MAX20010DATPN/V+T

EVALUATION KIT AVAILABLE Click here for production status of specific part numbers. MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters General Description The MAX20010C/MAX20010D ICs are high-efficiency, synchronous step-down converters that operate with a 3.0V to 5.5V input voltage range and provide a 0.5V to 1.5875V output voltage range. The wide input/output voltage range and the ability to provide up to 6A load current make these ICs ideal for on-board point-of-load and post-regulation applications. The ICs achieve ±2% output error over load, line, and temperature ranges. The MAX20010D offers improved transient response. The ICs feature a 2.2MHz fixed-frequency PWM mode for better noise immunity and load-transient response, and a pulse-frequency modulation mode (skip) for increased efficiency during light-load operation. The 2.2MHz frequency operation allows the use of all-ceramic capacitors and minimizes the solution footprint. The programmable spread-spectrum frequency modulation minimizes radiated electromagnetic emissions. Integrated low RDS(ON) switches improve efficiency at heavy loads and make the layout a much simpler task with respect to discrete solutions. The ICs are offered with factory-preset output voltages (see the Ordering Information for options). The I2C interface supports dynamic voltage adjustment with programmable slew rates. Other features include programmable soft-start, overcurrent, and overtemperature protections. Benefits and Features ● Fully Integrated, Synchronous 6A DC-DC Converter Enables Small Solution Size • 3.0V to 5.5V Operating Supply Voltage ● High-Precision Voltage Regulator for Applications Processors • ±2% Output-Voltage Accuracy • Differential Remote Voltage Sensing • I2C-Controlled Output Voltage of 0.5V to 1.27V in 10mV Steps, or 0.625V to 1.5875V in 12.5mV Steps • Excellent Load-Transient Performance ● Low-Noise Feature Reduces EMI • 2.2MHz Operation • Spread-Spectrum Option • Frequency-Synchronization Input/Output • Current-Mode, Forced-PWM, and Skip Operation ● Robust for the Automotive Environment • PGOOD Output • Overtemperature and Short-Circuit Protection • 20-Pin (4mm x 4mm) TQFN with an Exposed Pad • -40°C to +125°C Operating Temperature Range • AECQ-100 Qualified Ordering Information appears at end of data sheet. Typical Application Circuit PV PV PV PGND AV RS+ MAX20010C MAX20010D GND SYNC EN ADDR 19-100153; Rev 5; 3/19 PGND RS- SCL SDA LX EP PG VOUT MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Absolute Maximum Ratings PV, AV to GND ........................................................-0.3V to +6V ADDR, EN, PG, RS+, RS-, SYNC to GND.....-0.3V to VAV + 0.3V SDA, SCL to GND....................................................-0.3V to +6V GND to PGND.......................................................-0.3V to +0.3V LX to PGND (Note 1).................................. -0.3V to VPV + 0.3V Output Short-Circuit Duration.....................................Continuous Continuous Power Dissipation (TA = +70°C) TQFN (derate 30.3mW/°C above +70°C)...............2424.2mW Operating Temperature Range.......................... -40°C to +125°C Junction Temperature.......................................................+150°C Storage Temperature Range............................. -65°C to +150°C Lead Temperature (soldering, 10s).................................. +300°C Soldering Temperature (reflow)........................................+260°C Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Package Thermal Characteristics (Note 2) TQFN Junction-to-Ambient Thermal Resistance (θJA)...........33°C/W Junction-to-Case Thermal Resistance (θJC).................2°C/W Note 1: Self-protected against transient voltages exceeding these limits for ≤ 50ns under normal operation and loads up to the maximum rating output current. Note 2: Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a four-layer board. For detailed information on package thermal considerations, refer to www.maximintegrated.com/thermal-tutorial. Package Information For the latest package outline information and land patterns (footprints), go to www.maximintegrated.com/packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. PACKAGE TYPE PACKAGE CODE OUTLINE NO. LAND PATTERN NO. 20 TQFN-EP T2044+4C 21-100172 90-0409 20 SW TQFN-EP T2044Y+4C 21-100068 90-0409 Electrical Characteristics (VPV = VAV = 5.0V. TA = TJ = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C