynamic Rectifier Control are integrated to provide best-in-class system efficiency while keeping the smallest solution size of the industry.

As a WPC system, when the receiver (shown in Figure 7) is placed on the charging pad, the secondary coil couples to the magnetic flux generated by the coil in the transmitter, which consequently induces a voltage in the secondary coil. The internal synchronous rectifier feeds this voltage to the RECT pin, which in turn feeds the LDO which feeds the output.

The bq5102x device identifies itself to the primary using the COMMx pins, switching on and off the COMM FETs, and hence switching in and out COMM capacitors. If the authentication is successful, the primary remains powered-up. The bq5102x device measures the voltage at the RECT pin, calculates the difference between the actual voltage and the desired voltage VRECT(REG), and sends back error packets to the transmitter. This process goes on until the input voltage settles at VRECT(REG) MAX. During a load change, the dynamic rectifier algorithm sets the targets specified by targets between VRECT(REG) MAX and VRECT(REG) MIN shown in Table 1. This algorithm enhances the transient response of the power supply while still allowing for very high efficiency at high loads.

After the voltage at the RECT pin is at the desired value, an internal pass FET (LDO) is enabled. The voltage control loop ensures that the output voltage is maintained at VOUT(REG), powering the downstream charger. The bq5102x device meanwhile continues to monitor the RECT voltage, and keeps sending control error packets (CEP) to the primary on average every 250 ms. If a large transient occurs, the feedback to the primary speeds up to 32-ms communication periods to converge on an operating point in less time.

8.2 Functional Block Diagram

fbd_SLUSBX1.gif

8.3 Feature Description

8.3.1 Dynamic Rectifier Control

The Dynamic Rectifier Control algorithm offers the end-system designer optimal transient response for a given maximum output current setting. This is achieved by providing enough voltage headroom across the internal regulator (LDO) at light loads in order to maintain regulation during a load transient. The WPC system has a relatively slow global feedback loop where it can take up to 150 ms to converge on a new rectifier voltage target. Therefore, a transient response is dependent on the loosely coupled transformer's output impedance profile. The Dynamic Rectifier Control allows for a 1.5-V change in rectified voltage before the transient response is observed at the output of the internal regulator (output of the bq5102x device). A 1-A application allows up to a 2-Ω output impedance. The Dynamic Rectifier Control behavior is illustrated in Figure 12.

8.3.2 Dynamic Power Scaling

The Dynamic Power Scaling feature allows for the loss characteristics of the bq5102x device to be scaled based on the maximum expected output power in the end application. This effectively optimizes the efficiency for each application. This feature is achieved by scaling the loss of the internal LDO based on a percentage of the maximum output current. Note that the maximum output current is set by the KILIM term and the RILIM resistance (where RILIM = KILIM / IILIM). The flow diagram in Figure 12 shows how the rectifier is dynamically controlled (Dynamic Rectifier Control) based on a fixed percentage of the IILIM setting. Table 1 summarizes how the rectifier behavior is dynamically adjusted based on two different RILIM settings. Table 1 shows IMAX, which is typically lower than IILIM (about 20% lower). See section RILIM Calculations about setting the ILIM resistor for more details.

Table 1. Dynamic Rectifier Regulation

Output Current Percentage RILIM = 1400 Ω
IMAX = 0.5 A		 RILIM = 700 Ω
IMAX = 1.0 A		 VRECT
0 to 10% 0 to 0.05 A 0 to 0.1 A VOUT + 2.0
10 to 20% 0.05 to 0.1 A 0.1 to 0.2 A VOUT + 1.68
20 to 40% 0.1 to 0.2 A 0.2 to 0.4 A VOUT + 0.56
> 40% > 0.2 A > 0.4 A VOUT + 0.12

Table 1 shows the shift in the Dynamic Rectifier Control behavior based on the two different RILIM settings. With the rectifier voltage (VRECT) as the input to the internal LDO, this adjustment in the Dynamic Rectifier Control thresholds dynamically adjusts the power dissipation across the LDO where,

Equation 1. eq_dynamic_pwr_scal_SLUSBS9.gif

Figure 21 shows how the system efficiency is improved due to the Dynamic Power Scaling feature. Note that this feature balances efficiency with optimal system transient response.

