BQ25504RGTR

Product Folder Order Now Support & Community Tools & Software Technical Documents BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 BQ25504 Ultra Low-Power Boost Converter With Battery Management For Energy Harvester Applications 1 Features 3 Description • The BQ25504 device is the first of a new family of intelligent integrated energy harvesting nano-power management solutions that are well suited for meeting the special needs of ultra low power applications. The device is specifically designed to efficiently acquire and manage the microwatts (µW) to miliwatts (mW) of power generated from a variety of DC sources like photovoltaic (solar) or thermal electric generators. The BQ25504 is the first device of its kind to implement a highly efficient boost converter/charger targeted toward products and systems, such as wireless sensor networks (WSNs) which have stringent power and operational demands. The design of the BQ25504 starts with a DC-DC boost converter/charger that requires only microwatts of power to begin operating. 1 • • • • Ultra low-power with high-efficiency DC-DC boost converter/charger – Continuous energy harvesting from low-input sources: VIN ≥ 130 mV (Typical) – Ultra-low quiescent current: IQ < 330 nA (Typical) – Cold-start voltage: VIN ≥ 600 mV (typical) Programmable dynamic maximum power point tracking (MPPT) – Integrated dynamic maximum power point tracking for optimal energy extraction from a variety of energy generation sources – Input voltage regulation prevents collapsing input source Energy storage – Energy can be stored to rechargeable li-ion batteries, thin-film batteries, super-capacitors, or conventional capacitors Battery charging and protection – User Programmable undervoltage and overvoltage levels – On-chip temperature sensor with programmable overtemperature shutoff Battery status output – Battery good output pin – Programmable threshold and hysteresis – Warn attached microcontrollers of pending loss of power – Can be used to enable or disable system loads 2 Applications • • • • • • • • • • Energy harvesting Solar chargers Thermal electric generator (TEG) harvesting Wireless sensor networks (WSNs) Industrial monitoring Environmental monitoring Bridge and structural health monitoring (SHM) Smart building controls Portable and wearable health devices Entertainment system remote controls Once started, the boost converter/charger can effectively extract power from low-voltage output harvesters such as thermoelectric generators (TEGs) or single- or dual-cell solar panels. The boost converter can be started with VIN as low as 600 mV, and once started, can continue to harvest energy down to VIN = 130 mV. Device Information(1) PART NUMBER BQ25504 PACKAGE BODY SIZE (NOM) VQFN (16) 3.00 mm x 3.00 mm (1) For all available packages, see the orderable addendum at the end of the datasheet. Solar Application Circuit LBST CFLTR CSTOR Battery CHVR Solar Cell SYSTEM LOAD VSTOR + - 16 15 LBST VSTOR ` 14 13 VBAT VSS 1 VSS 2 VIN_DC 3 VOC_SAMP OK_PROG 10 VREF_SAMP OK_HYST 9 AVSS 12 VBAT_OK 11 bq25504 ROC 2 ROC 1 VBAT_OK CREF ROK1 ROK2 4 OT_PROG VBAT_OV VRDIV VBAT_UV 5 6 7 ROK3 8 ROV2 RUV 2 ROV1 RUV 1 1 An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications, intellectual property matters and other important disclaimers. PRODUCTION DATA. BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com Table of Contents 1 2 3 4 5 6 7 8 Features .................................................................. Applications ........................................................... Description ............................................................. Revision History..................................................... Description (continued)......................................... Pin Configuration and Functions ......................... Specifications......................................................... 1 1 1 2 4 5 6 7.1 7.2 7.3 7.4 7.5 7.6 6 6 6 7 7 9 Absolute Maximum Ratings ..................................... ESD Ratings.............................................................. Recommended Operating Conditions....................... Thermal Information .................................................. Electrical Characteristics........................................... Typical Characteristics .............................................. Detailed Description ............................................ 11 8.1 8.2 8.3 8.4 Overview ................................................................. Functional Block Diagram ....................................... Feature Description................................................. Device Functional Modes........................................ 