under normal conditions, unless otherwise noted.) (Note 3) PARAMETER Supply Voltage Range Undervoltage Lockout SYMBOL VIN UVLO CONDITIONS Fully operational 3.0 2.85 Falling 2.55 TA = +25°C IIN EN = low Supply Current IIN EN = high, IOUT = 0mA, skip mode PWM Switching Frequency fSW CONFIG.SS = 1 Voltage Accuracy ILOAD = 0A to 6A, 3.0V ≤ VPV ≤ 5.5V 2.5 TA = +125°C Internally generated Spread Spectrum www.maximintegrated.com TYP Rising Shutdown Supply Current VOUT MIN MAX UNITS 5.5 V 3 5 4.5 300 2.0 2.2 V µA µA 2.4 +3 MHz % 0.80V to 1.5875V -2 +2 % 0.50V to 0.79V -16 +21 mV Maxim Integrated │  2 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Electrical Characteristics (continued) (VPV = VAV = 5.0V. TA = TJ = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C under normal conditions, unless otherwise noted.) (Note 3) PARAMETER SYMBOL CONDITIONS pMOS On-Resistance VPV = VAV = 5V, ILX = 1A nMOS On-Resistance VPV = VAV = 5V, ILX = 1A pMOS Current-Limit Threshold MIN 7.76 nMOS Zero Crossing Threshold TYP MAX UNITS 31 55 mΩ 18 31 mΩ 9.70 11.64 A 60 LX Leakage Current VPV = VAV = 6V, LX = PGND or PV Duty-Cycle Range PWM mode TA = +25°C 0.5 TA = +125°C 4 Minimum On-Time 36 mA 5 µA 100 % 75 ns THERMAL OVERLOAD Thermal-Shutdown Temperature TJ rising Hysteresis 165 °C 15 °C POWER-GOOD OUTPUT (PG) Percentage of nominal output, output voltage rising, blanked during slewing PG Overvoltage (OV) Threshold, Rising Percentage of nominal output, output voltage falling, blanked during slewing PG Undervoltage (UV) Threshold, Falling 0.5V < VOUT < 0.79V 104 0.8V < VOUT < 1.5875V 105 108 111 0.5V < VOUT < 0.79V 88 92 96 0.8V < VOUT < 1.5875V 108 % % 89 Active Timeout Period UV/OV Propagation Delay 92 95 256 Clocks 5 µs PG Output High-Leakage Current 3.0V ≤ VPV ≤ 5.5V, 3.0V ≤ VAV ≤ 5.5V, sinking -2mA PG Output Low Level 112 1 µA 0.2 V 0.5 V DIGITAL INPUTS (SYNC, EN, ADDR) Input High Level VIH Input Low Level VIL 1.5 Input Hysteresis V 0.1 V EN Input Leakage Current 0V ≤ VPV ≤ 5.5V, 0V ≤ VAV ≤ 5.5V 0.1 mA Enable Time Rising EN to beginning of soft-start 140 µs SYNC Input Pulldown SYNC Input Frequency Range www.maximintegrated.com 100 1.8 150 kΩ 2.6 MHz Maxim Integrated │  3 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Electrical Characteristics (continued) (VPV = VAV = 5.0V. TA = TJ = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C under normal conditions, unless otherwise noted.) (Note 3) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS 0.4 V SYNC OUTPUT Output Low VOL ISINK = 3mA Output High VOH VPV = VAV = 5.0V, ISOURCE = 3mA 4.2 V 1.3 V DIGITAL INPUTS (SDA, SCL) Input High Level VIH_I2C Input Low Level VIL_I2C 0.5 Input Hysteresis 0V ≤ VPV ≤ 5.5V, 0V ≤ VAV ≤ 5.5V Input Leakage Current V 0.1 V 0.1 µA I2C INTERFACE Clock Frequency fSCL 3.4 MHz Setup Time (Repeated) START tSU:STA (Note 4) 160 ns Hold Time (Repeated) START tHD:STA (Note 4) 160 ns SCL Low Time tLOW (Note 4) 160 ns SCL High Time tHIGH (Note 4) 60 ns Data Setup Time tSU:DAT (Note 4) 50 Data Hold Time tHD:DAT (Note 4) 0 Setup Time for STOP Condition tSU:STO (Note 4) 160 Spike Suppression SDA Output Low (Note 4) VOL_SDA ns 70 ns ns 20 ISINK = 13mA ns 0.4 V Note 3: All units are 100% production tested at TA = +25°C. All temperature limits are guaranteed by design. Note 4: Guaranteed by design. Not production tested. www.maximintegrated.com Maxim Integrated │  4 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Typical Operating Characteristics (TA = +25°C, unless otherwise noted.) EFFICIENCY vs. LOAD CURRENT (VOUT = 0.95V) 90 80 PWM VIN = 3V VIN = 4V VIN = 5V 50 40 30 0.4 0 -0.2 -0.4 -0.6 10 -0.8 0.01 0.1 1 -1 10 0 1 2 300 280 260 240 220 2.35 fSW (MHz) 2.30 4 4.5 5 -1 3 3.5 4 INPUT VOLTAGE (V) 4.5 5 LOAD-TRANSIENT RESPONSE (PWM) toc06 50mV/div (ACCOUPLED) 30 4.2A 29 -40 -25 -10 5 fSW vs. TEMPERATURE fSW vs. LOAD CURRENT toc07 2.30 2.26 3A LOAD STARTUP BEHAVIOR 2.24 100V/div VOUT 2.22 2.20 2A/div IOUT 2.16 2.10 5V/div 2.14 2.05 toc09 5V/div VEN 2.18 2.15 20μs/div toc08 VIN = 5V CONFIG BIT3=1 2.28 2.20 0A 20 35 50 65 80 95 110 125 TEMPERATURE (°C) VIN = 5V CONFIG BIT3=1 NO LOAD ILOAD CONFIG BIT3 = 1 VIN = 5V ILOAD = 0A VOUT = 0.95V INPUT VOLTAGE (V) 2.25 2.00 6 VOUT = 0.95V No Load TA = -40°C -0.8 31 27 5.5 fSW (MHz) 2.40 -0.4 SUPPLY CURRENT vs. TEMPERATURE (PWM) toc05 28 3.5 0 -0.2 VOUT 320 3 5 TA = +125°C 32 INPUT CURRENT (mA) INPUT CURRENT (μA) 33 CONFIG BIT3 = 0 ILOAD = 0A VOUT = 0.95V 340 200 4 TA = +25°C 0.2 LOAD CURRENT (A) SUPPLY CURRENT vs. INPUT VOLTAGE (SKIP) toc04 360 3 0.4 -0.6 VIN = 5V VOUT = 0.95V TA = -40°C LOAD CURRENT (A) 400 toc03 0.6 TA = +125°C TA = +25°C 0.2 20 VOUT LINE REGULATION (PWM) 1 0.8 0.6 60 380 toc02 0.8 70 0 0.001 VOUT LOAD REGULATION (PWM) 1 REGULATION (%) EFFICIENCY (%) toc01 SKIP VIN = 3V VIN = 4V VIN = 5V REGULATION (%) 100 VPG 2.12 -40 -25 -10 5 20 35 50 65 80 95 110 125 TEMPERATURE (°C) www.maximintegrated.com 2.10 0 1 2 3 4 5 6 100μs/div LOAD CURRENT (A) Maxim Integrated │  5 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Typical Operating Characteristics (continued) (TA = +25°C, unless otherwise noted.) SYNC FUNCTION SHORT CIRCUIT (PWM MODE) toc10 VLX 2V/div VSYNC 2V/div toc11 500mV/div VOUT ILX 5A/div VPG 200ns/div PWM WAVEFORM (NO LOAD) ILX SKIP WAVEFORM (50mA LOAD) toc12 toc13 10mV/div (ACCOUPLED) VOUT ILX 1A/div VLX 2V/div 2A/div 5V/div VLX 400ns/div www.maximintegrated.com 2ms/div 10mV/div (ACCOUPLED) VOUT 500mV/div 400ns/div Maxim Integrated │  6 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters SYNC EN PG RS+ TOP VIEW GND Pin Configuration 15 14 13 12 11 AV 16 ADDR 17 MAX20010C MAX20010D PV 18 PV 19 3 4 RS- 9 SCL 8 SDA 7 PGND 6 PGND 5 PGND 2 LX LX 1 LX + LX PV 20 10 TQFN (4mm x 4mm) Pin Description PIN NAME FUNCTION 1–4 LX 5–7 PGND Inductor Connection. Connect LX to the switched side of the inductor. Connect all LX pins together. 8 SDA I2C Data I/O 9 SCL I2C Clock Input 10 RS- Buck Regulator Remote Voltage-Sense Negative Input 11 RS+ Buck Regulator Remote Voltage-Sense Positive Input 12 PG Open-Drain Power-Good Output. This output remains low for 120μs after the output has reached its regulation level (see the Electrical Characteristics table). To obtain a logic signal, pull up PG with an external resistor. 13 EN Active-High Enable Input. When EN is high, the device enters soft-start. When EN is low, the device enters soft-shutdown. Power Ground. Connect all PGND pins together. 14 SYNC SYNC I/O. When configured as an input, connect SYNC to GND or leave unconnected to enable skipmode operation under light loads. Connect SYNC to AV or an external clock to enable fixed-frequency, forced-PWM (FPWM) mode operation. When configured as an output, connect SYNC to other devices’ SYNC inputs. 15 GND Analog Ground 16 AV 17 ADDR 18–20 PV Power Input Supply. Connect a 4.7µF or larger ceramic capacitor from PV to PGND. Connect all PV pins together. — EP Exposed Pad. Connect EP to ground. Connecting the exposed pad to ground does not remove the requirement for proper ground connections to PGND. The exposed pad is attached with epoxy to the substrate of the die, making it an excellent path to remove heat from the IC. www.maximintegrated.com Analog Input Supply. Filter AV using a 100Ω resistor from PV and a 1µF ceramic capacitor from AV to GND. I2C Address Select. See the Ordering Information table for default I2C settings. Maxim Integrated │  7 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Detailed Description Integrated low RDS(ON) switches help improve efficiency at heavy loads and make the layout a much simpler task with respect to discrete solutions. The ICs are offered with a factory-preset output voltage that is dynamically adjustable through the I2C interface. The output voltage can be set to any desired value between 0.5V and 1.27V in 10mV steps, and between 0.625V and 1.5875V in 12.5mV steps. Optional spread-spectrum frequency modulation minimizes radiated electromagnetic emissions due to the switching frequency. The I2C-programmable I/O (SYNC) enables system synchronization. Additional features include adjustable soft-start, powergood delay, DVS rate, overcurrent, and overtemperature protections (see Figure 1). The MAX20010C/MAX20010D ICs are high-efficiency, synchronous step-down converters that operate with a 3.0V to 5.5V input voltage range and provide a 0.5V to 1.5875V output voltage range. The ICs deliver up to 6A of load current and achieve ±2% output error over load, line, and temperature ranges. The MAX20010D offers improved transient performance. MAX20010C MAX20010D CURRENT-SENSE AMP PV SKIP CURRENT COMP CLK PV PEAK CURRENT COMP RAMP GENERATOR ∑ PWM COMP COMP LX PGND CONTROL LOGIC PV PGND VID[6:0] VREF FPWM EAMP 7-BIT DAC CURRENT-LIMIT COMP CLK PGND PGOOD COMP RS+ POK VREF RSVSTEP VPVA SYNC SS OSC CLK FPWM ADDR VOLTAGE REFERENCE GND VREF AGND PG EN SCL AV CLK180 P-OK SDA UVLO I2C AND CONTROL LOGIC VID[6:0] Figure 