8.3.3 VO_REG Calculations

The bq5102x device allows the designer to set the output voltage by setting a feedback resistor divider network from the OUT pin to the VO_REG pin, as seen in Figure 8. The resistor divider network should be chosen so that the voltage at the VO_REG pin is 0.5 V at the desired output voltage. For the device bq51021 which has I2C enabled, this applies to the default I2C code for VO_REG shown in I2C register in Figure 8.

VO_REG_net_LUSBS9.gifFigure 8. VO_REG Network

Choose the desired output voltage VOUT and R6:

Equation 2. eq_Kvo_SLUSBS9.gif
Equation 3. eq_R6_voltage_SLUSBS9.gif

8.3.4 RILIM Calculations

The bq5102x device includes a means of providing hardware overcurrent protection (IILIM) through an analog current regulation loop. The hardware current limit provides an extra level of safety by clamping the maximum allowable output current (for example, current compliance). The RILIM resistor size also sets the thresholds for the dynamic rectifier levels providing efficiency tuning per each application’s maximum system current. The calculation for the total RILIM resistance is as follows:

Equation 4. RILIM = KILIM / IILIM
Equation 5. R1 = RILIM – RFOD

RILIM allows for the ILIM pin to reach 1.2 V at an output current equal to IILIM. When choosing RILIM, two options are possible.

If the user's application requires an output current equal to or greater than the external IILIM that the circuit is designed for (input current limit on the charger where the receiver device is tied higher than the external IILIM), ensure that the downstream charger is capable of regulating the voltage of the input into which the receiver device output is tied to by lowering the amount of current being drawn. This ensures that the receiver output does not drop to 0. Such behavior is referred to as VIN DPM in TI chargers. Unless such behavior is enabled on the charger, the charger will pull the output of the receiver device to ground when the receiver device enters current regulation. If the user's applications are designed to extract less than the IILIM (1-A maximum), typical designs should leave a design margin of at least 10%, so that the voltage at ILIM pin reaches 1.2 V when 10% more than maximum current is drawn from the output. Such a design would have input current limit on the charger lower than the external ILIM of the receiver device. In both cases, the charger must be capable of regulating the current drawn from the device to allow the output voltage to stay at a reasonable value. This same behavior is also necessary during the WPC communication. The following calculations show how such a design is achieved:

Equation 6. RILIM = KILIM / (1.1 × IILIM)
Equation 7. R1 = RILIM – RFOD

where

    When referring to the application diagram shown in Typical Applications, RILIM is the sum of the R1 and RFOD resistance (that is, the total resistance from the ILIM pin to GND). RFOD is chosen according to the application. The tool for calculating RFOD can be obtained by contacting your TI representative. Use RFOD to allow the receiver implementation to comply with WPC v1.1 requirements related to received power accuracy. For the device bq51021 which has I2C enabled, this applies to the default I2C code for IO_REG (100%) shown in I2C register in Figure 8.

    8.3.5 Adapter Enable Functionality

    The bq5102x device can also help manage the multiplexing of adapter power to the output and can turn off the TX when the adapter is plugged in and is above the VAD-EN. After the adapter is plugged in and the output turns off, the RX device sends an EOC to the TX. In this case, the AD_EN pins are then pulled to approximately 4 V below AD, which allows the device turn on the back-to-back PMOS connected between AD and OUT (Figure 28).

    Both the AD and AD-EN pins are rated at 30 V, while the OUT pin is rated at 20 V. It must also be noted that it is required to connect a back-to-back PMOS between AD and OUT so that voltage is blocked in both directions. Also, when AD mode is enabled, no load can be pulled from the RECT pin as this could cause an internal device overvoltage in the bq5102x device.

    For the device bq51021, the wired power will always take priority over wireless power, and thus when the adapter is plugged in, the device will first send an EPT to the TX and then will send allow for up to 30 ms after disabling the output allowing the WPG to go high impedance. It will then allow the wired power to be delivered to the output by pulling the AD_EN below the AD pin to allow the adapter power to be passed on the output.

    For the device bq51020, the EN1 and EN2 pins will determine the preference of wired or wireless power. Table 2 shows the EN1 and EN2 state and the corresponding device selection.