11 12 12 15 9 Application and Implementation ........................ 18 9.1 Application Information............................................ 18 9.2 Typical Applications ................................................ 20 10 Power Supply Recommendations ..................... 27 11 Layout................................................................... 27 11.1 Layout Guidelines ................................................. 27 11.2 Layout Example .................................................... 28 11.3 Thermal Considerations ........................................ 28 12 Device and Documentation Support ................. 29 12.1 12.2 12.3 12.4 12.5 12.6 12.7 Device Support...................................................... Documentation Support ........................................ Receiving Notification of Documentation Updates Support Resources ............................................... Trademarks ........................................................... Electrostatic Discharge Caution ............................ Glossary ................................................................ 29 29 29 29 29 29 29 13 Mechanical, Packaging, and Orderable Information ........................................................... 29 4 Revision History Changes from Revision E (March 2019) to Revision F • Page Deleted Not Recommended for New Designs ....................................................................................................................... 1 Changes from Revision D (December 2018) to Revision E Page • Changed Feature From: VIN ≥ 80 mV (Typical) To: VIN ≥ 130 mV (Typical) .......................................................................... 1 • Changed From: VIN as low as 330 mV To: VIN as low as 600 mV in the Description ............................................................ 1 • Changed From: "harvest energy down to VIN = 80 mV." To: "harvest energy down to VIN = 130 mV." in the Description.... 1 • Changed From: "330 mV typical,.." To: "600 mV typical,.." in the second paragraph of the Overview section ................... 11 • Changed Figure 11 .............................................................................................................................................................. 14 • Changed From: "VIN(CS) = 330 mV typical." To: "VIN(CS) = 600 mV typical." in the second paragraph of the ColdStart Operation section......................................................................................................................................................... 16 Changes from Revision C (June 2015) to Revision D Page • Changed Feature From: Cold-Start Voltage: VIN ≥ 330 mV (Typical) To: Cold-Start Voltage: VIN ≥ 600 mV (Typical) ........ 1 • Changed the RGT Package appearance .............................................................................................................................. 5 • Moved Tstg to the Absolute Maximum Ratings table............................................................................................................... 6 • Changed Handling Ratings To: ESD Ratings......................................................................................................................... 6 • Increased VIN(CS) From: TYP = 330 mV and MAX = 450 mV To: TYP = 600 mV and MAX = 700 mV in Electrical Characteristics table ............................................................................................................................................................... 7 Changes from Revision B (December 2014) to Revision C Page • Changed the Test Condition for PIN(CS) in the Electrical Characteristics ............................................................................... 7 • Changed the values for PIN(CS) in the Electrical Characteristics From: TYP = 10, MAX = 50 To: TYP = 15, MAX deleted ................................................................................................................................................................................... 7 • Changed CFLTR To: CBYP Figure 14 ..................................................................................................................................... 20 2 Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 • Changed CBYP = 0.1 µF To: CBYP = 0.01 µF in Detailed Design Procedure .................................................................... 20 • Changed CFLTR To: CBYP in Figure 21 .................................................................................................................................. 23 • Changed CBYP = 0.1 µF To: CBYP = 0.01 µF in Detailed Design Procedure .................................................................... 