1. Internal Block Diagram www.maximintegrated.com Maxim Integrated │  8 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters I2C Interface The ICs feature an I2C, 2-wire serial interface consisting of a serial-data line (SDA) and serial-clock line (SCL). SDA and SCL facilitate communication between the ICs and the master at clock rates up to 3.4MHz. The master, typically a microcontroller, generates SCL and initiates data transfer on the bus. Figure 2 shows the 2-wire interface timing diagram. A master device communicates with the ICs by transmitting the proper address followed by the data word. Each transmit sequence is framed by a START (S) or Repeated START (Sr) condition and a STOP (P) condition. Each word transmitted over the bus is 8 bits long and is always followed by an acknowledge clock pulse. The SDA line operates as both an input and an open-drain output. A pullup resistor greater than 500Ω is required on the SDA bus. The SCL line operates as an input only. A pullup resistor greater than 500Ω is required on SCL if there are multiple masters on the bus, or if the master in a single-master system has an open-drain SCL output. Series resistors in line with SDA and SCL are optional. The SCL and SDA inputs suppress noise spikes to assure proper device operation even on a noisy bus. Bit Transfer One data bit is transferred during each SCL cycle. The data on SDA must remain stable during the high period of the SCL pulse. Changes in SDA while SCL is high are control signals (see the START and STOP Conditions section). SDA and SCL idle high when the I2C bus is not busy. START and STOP Conditions A master device initiates communication by issuing a START condition. A START condition is a high-to-low transition on SDA with SCL high. A STOP condition is a low-to-high transition on SDA while SCL is high (Figure 3). A START (S) condition from the master signals the beginning of a transmission to the IC. The master terminates transmission, and frees the bus, by issuing a STOP (P) condition. The bus remains active if a Repeated START (Sr) condition is generated instead of a STOP condition. SDA tBUF tSU, DAT tSU,STA tLOW tSP tHD,DAT tHD,DAT tSU,STO SCL tHIGH tHD,STA tF tR START CONDITION REPEATED START CONDITION STOP CONDITION START CONDITION Figure 2. I2C Timing Diagram S Sr P SCL SDA Figure 3. START, STOP, and Repeated START Conditions www.maximintegrated.com Maxim Integrated │  9 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Early STOP Condition Slave Address The ICs recognize a STOP condition at any point during data transmission, except if the STOP condition occurs in the same high pulse as a START condition. Clock Stretching In general, the clock-signal generation for the I2C bus is the responsibility of the master device. The I2C specification allows slow slave devices to alter the clock signal by holding down the clock line. The process in which a slave device holds down the clock line is typically called clock stretching. The ICs do not use any form of clock stretching to hold down the clock line. I2C General Call Address The ICs do not implement the I2C specification’s “general call address.” If the IC sees the general call address (0b0000_0000), it does not issue an acknowledge. Once the device is enabled, the I2C slave address is set by the ADDR pin. The address is defined as the 7 most significant bits (MSBs) followed by the R/W bit. Set the R/W bit to 1 to configure the IC to read mode. Set the R/W bit to 0 to configure the device to write mode. The address is the first byte of information sent to the device after the START condition. See Table 1 for I2C slave addresses. Acknowledge The acknowledge bit (ACK) is a clocked 9th bit that the ICs use to handshake receipt each byte of data (Figure 4). The device pulls down SDA during the master-generated 9th clock pulse. The SDA line must remain stable and low during the high period of the acknowledge clock pulse. Monitoring ACK allows for detection of unsuccessful data transfers. An unsuccessful data transfer occurs if a receiving device is busy or if a system fault has occurred. In the CLOCK PULSE FOR ACKNOWLEDGMENT START CONDITION SCL 1 2 8 9 NOT ACKNOWLEDGE SDA ACKNOWLEDGE Figure 4. Acknowledge Condition Table 1. I2C Slave Addresses ADDR PIN A6 A5 A4 A3 A2* A1* A0 WRITE READ 0 0 1 1 1 0 0 0 0x70 0x71 1 0 1 1 1 0 0 1 0x72 0x73 0 0 1 1 1 0 1 0 0x74 0x75 1 0 1 1 1 0 1 1 0x76 0x77 0 0 1 1 1 1 0 0 0x78 0x79 1 0 1 1 1 1 0 1 0x7A 