    Table 2. Adapter Functionality EN1 and EN2

    EN1 EN2 Adapter Insert AD_EN EPT Message Preference
    0 0 5 V VAD – 4 V EPT 0x00 Wired preference
    0 1 5 V VOUT / VAD No EPT Wireless preference
    1 0 5 V VAD – 4 V EPT 0x00 Wired preference(1)
    1 1 5 V VOUT / VAD EPT 0x00 Neither wired nor wireless(1)
    (1) Only valid when wireless power is present.

    8.3.6 Turning Off the Transmitter

    WPC v1.1 specification allows the receiver to turn off the transmitter and put the system in a low-power standby mode. There are two different ways to accomplish this with the bq5102x device. The first method is by using the TS/CTRL pin. By pulling the pin high or low, EPT can be sent to the transmitter.

    Pulling the TS/CTRL pin high will send EPT (code 0x01), which corresponds to charge complete. The transmitter will then respond to this EPT code as per the transmitter's design. After this EPT code is sent, some transmitters will then periodically check to make sure that the receiver is not looking for a refresh charge on the battery. The period of how often the transmitter checks varies based on the transmitter design. The transmitter will use the digital ping or a shortened version of it to check the receiver status. It is this energy on the digital ping that the receiver uses to indicate whether it is still sitting on the transmitter surface by storing the energy from the digital ping on the capacitor attached to the TMEM pin. The cap voltage (determined by the periodicity of the digital ping and the bleed off resistor attached in parallel to the TMEM cap) determine when the receiver indicates that it is no longer on the surface of the transmitter by allowing the PD_DET pin to go high impedance.

    The TS/CTRL pin can also be pulled low. This will allow the receiver to determine that the host processor would like to shut down the transmitter because of thermal reasons. Therefore, the receiver will send EPT (code 0x03) indicating an overtemperature event.

    8.3.6.1 End Power Transfer (EPT)

    The WPC allows for a special command to terminate power transfer from the TX termed EPT packet. The v1.1 specifies the following reasons and their responding data field value in Table 3.

    Table 3. End Power Transfer Codes in WPC

    Reason Value Condition(1)
    Unknown 0x00 AD > 3.6 V
    Charge complete 0x01 TS/CTRL > 1.4V
    Internal fault 0x02 TJ > 150°C or RILIM < 100 Ω
    Over temperature 0x03 TS < VHOT, or TS/CTRL < 100 mV
    Over voltage 0x04 VRECT target does not converge and stays higher or lower than target
    Battery failure 0x06 Not sent
    Reconfigure 0x07 Not sent
    No response 0x08 Not sent
    (1) The Condition column corresponds to the case where the bq5102x device will send the WPC EPT command.

    8.3.7 Communication Current Limit

    Communication current limit is a feature that allows for error free communication to happen between the RX and TX in the WPC mode. This is done by decoupling the coil from the load transients by limiting the output current during communication with the TX. The communication current limit is set according to the Table 4. The communication current limit can be disabled by pulling CM_ILIM pin high (> 1.4 V) or enabled by pulling the CM_ILIM pin low. There is an internal pulldown that enables communication current limit when the CM_ILIM pin is left floating.

    Table 4. Communication Current Limit

    IOUT Communication Current Limit
    0 mA < IOUT < 100 mA None
    100 mA < IOUT < 320 mA IOUT + 50 mA
    320 mA < IOUT < Max current IOUT – 50 mA

    When the communication current limit is enabled, the amount of current that the load can draw is limited. If the charger in the system does not have a VIN-DPM feature, the output of the receiver will collapse if communication current limit is enabled. To disable communication current limit, pull CM_ILIM pin high.

    8.3.8 PD_DETand TMEM

    PD_DET is an open-drain pin that goes low based on the voltage of the TMEM pin. When the voltage of TMEM is higher than 1.6 V, PD_DET will be low. The voltage on the TMEM pin depends on capturing the energy from the digital ping from the transmitter and storing it on the C5 capacitor in Figure 9. After the receiver sends an EPT (charge complete), the transmitter shuts down and goes into a low-power mode. After this EPT code is sent, some transmitters will then periodically check to make sure that the receiver is not looking for a refresh charge on the battery. The period of how often the transmitter checks varies based on the transmitter design. The transmitter will use the digital ping or a shortened version of it to check the receiver status. It is this energy on the digital ping that the receiver uses to indicate whether it is still sitting on the transmitter surface by storing the energy from the digital ping on the capacitor attached to the TMEM pin. The cap voltage (determined by the periodicity of the digital ping and the bleed off resistor attached in parallel to the TMEM cap) determine when the receiver indicates that it is no longer on the surface of the transmitter by allowing the PD_DET pin to go high impedance. The energy from the digital ping can be stored on the TMEM pin until the next digital ping refreshes the capacitor. A bleedoff resistor RMEMcan be chosen in parallel with C5 that sets the time constant so that the TMEM pin will fall below 1.6 V once the next ping timer expires. The duration between digital pings is indeterminate and depends on each transmitter manufacturer.