23 • Changed CFLTR To: CBYP in Figure 28 ................................................................................................................................. 25 • Changed CBYP = 0.1 µF To: CBYP = 0.01 µF in Detailed Design Procedure .................................................................... 25 • Changed Figure 34 .............................................................................................................................................................. 28 Changes from Revision A (September 2012) to Revision B • Page Added Handling Rating table, Feature Description section, Device Functional Modes, Application and Implementation section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and Mechanical, Packaging, and Orderable Information section................................................................ 1 Changes from Original (October 2011) to Revision A Page • Added the INTENDED OPERATION section ....................................................................................................................... 11 • Changed the Cold -Start Operation section ......................................................................................................................... 15 • Changed the Boost Converter, Charger Operation section.................................................................................................. 16 • Changed the Storage Element section................................................................................................................................. 16 • Changed the CAPACITOR SELECTION section ................................................................................................................. 19 • Added CFLTR and Notes 1 and 2 to Figure 14 ..................................................................................................................... 20 • Added CFLTR and Notes 1 and 2 to Figure 21 ..................................................................................................................... 23 • Added CFLTR and Notes 1 and 2 to Figure 28 ..................................................................................................................... 25 Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 3 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com 5 Description (continued) The BQ25504 also implements a programmable maximum power point tracking sampling network to optimize the transfer of power into the device. Sampling the VIN_DC open-circuit voltage is programmed using external resistors, and held with an external capacitor (CREF). For example solar cells that operate at maximum power point (MPP) of 80% of their open-circuit voltage, the resistor divider can be set to 80% of the VIN_DC voltage and the network will control the VIN_DC to operate near that sampled reference voltage. Alternatively, an external reference voltage can be provide by a MCU to produce a more complex MPPT algorithm. The BQ25504 was designed with the flexibility to support a variety of energy storage elements. The availability of the sources from which harvesters extract their energy can often be sporadic or time-varying. Systems will typically need some type of energy storage element, such as a rechargeable battery, super capacitor, or conventional capacitor. The storage element ensures that constant power is available when needed for the systems. The storage element also allows the system to handle any peak currents that cannot directly come from the input source. To prevent damage to a customer’s storage element, both maximum and minimum voltages are monitored against the user programmed undervoltage (UV) and overvoltage (OV) levels. To further assist users in the strict management of their energy budgets, the BQ25504 toggles the battery good flag to signal an attached microprocessor when the voltage on an energy storage battery or capacitor has dropped below a preset critical level. This warning should trigger the shedding of load currents to prevent the system from entering an undervoltage condition. The OV, UV, and battery good thresholds are programmed independently. All the capabilities of BQ25504 are packed into a small-footprint, 16-lead, 3-mm x 3-mm VQFN package. 