0x7B 0 0 1 1 1 1 1 0 0x7C 0x7D 1 0 1 1 1 1 1 1 0x7E 0x7F *See the Ordering Information for default settings. www.maximintegrated.com Maxim Integrated │  10 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters event of an unsuccessful data transfer, the bus master can reattempt communication. Write Data Format A write to the device includes: ● Transmission of a START condition ● Slave address with the write bit set to 0 ● 1 byte of data to the register address ● 1 byte of data to the command register ● STOP condition. . (Figure 5 illustrates the proper format for one frame) Read Data Format A read from the device includes: ● Transmission of a START condition 1) Master sends a START command (S). 2) Master sends the 7-bit slave address followed by a write bit (R/W = 0). 3) Addressed slave asserts an acknowledge (A) by pulling SDA low. 4) Master sends an 8-bit register pointer. 5) Slave acknowledges the register pointer. 6) Master sends a data byte. 7) Slave updates with the new data. 8) Slave acknowledges or not acknowledges the data byte. The next rising edge on SDA loads the data byte into its target register and the data becomes active. 9) Master sends a STOP condition (P) or a Repeated START condition (Sr). Writing Multiple Bytes Using Register-Data Pairs ● Slave address with the write bit set to 0 Figure 7 shows the protocol for the I2C master device to write multiple bytes to the ICs using register-data pairs. This protocol allows the I2C master device to address the slave only once and then send data to multiple registers in a random order. Registers can be written continuously until the master issues a STOP condition. ● 1 byte of data to the register address ● Restart condition ● Slave address with the read bit set to 1 ● 1 byte of data to the command register ● STOP condition The “multiple byte register-data pair” protocol is as follows: (Figure 5 illustrates the proper format for one frame) Writing to a Single Register Figure 6 shows the protocol for the I2C master device to write 1 byte of data to the ICs. This protocol is the same as the SMBus specification’s “write byte” protocol. The “write byte” protocol is as follows: 1) Master sends a START command. 2) Master sends the 7-bit slave address followed by a write bit. 3) Addressed slave asserts an acknowledge by pulling SDA low. 4) Master sends an 8-bit register pointer. WRITE BYTE S SLAVE WRITE ADDRESS A REGISTER ADDRESS A DATA A REGISTER ADDRESS A DATA 1 A REGISTER ADDRESS A Sr SLAVE READ ADDRESS A DATA REGISTER ADDRESS A Sr SLAVE READ ADDRESS A DATA 1 NA P WRITE MULTIPLE BYTES S SLAVE WRITE ADDRESS REGISTER ADDRESS A A DATA 2 ... REGISTER ADDRESS A DATA 2 A P READ BYTE S SLAVE WRITE ADDRESS NA P READ SEQUENTIAL BYTES S SLAVE WRITE ADDRESS A ... DATA N NA P Figure 5. Data Format of I2C Interface www.maximintegrated.com Maxim Integrated │  11 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters LEGEND SLAVE TO MASTER MASTER TO SLAVE 1 7 1 1 8 1 8 1 1 S SLAVE ADDRESS 0 A REGISTER POINTER A DATA A OR nA P OR Sr R/W NUMBER OF BITS THE DATA IS LOADED INTO THE TARGET REGISTER SDA B1 B2 A SCL 7 8 9 Figure 6. Write Byte Format 5) Save acknowledges the register pointer. 6) Master sends a data byte. 7) Slave acknowledges the data byte. The next rising edge on SDA loads the data byte into its target register and the data becomes active. 8) Steps 4–7 are repeated as many times as the master requires. 9) Master sends a STOP condition. During the rising edge of the stop-related SDA edge, the data byte that was previously written is loaded into the target register and becomes active. PG Output Shutdown During shutdown, the output voltage is ramped down at the 5.5mV/µs slew rate. Once the controlled ramp is stopped, the output voltage is typically around 0.15V at no load. Spread-Spectrum Option The ICs, featuring spread-spectrum (SS) operation, vary the internal operating frequency down by 3% relative to the internally generated operating frequency of 2.2MHz (typ). This function does not apply to externally applied oscillation frequency. Synchronization (SYNC) The ICs feature an open-drain PGOOD output that asserts low when the output voltage exceeds the PG_OV and PG_ UV thresholds. PG remains low for a fixed timeout period after the output is within the regulation window. Connect PG to a logic supply using a pullup resistor. SYNC is factory-programmable I/O (see Ordering Information for the available options). When SYNC is configured