    desc_TMEM_config_SLUSBS9.gifFigure 9. TMEM Configuration

    Set capacitor on C5 = TMEM to 2.2 µF. Resistor RMEM across C5 can be set by understanding the duration between digital pings (tping). Set the resistor such that:

    Equation 8. eq_R_C5_SLUSBS9.gif

    PD_DET typically requires a pullup resistor to an external source. The choice of the pullup resistor determines load regulation; the suggested values for the pullup resistor are between 5.6 and 100 kΩ. The higher values offer better load regulation.

    8.3.9 TS/CTRL

    The bq5102x device includes a ratio metric external temperature sense function. The temperature sense function has a low ratio metric threshold which represents a hot condition. TI recommends an external temperature sensor in order to provide safe operating conditions for the receiver product. This pin is best used for monitoring the surface that can be exposed to the end user (for example, place the negative temperature coefficient (NTC) resistor closest to the user touch point on the back cover). A resistor in series or parallel can be inserted to adjust the NTC to match the trip point of the device. The implementation in Figure 10 shows the series-parallel resistor implementation for setting the threshold at which VTS-HOT is reached. Once the VTS-HOT threshold is reached, the device will send an EPT – overtemperature signal for a WPC transmitter.

    det_ntc_setup_SLUSBS9.gifFigure 10. NTC Resistor Setup

    Figure 10 shows a parallel resistor setup that can be used to adjust the trip point of VTS-HOT. TS-HOT is VS. After the NTC is chosen and RNTCHOT at VTS-HOT is determined from the data sheet of the NTC, Equation 9 can be used to calculate R1 and R3. In many cases depending on the NTC resistor, R1 or R3 can be omitted. To omit R1, set R1 to 0, and to omit R3, set R3 to 10 MΩ.

    Equation 9. eq_Ts-hot_SLUSBS9.gif

    8.3.10 I2C Communication

    Only bq51021

    The bq5102x device allows for I2C communication with the internal CPU. In case the I2C is not used, ground SCL and SDA. See Register Maps for more information.

    8.3.11 Input Overvoltage

    If the input voltage suddenly increases in potential for some condition (for example, a change in position of the equipment on the charging pad), the voltage-control loop inside the bq5102x device becomes active, and prevents the output from going beyond VOUT(REG). The receiver then starts sending back error packets every 30 ms until the input voltage comes back to an acceptable level, and then maintains the error communication every 250 ms.

    If the input voltage increases in potential beyond VRECT-OVP, the device switches off the LDO and informs the primary to bring the voltage back to VRECT(REG). In addition, a proprietary voltage protection circuit is activated by means of CCLAMP1 and CCLAMP2 that protects the device from voltages beyond the maximum rating of the device.

    8.4 Device Functional Modes

    At startup operation, the bq5102x device must comply with proper handshaking to be granted a power contract from the WPC transmitter. The transmitter initiates the handshake by providing an extended digital ping after analog ping detects an object on the transmitter surface. If a receiver is present on the transmitter surface, the receiver then provides the signal strength, configuration, and identification packets to the transmitter (see volume 1 of the WPC specification for details on each packet). These are the first three packets sent to the transmitter. The only exception is if there is a true shutdown condition on the AD, or TS/CTRL pins where the receiver shuts down the transmitter immediately. See Table 3 for details. After the transmitter has successfully received the signal strength, configuration, and identification packets, the receiver is granted a power contract and is then allowed to control the operating point of the power transfer. With the use of the bq5102x device Dynamic Rectifier Control algorithm, the receiver will inform the transmitter to adjust the rectifier voltage approximately 8V prior to enabling the output supply. This method enhances the transient performance during system startup. For the startup flow diagram details, see Figure 11.