4 Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 6 Pin Configuration and Functions VSS 1 VIN_DC 2 LBST VSTOR VBAT VSS 16 15 14 13 RGT Package 16 Pins Top View 12 AVSS 11 VBAT_OK 10 OK_PROG 9 OK_HYST Thermal 6 7 8 VRDIV VBAT_UV 4 VBAT_OV VREF_SAMP Pad 5 3 OT_PROG VOC_SAMP Not to scale Pin Functions PIN I/O DESCRIPTION NAME NO. AVSS 12 Supply LBST 16 Input Inductor connection for the boost charger switching node. Connect a 22 µH inductor between this pin and pin 2 (VIN_DC). OK_HYST 9 Input Connect to the mid-point of external resistor divider between VRDIV and GND for setting the VBAT_OK hysteresis threshold. If not used, connect this pin to GND. OK_PROG 10 Input Connect to the mid-point of external resistor divider between VRDIV and GND for setting the VBAT_OK threshold. If not used, connect this pin to GND. OT_PROG 5 Input Digital Programming input for IC overtemperature threshold. Connect to GND for 60 C threshold or VSTOR for 120 C threshold. VBAT 14 I/O VBAT_OK 11 Output Digital output for battery good indicator. Internally referenced to the VSTOR voltage. Leave floating if not used. VBAT_OV 6 Input Connect to the mid-point of external resistor divider between VRDIV and GND for setting the VSTOR = VBAT overvoltage threshold. VBAT_UV 8 Input Connect to the mid-point of external resistor divider between VRDIV and GND for setting the VBAT undervoltage threshold. The PFET between VBAT and VSTOR opens if the voltage on VSTOR is below this threshold. VIN_DC 2 Input DC voltage input from energy harvesters. Connect at least a 4.7 µF capacitor as close as possible between this pin and pin 1. VOC_SAMP 3 Input Sampling pin for MPPT network. Connect to the mid-point of external resistor divider between VIN_DC and GND for setting the MPP threshold voltage which will be stored on the VREF_SAMP pin. To disable the MPPT sampling circuit, connect to VSTOR. VRDIV 7 Output VREF_SAMP 4 Input Connect a 0.01 µF low leakage capacitor from this pin to GND to store the voltage to which VIN_DC will be regulated. This voltage is provided by the MPPT sample circuit. When MPPT is disabled, either use an external voltage source to provide this voltage or tie this pin to GND to disable input voltage regulation (i.e. operate from a low impedance power supply). Signal ground connection for the device Connect a rechargeable storage element with at least 100 uF of equivalent capacitance to this pin. Resistor divider biasing voltage. VSS 1 Input General ground connection for the device VSS 13 Supply General ground connection for the device VSTOR 15 Output Connection for the output of the boost charger, which is typically connected to the system load. Connect at least a 4.7 µF capacitor in parallel with a 0.1 µF capacitor as close as possible to between this pin and pin 1 (VSS). Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 5 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com 7 Specifications 7.1 Absolute Maximum Ratings (1) over operating free-air temperature range (unless otherwise noted) Input voltage Peak Input Power, PIN_PK VIN_DC, VOC_SAMP, VREF_SAMP, VBAT_OV, VBAT_UV, VRDIV, OK_HYST, OK_PROG, VBAT_OK, VBAT, VSTOR, LBST (2) MIN MAX UNIT –0.3 5.5 V 400 mW Operating junction temperature range, TJ –40 125 °C Storage temperature range, Tstg –65 150 °C (1) (2) 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 under Recommended Operating Conditions is not implied. Exposure to absolute–maximum–rated conditions for extended periods may affect device reliability. All voltage values are with respect to VSS/ground terminal. 7.2 ESD Ratings MIN V(ESD) (1) (2) Electrostatic discharge MAX Human body model (HBM), per ANSI/ESDA/JEDEC JS-001, all pins (1) UNIT 2 Charged device model (CDM), per JEDEC specification JESD22-C101, all pins (2) kV 500 V JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process. 7.3 Recommended Operating Conditions MIN VIN (DC) DC input voltage into VIN_DC (1) VBAT Battery voltage range (2) CHVR Input capacitance 4.23 CSTOR Storage capacitance 4.23 CBAT Battery pin capacitance or equivalent battery capacity 100 CREF Sampled reference storage capacitance ROC1 + ROC2 Total resistance for setting for MPPT reference. ROK1 + ROK2 + ROK3 NOM MAX UNIT 0.13 3 V 2.5 5.25 V 4.7 5.17 µF 4.7 5.17 µF µF 9 10 11 nF 18 20 22 MΩ Total resistance for setting reference voltage. 9 10 11 MΩ RUV1 + RUV2 Total resistance for setting reference voltage. 9 10 11 MΩ ROV1 + ROV2 Total resistance for setting reference voltage. 9 10 11 MΩ LBST Input inductance 19.8 22 24.2 µH TA Operating free air ambient temperature –40 85 °C TJ Operating junction temperature –40 105 °C (1) (2) 6 Maximum input power ≤ 300 mW. Cold start has been completed VBAT_OV setting must be higher than VIN_DC Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 7.4 Thermal Information BQ25504 THERMAL METRIC (1) QFN UNIT 16 PINS RθJA Junction-to-ambient thermal resistance 48.5 RθJC(top) Junction-to-case (top) thermal resistance 63.9 RθJB Junction-to-board thermal resistance 22 ψJT Junction-to-top characterization parameter 1.8 ψJB Junction-to-board characterization parameter 22 RθJC(bot) Junction-to-case (bottom) thermal resistance 6.5 (1) °C/W For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report, . 