as an input, a logic-high on the FPWM bit enables SYNC to accept signal frequencies in the range of 1.8MHz < fSYNC < 2.6MHz. When SYNC is configured as an output, it outputs the internal PWM switching frequency. Soft-Start Current-Limit/Short-Circuit Protection The ICs include a programmable startup fixed soft-start rate. Soft-start time limits startup inrush current by forcing the output voltage to ramp up towards its regulation point. www.maximintegrated.com The current-limit feature protects the ICs against shortcircuit and overload conditions at the output. After soft-start is completed, if VOUT is less than 50% of the set value and the IC is in current limit, the IC shuts off for 4ms (at 2.2MHz switching frequency) and repeats soft-start. This cycle repeats until the short or overload condition is removed. See the short-circuit (PWM) waveform for an example. Maxim Integrated │  12 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters LEGEND SLAVE TO MASTER MASTER TO SLAVE 1 S 7 SLAVE ADDRESS 1 1 8 1 8 1 0 A REGISTER POINTER X A DATA X A NUMBER OF BITS ••• a R/W 8 1 8 1 REGISTER POINTER n A DATA n A NUMBER OF BITS ••• a 8 1 8 1 1 REGISTER POINTER Z A DATA Z A P NUMBER OF BITS ß THE DATA IS LOADED INTO THE TARGET REGISTER SDA B1 SCL 7 B0 8 A B7 9 1 DETAIL : a THE DATA IS LOADED INTO THE TARGET REGISTER SDA B1 B0 SCL 7 8 A 9 DETAIL : ß Figure 7. Write Register (Data-Pair Format) www.maximintegrated.com Maxim Integrated │  13 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Table 2. Register Map REGISTER R/W ADDRESS POWERON RESET REG BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 ID DEV3 DEV2 DEV1 DEV0 R3 R2 R1 R0 0x00 R 0x00 — — — — — — — — — 0x01 R/W 0x00 VIDMAX — VMAX6 VMAX5 VMAX4 VMAX3 VMAX2 VMAX1 VMAX0 0x02 R/W OTP Reserved* Reserved* — — — — — 0x03 R/W 0x02 TRKERR UV OV OC VMERR 0 0x04 R 0x00 VSTEP — VRHOT — FPWM SS SO1 SO0 0x05 R/W OTP — — — — SR3 SR2 SR1 SR0 0x06 R/W OTP VID — VID6 VID5 VID4 VID3 VID2 VID1 VID0 0x07 R/W OTP Reserved* — — 0x2B R/W 0x00 STATUS INTERR CONFIG SLEW — Reserved* Reserved* Reserved* Reserved* Reserved* Reserved* Reserved* Reserved* *Note: Reserved registers and bits are not used for readback; they are reserved for internal use. Table 3. Identification Registers (ID) ID BIT NO. BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 NAME DEV3 DEV2 DEV1 DEV0 R3 R2 R1 R0 POR 0 0 0 0 0 0 0 0 BIT DEV[7:4] R[3:0] BIT DESCRIPTION Device ID: MAX20010C/MAX20010D = 0x0 0x3 www.maximintegrated.com Maxim Integrated │  14 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Table 4. Maximum Voltage-Setting Registers (VIDMAX) VIDMAX BIT NO. 7 6 5 4 3 2 1 0 NAME — VMAX6 VMAX5 VMAX4 VMAX3 VMAX2 VMAX1 VMAX0 POR OTP OTP OTP OTP OTP OTP OTP OTP BIT VMAX[6:0] BIT DESCRIPTION Maximum Voltage Setting: If VID[] > VMAX[], a fault is set and the actual voltage will be capped by VMAX[]. See Table 9 for voltage selections. Table 5. Configuration Registers (CONFIG) CONFIG BIT NO. BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 NAME VSTEP — — — FPWM SS SO1 SO0 POR OTP OTP OTP OTP OTP OTP OTP OTP BIT BIT DESCRIPTION VSTEP Voltage Step Size—Sets the voltage step size for the LSB of SETVOUT: 0 = 10mV 1 = 12.5mV FPWM Forced-PWM Mode: 0 = Mode controlled by SYNC pin. When SYNC is output device is always FPWM mode. 1 = Forced-PWM Mode. Overrides SYNC skip mode setting when SYNC is an input. SS SO[1:0] Spread-Spectrum Clock Setting: 0 = Disabled 1 = +3% spread SYNC I/O Select: 00 = Master: Input, rising edge starts cycle 01 = Master: Input, falling edge starts cycle 10 = Master: Output, falling edge starts cycle 11 = Unused www.maximintegrated.com Maxim Integrated │  15 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Table 6. Status Registers (STATUS) BIT NO. NAME POR BIT INTERR Reserved VRHOT UV OV OC VMERR BIT 7 INTERR 0 BIT 6 Reserved* 0 BIT 5 VRHOT 0 STATUS BIT 4 UV 0 BIT 3 OV 0 BIT 2 OC 0 BIT 1 VMERR 0 BIT 0 0 0 BIT DESCRIPTION Internal Hardware Error: This bit is set to 1 when ATE trimming and testing is not complete. Reserved registers and bits are not used for readback; they are reserved for internal use. Thermal-Shutdown Indication: This bit indicates if thermal shutdown has occurred since the last time the STATUS register was read. VOUT Undervoltage: This bit indicates if the output is currently under the target voltage. VOUT Overvoltage: This bit indicates if the output is currently over the target voltage. VOUT Overcurrent: This bit indicates