    desc_wireless_pwr_SLUSBS9.gifFigure 11. Wireless Power Startup Flow Diagram on WPC TX

    After the startup procedure is established, the receiver will enter the active power transfer stage. This is considered the main loop of operation. The Dynamic Rectifier Control algorithm determines the rectifier voltage target based on a percentage of the maximum output current level setting (set by KILIM and the RILIM). The receiver will send control error packets in order to converge on these targets. As the output current changes, the rectifier voltage target dynamically changes. As a note, the feedback loop of the WPC system is relatively slow, it can take up to 150 ms to converge on a new rectifier voltage target. It should be understood that the instantaneous transient response of the system is open loop and dependent on the receiver coil output impedance at that operating point. The main loop also determines if any conditions in Table 3 are true in order to discontinue power transfer. Figure 12 shows the active power transfer loop.

    power_flowchart_SLUSBJ7.gifFigure 12. Active Power Transfer Flow Diagram on WPC

    8.5 Register Maps

    Locations 0x01 and 0x02 can be written to any time. Locations 0xE0 to 0xFF are only functional when VRECT > VUVLO. When VRECT goes below VUVLO, locations 0xE0 to 0xFF are reset.

    Table 5. Wireless Power Supply Current Register 1 (READ / WRITE)

    Memory Location: 0x01, Default State: 00000001
    BIT NAME READ / WRITE FUNCTION
    B7 (MSB) Read / Write Not used
    B6 Read / Write Not used
    B5 Read / Write Not used
    B4 Read / Write Not used
    B3 Read / Write Not used
    B2 VOREG2 Read / Write 450, 500, 550, 600, 650, 700, 750, or 800 mV
    Changes VO_REG target
    Default value 001
    B1 VOREG1 Read / Write
    B0 VOREG0 Read / Write

    Table 6. Wireless Power Supply Current Register 2 (READ / WRITE)

    Memory Location: 0x02, Default State: 00000111
    BIT NAME READ / WRITE FUNCTION
    B7 (MSB) JEITA Read / Write Not used
    B6 Read / Write Not used
    B5 ITERM2 Read / Write Not used for bq5102x
    B4 ITERM1 Read / Write
    B3 ITERM0 Read / Write
    B2 IOREG2 Read / Write 10%, 20%, 30%, 40%, 50%, 60%, 90%, and 100% of IILIM current based on configuration
    000, 001, …111
    B1 IOREG1 Read / Write
    B0 IOREG0 Read / Write

    Table 7. I2C Mailbox Register (READ / WRITE)

    Memory Location: 0xE0, Reset State: 10000000
    BIT NAME READ / WRITE FUNCTION
    B7 USER_PKT_DONE Read Set bit to 0 to send proprietary packet with header in 0xE2.
    CPU checks header to pick relevant payload from 0xF1 to 0xF4
    This bit will be set to 1 after the user packet with the header in register 0xE2 is sent.
    B6 USER_PKT_ERR Read 00 = No error in sending packet
    01 = Error: no transmitter present
    10 = Illegal header found (packet will not be sent)
    11 = Error: not defined yet
    B5
    B4 FOD Mailer Read / Write Not used
    B3 ALIGN Mailer Read / Write Setting this bit to 1 will enable alignment aid mode where the CEP = 0 will be sent until this bit is set to 0 (or CPU reset occurs) – see register 0xED
    B2 FOD Scaler Read / Write Not used
    B1 Reserved Read / Write
    B0 Reserved Read / Write

    Table 8. Wireless Power Supply FOD RAM (READ / WRITE)

    Memory Location: 0xE1, Reset State: 00000000(1)
    BIT NAME READ / WRITE FUNCTION
    B7 (MSB) ESR_ENABLE Read / Write Enables I2C based ESR in received power, Enable = 1, Disable = 0
    B6 OFF_ENABLE Read / Write Enables I2C based offset power, Enable = 1, Disable = 0
    B5 RoFOD5 Read / Write 000 – 0 mW
    001 – +39 mW
    010 – +78 mW
    011 – +117 mW
    100 – +156 mW    		 101 – +195 mW
    110 – +234 mW
    111 – +273 mW
    The value is added to received power message
    B4 RoFOD4 Read / Write
    B3 RoFOD3 Read / Write
    B2 RsFOD2 Read / Write 000 – ESR
    001 – ESR
    010 – ESR × 2
    011 – ESR × 3
    100 – ESR × 4    		 101 – Not used
    110 – Not used
    111 – ESR/2
    B1 RsFOD1 Read / Write
    B0 RsFOD0 Read / Write
    (1) A non-zero value will change the I2R calculation resistor and offset in the received power calculation by a factor shown in the table.