if an overcurrent event has occurred since the last time the STATUS register was read. VOUT MAX Error: Set to 1 if VID[] > VOUTMAX[] is in normal mode. Table 7. Slew-Rate Registers (SLEW) BIT NO. NAME POR BIT 7 — OTP BIT 6 — OTP BIT 5 — OTP SLEW BIT 4 — OTP BIT 3 SR3 OTP BIT 2 SR2 OTP BIT 1 SR1 OTP BIT 0 SR0 OTP SR[3:0] SOFT-START SLEW RATE (mV/μs)* DVS SLEW RATE (mV/μs)* XXXX0000 XXXX0001 XXXX0010 XXXX0011 XXXX0100 XXXX0101 XXXX0110 XXXX0111 XXXX1000 XXXX1001 XXXX1010―XXXX1111 22 11 5.5 11 5.5 44 22 11 5.5 5.5 Reserved 22 22 22 11 11 44 44 44 44 5.5 Reserved *Note: VSTEP = ‘0’; when VSTEP = ‘1’, increase by a factor of 1.25. Table 8. Output-Voltage Registers, VID BIT NO. NAME POR BIT 7 — OTP BIT VID[6:0] BIT 6 VID6 OTP BIT 5 VID5 OTP VID BIT 4 VID4 OTP BIT 3 VID3 OTP BIT 2 VID2 OTP BIT 1 VID1 OTP BIT 0 VID0 OTP BIT DESCRIPTION Target Voltage Setting: VOUT ramps at the programmed DVS ramp until it reaches VSET. See Table 9 for voltage selections. www.maximintegrated.com Maxim Integrated │  16 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Table 9. VID Output-Voltage Selections VID[6:0] VOUT (V) (VSTEP = 0) VOUT (V) (VSTEP = 1) VID[6:0] VOUT (V) (VSTEP = 0) VOUT (V) (VSTEP = 1) VID[6:0] VOUT (V) (VSTEP = 0) VOUT (V) (VSTEP = 1) 0x00 OFF OFF 0x20 0.810 1.0125 0x40 1.130 1.4125 0x01 0.500 0.6250 0x21 0.820 1.0250 0x41 1.140 1.4250 0x02 0.510 0.6375 0x22 0.830 1.0375 0x42 1.150 1.4375 0x03 0.520 0.6500 0x23 0.840 1.0500 0x43 1.160 1.4500 0x04 0.530 0.6625 0x24 0.850 1.0625 0x44 1.170 1.4625 0x05 0.540 0.6750 0x25 0.860 1.0750 0x45 1.180 1.4750 0x06 0.550 0.6875 0x26 0.870 1.0875 0x46 1.190 1.4875 0x07 0.560 0.7000 0x27 0.880 1.1000 0x47 1.200 1.5000 0x08 0.570 0.7125 0x28 0.890 1.1125 0x48 1.210 1.5125 0x09 0.580 0.7250 0x29 0.900 1.1250 0x49 1.220 1.5250 0x0A 0.590 0.7375 0x2A 0.910 1.1375 0x4A 1.230 1.5375 0x0B 0.600 0.7500 0x2B 0.920 1.1500 0x4B 1.240 1.5500 0x0C 0.610 0.7625 0x2C 0.930 1.1625 0x4C 1.250 1.5625 0x0D 0.620 0.7750 0x2D 0.940 1.1750 0x4D 1.260 1.5750 0x0E 0.630 0.7875 0x2E 0.950 1.1875 0x4E 1.270 1.5875 0x0F 0.640 0.8000 0x2F 0.960 1.2000 0x10 0.650 0.8125 0x30 0.970 1.2125 0x11 0.660 0.8250 0x31 0.980 1.2250 0x12 0.670 0.8375 0x32 0.990 1.2375 0x13 0.680 0.8500 0x33 1.000 1.2500 0x14 0.690 0.8625 0x34 1.010 1.2625 0x15 0.700 0.8750 0x35 1.020 1.2750 0x16 0.710 0.8875 0x36 1.030 1.2875 0x17 0.720 0.9000 0x37 1.040 1.3000 0x18 0.730 0.9125 0x38 1.050 1.3125 0x19 0.740 0.9250 0x39 1.060 1.3250 0x1A 0.750 0.9375 0x3A 1.070 1.3375 0x1B 0.760 0.9500 0x3B 1.080 1.3500 0x1C 0.770 0.9625 0x3C 1.090 1.3625 0x1D 0.780 0.9750 0x3D 1.100 1.3750 0x1E 0.790 0.9875 0x3E 1.110 1.3875 0x1F 0.800 1.0000 0x3F 1.120 1.4000 www.maximintegrated.com Maxim Integrated │  17 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters PWM/Skip Modes The ICs feature a SYNC input that puts the converter either in skip mode or forced-PWM mode of operation. See the Pin Description table for mode details. In PWM mode, the converter switches at a constant frequency with variable on-time. In skip mode, the converter’s switching frequency is load-dependent until the output load reaches a certain threshold. At higher load current, the switching frequency does not change and the operating mode is similar to the PWM mode. Skip mode helps improve efficiency in light-load applications by transferring more energy to the output during each on cycle, so the converter does not switch MOSFETs on and off as often as is the case in PWM mode. Consequently, the gate charge and switching losses are much lower in skip mode. Choose an input capacitor that exhibits less than +10°C self-heating temperature rise at the RMS input current for optimal long-term reliability: ESR IN = ∆VESR ∆I I OUT + L 2 where: (VPV _ - VOUT ) × VOUT ∆IL = VPV _ × f SW × L and: I × D(1- D) C IN = OUT ∆VQ × f SW Overtemperature Protection Thermal-overload protection limits the total power dissipation in the ICs. When the junction temperature exceeds 165°C (typ), an internal thermal sensor shuts down the internal bias regulator and the step-down controller, allowing the ICs to cool. The thermal sensor turns on the ICs again after the junction temperature cools by 15°C. and: Applications Information The ICs are optimized to use a nominal 0.22µH inductor value. 