    Table 9. Wireless Power User Header RAM (WRITE)

    Memory Location: 0xE2, Reset State: 00000000(1)
    BIT READ / WRITE
    B7 (MSB) Read / Write
    B6 Read / Write
    B5 Read / Write
    B4 Read / Write
    B3 Read / Write
    B2 Read / Write
    B1 Read / Write
    B0 Read / Write
    (1) Must write a valid header to enable proprietary package. As soon as mailer (0xE0) is written, payload bytes are sent on the next available communication slot as determined by CPU. After payload is sent, the mailer (USER_PKT_DONE) is set to 1.

    Table 10. Wireless Power USER VRECT Status RAM (READ)(1)

    Memory Location: 0xE3, Reset State: 00000000
    Range – 0 to 12 V
    This register reads back the VRECT voltage with LSB = 46 mV
    BIT NAME READ / WRITE FUNCTION
    B7 (MSB) VRECT7 Read LSB = 46 mV
    B6 VRECT6 Read
    B5 VRECT5 Read
    B4 VRECT4 Read
    B3 VRECT3 Read
    B2 VRECT2 Read
    B1 VRECT1 Read
    B0 VRECT0 Read
    (1) VRECT is above UVLO.

    Table 11. Wireless Power VOUT Status RAM (READ)(1)

    Memory Location: 0xE4, Reset State: 00000000
    This register reads back the VOUT voltage with LSB = 46 mV
    BIT NAME Read / Write FUNCTION
    B7 (MSB) VOUT7 Read / Write LSB = 46 mV
    B6 VOUT6 Read / Write
    B5 VOUT5 Read / Write
    B4 VOUT4 Read / Write
    B3 VOUT3 Read / Write
    B2 VOUT2 Read / Write
    B1 VOUT1 Read / Write
    B0 VOUT0 Read / Write
    (1) Ouput is enabled.

    Table 12. Wireless Power REC PWR Most Significant Byte Status RAM (READ)

    Memory Location: 0xE8, Reset State: 00000000
    This register reads back the received power with LSB = 39 mW
    BIT Read / Write
    B7 (MSB) Read / Write
    B6 Read / Write
    B5 Read / Write
    B4 Read / Write
    B3 Read / Write
    B2 Read / Write
    B1 Read / Write
    B0 Read / Write

    Table 13. Wireless Power Prop Packet Payload RAM Byte 0 (WRITE)

    Memory Location: 0xF1, Reset State: 00000000
    BIT Read / Write
    B7 (MSB) Read / Write
    B6 Read / Write
    B5 Read / Write
    B4 Read / Write
    B3 Read / Write
    B2 Read / Write
    B1 Read / Write
    B0 Read / Write

    Table 14. Wireless Power Prop Packet Payload RAM Byte 1 (WRITE)

    Memory Location: 0xF2, Reset State: 00000000
    BIT Read / Write
    B7 (MSB) Read / Write
    B6 Read / Write
    B5 Read / Write
    B4 Read / Write
    B3 Read / Write
    B2 Read / Write
    B1 Read / Write
    B0 Read / Write

    Table 15. Wireless Power Prop Packet Payload RAM Byte 2 (WRITE)

    Memory Location: 0xF3, Reset State: 00000000
    BIT Read / Write
    B7 (MSB) Read / Write
    B6 Read / Write
    B5 Read / Write
    B4 Read / Write
    B3 Read / Write
    B2 Read / Write
    B1 Read / Write
    B0 Read / Write

    Table 16. Wireless Power Prop Packet Payload RAM Byte 3 (WRITE)

    Memory Location: 0xF4, Reset State: 00000000
    BIT Read / Write
    B7 (MSB) Read / Write
    B6 Read / Write
    B5 Read / Write
    B4 Read / Write
    B3 Read / Write
    B2 Read / Write
    B1 Read / Write
    B0 Read / Write