0.15µH to 0.33µH inductors can also be used. Input Capacitor The input filter capacitor reduces peak currents drawn from the power source and reduces noise and voltage ripple on the input caused by the circuit’s switching. The input capacitor RMS current requirement (IRMS) is defined by the following equation: IRMS = ILOAD(MAX) VOUT (VPV _ - VOUT ) VPV _ IRMS has a maximum value when the input voltage equals twice the output voltage (VPV_ = 2VOUT), so IRMS(MAX) = ILOAD(MAX)/2. www.maximintegrated.com D= VOUT VPV _ IOUT is the maximum output current, D is the duty cycle. Inductor Selection Inductors are rated for maximum saturation current. The maximum inductor current equals the maximum load current in addition to half the peak-to-peak ripple current: = IPEAK ILOAD(MAX) + ∆IINDUCTOR 2 The actual peak-to-peak inductor ripple current is calculated in the previous ΔIL equation. The saturation current should be > IPEAK, or at least in a range where the inductance does not degrade significantly. Output Capacitor The MAX20010C is stable with 2x47μF (typ) or more of X7R ceramic capacitance on the output, while the MAX20010D is stable with 3x47μF (typ). Phase and gain margin must be measured with the worst-case-derated output capacitance to ensure stability. Larger capacitance values can be used to minimize VSAG and VSOAR during load transients. Maxim Integrated │  18 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Setting the Output Voltage Externally An external resistive divider can be used to set the output voltage, or to change the voltage range that can be programmed through I2C. This should only be done with VSTEP = 0 (10mV steps). To set the output voltage, connect a resistive divider from the output (OUT) to RS+ to GND, as shown in Figure 8. Select RFB2 (RS+ to GND resistor) ≤ 100kΩ. Calculate RFBA (OUT to RS+ resistor) with the following equation: VOUT RFB1 CFB1 RS+ V  = R FB1 R FB2 ( OUT ) − 1  VRS+  RFB2 where VRS+ = programmed VID voltage. Capacitor CFB1 can help improve the phase margin when using a resistive divider. Determine CFB1 from the following equation: Figure 8. Adjustable Output-Voltage Setting R C FB1 = 10 FB2 pF R FB1 Ordering Information PART PINPACKAGE V OUT (V) VMAX[6:0] CONFIG VID[6:0] SLEW I2C ADDR = 0 MAX20010CATPD/V+ 20 TQFN-EP* 0.82 0x3C (1.09V) 0x0E 0x21 (0.82V) 0x09 0x70 MAX20010CATPE/V+ 20 TQFN-EP* 0.80 0x29 (0.90V) 0x08 0x1F (0.80V) 0x09 0x74 MAX20010CATPJ/V+ 20 TQFN-EP* 1.20 0x4C (1.25V) 0x08 0x47 (1.20V) 0x03 0x70 MAX20010CATPL/V+ 20 TQFN-EP* 1.00 0x42 (1.15V) 0x06 0x33 (1.00V) 0x03 0x70 MAX20010CATPM/V+ 20 TQFN-EP* 1.00 0x3D (1.10V) 0x08 0x33 (1.00V) 0x03 0x70 MAX20010CATPQ/V+ 20 TQFN-EP* 0.60 0x1F (0.80V) 0x08 0x0B (0.60V) 0x03 0x70 MAX20010CATPU/V+ 20 TQFN-EP* 1.03 0x3B (1.08V) 0x0C 0x36 (1.03V) 0x00 0x70 MAX20010DATPN/V+ 20 TQFN-EP* 1.00 0x42 (1.15V) 0x08 0x33 (1.00V) 0x03 0x70 MAX20010DATPO/V+ 20 TQFN-EP* 0.91 0x42 (1.15V) 0x08 0x2A (0.91V) 0x03 0x70 20 SW TQFN-EP* 0.91 0x42 (1.15V) 0x08 0x2A (0.91V) 0x03 0x70 MAX20010DATPO/VY+ MAX20010DATPP/V+ 20 TQFN-EP* 0.87 0x42 (1.15V) 0x08 0x26 (0.87V) 0x03 0x70 MAX20010DATPR/V+ 20 TQFN-EP* 0.90 0x42 (1.15V) 0x08 0x29 (0.90V) 0x00 0x70 MAX20010DATPT/V+ 20 TQFN-EP* 0.75 0x42 (1.15V) 0x08 0x1A (0.75V) 0x03 0x70 /V denotes an automotive qualified part. +Denotes a lead(Pb)-free/RoHS-compliant package. *EP = Exposed pad. www.maximintegrated.com Maxim Integrated │  19 MAX20010C/MAX20010D Automotive Single 6A Step-Down Converters Revision History REVISION NUMBER REVISION DATE PAGES CHANGED 0 9/17 Initial release 1 3/18 Updated Table 7, Output Capacitor section, and Ordering Information 16, 18–19 2 4/18 Updated Package Information table and Table 7. Added MAX20010DATPR/V+ as a future product to the Ordering Information table. 2, 16, 19 3 8/18 Updated equation in the Setting the Output Voltage Externally section. Added MAX20010CATPE/V+** as a future product and removed future product designation from MAX20010DATPR/V+ in the Ordering Information table. 19 4 11/18 Updated Package Information table. Added MAX20010DATPT/V+ and MAX20010DATPO/VY+ to the Ordering Information table. Added MAX20010CATPU/V+as a future product to the Ordering Information table. 2, 19 5 3/19 Removed future-product notation from MAX20010CATPE/V+ and MAX20010CATPU/V+ in the Ordering Information table 19 DESCRIPTION — For pricing, delivery, and ordering information, please visit Maxim Integrated’s online storefront at https://www.maximintegrated.com/en/storefront/storefront.html. Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance. Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc. © 2018 Maxim Integrated Products, Inc. │  20