7.5 Electrical Characteristics Over recommended temperature range, typical values are at TA = 25°C. Unless otherwise noted, specifications apply for conditions of VIN_DC = 1.2V, VBAT = VSTOR = 3V. External components LBST = 22 µH, CHVR = 4.7 µF CSTOR= 4.7 µF. PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 3000 mV BOOST CONVERTER \ CHARGER STAGE VIN(DC) DC input voltage into VIN_DC Cold-start completed IIN(DC) Peak Current flowing from VIN into VIN_DC input 0.5V < VIN < 3 V; VSTOR = 4.2 V PIN Input power range for normal charging VBAT > VIN_DC; VIN_DC = 0.5 V VIN(CS) Cold-start Voltage. Input voltage that will start charging of VSTOR VBAT < VBAT_UV; VSTOR = 0 V; 0°C < TA < 85°C PIN(CS) Minimum cold-start input power to start normal charging VBAT < VSTOR(CHGEN) VIN_DC clamped to VIN_CS by cold start circuit VBAT = 100 µF ceramic VSTOR_CHGEN Voltage on VSTOR when cold start operation ends and normal charger operation begins RBAT(on) Resistance of switch between VBAT and VSTOR when turned on. 130 200 0.01 600 300 mA 300 mW 700 mV 15 1.6 1.77 µW 1.95 V VBAT = 4.2 V; VSTOR load = 50 mA 2 Ω VBAT = 2.1 V 2 VBAT = 4.2 V 2 VBAT = 2.1 V 5 VBAT = 4.2 V 5 Charger Low Side switch ON resistance Ω RDS(on) Charger rectifier High Side switch ON resistance fSW_BST Ω Boost converter mode switching frequency 1 MHz 5 nA 80 nA BATTERY MANAGEMENT VBAT = 2.1 V; VBAT_UV = 2.3 V, TJ = 25°C VSTOR = 0 V IVBAT Leakage on VBAT pin 1 VBAT = 2.1 V; VBAT_UV = 2.3 V, –40°C < TJ < 65°C, VSTOR = 0 V VSTOR Quiescent current Charger Shutdown in UV Condition VIN_DC = 0V; VBAT < VBAT_UV = 2.4V; VSTOR = 2.2V, No load on VBAT 330 750 nA VSTOR Quiescent current Charger Shutdown in OV Condition VIN_DC = 0V, VBAT > VBAT_OV, VSTOR = 4.25, No load on VBAT 570 1400 nA VBAT_OV Programmable voltage range for overvoltage threshold (Battery voltage is rising) VSTOR increasing 2.5 5.25 V VBAT_OV_HYST Battery voltage overvoltage hysteresis threshold (Battery voltage is falling), internal threshold VSTOR decreasing 18 VBAT_UV Programmable voltage range for under voltage threshold (Battery voltage is falling) VSTOR decreasing; VBAT_UV > VBias 2.2 VBAT_UV_HYST Battery under voltage threshold hysteresis, internal thershold VSTOR increasing 40 VBAT_OK Programmable voltage range for threshold voltage for high to low transition of digital signal indicating battery is OK, VSTOR decreasing VBAT_OK_HYST Programmable voltage range for threshold voltage for low to high transition of digital signal indicating battery is OK, VSTOR increasing VBAT_ACCURACY Overall Accuracy for threshold values, UV, OV, VBAT_OK Selected resistors are 0.1% tolerance VBAT_OKH VBAT OK (High) threshold voltage Load = 10 µA IVSTOR 35 89 VBAT_OV 80 125 Product Folder Links: BQ25504 V mV VBAT_UV VBAT_OV V 50 VBAT_OVVBAT_UV mV –5% 5% VSTOR200mV Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated mV V 7 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com Electrical Characteristics (continued) Over recommended temperature range, typical values are at TA = 25°C. Unless otherwise noted, specifications apply for conditions of VIN_DC = 1.2V, VBAT = VSTOR = 3V. External components LBST = 22 µH, CHVR = 4.7 µF CSTOR= 4.7 µF. PARAMETER TEST CONDITIONS MIN TYP VBAT_OKL VBAT OK (Low) threshold voltage Load = 10 µA TSD_PROTL The temperature at which the boost converter is disabled and the switch between VBAT and VSTOR is disconnected to protect the battery OT_Prog = LO 65 OT_Prog = HI 120 TSD_PROTH MAX UNIT 100 mV °C Voltage for OT_PROG High setting 2 V OT_Prog Voltage for OT_PROG Low setting 0.3 V BIAS and MPPT CONTROL STAGE VOC_sample Sampling period of VIN_DC open circuit voltage 16 s VOC_Settling Sampling period of VIN_DC open circuit voltage 256 ms VIN_Reg Regulation of VIN_DC during charging VIN_shutoff DC input voltage into VIN_DC when charger is turned off 40 MPPT_Disable Threshold on VOC_SAMP to disable MPPT functionality VSTOR-15 mV VBIAS Voltage node which is used as reference for the programmable voltage thresholds 8 0.5 V 130 mV) Charger resumes charging VSTOR_CHGEN = 1.8 V typical GND Signal to turn off system load on VSTOR VBAT disconnected from VSTOR to prevent overdischarge Cold Start Circuit on (if VIN_DC > 600 mV) P(harvester) x Kbq255xx < P(load) P(harvester) x Kbq255xx > P(load) Increasing VSTOR voltage Decreasing VSTOR voltage Figure 11. Summary of VSTOR Threshold Voltages 8.3.5 Nano-Power Management and Efficiency The high efficiency of the BQ25504 charger is achieved via the proprietary Nano-Power management circuitry and algorithm. This feature essentially samples and holds the VSTOR voltage in order to reduce the average quiescent current. That is, the internal circuitry is only active for a short period of time and then off for the remaining period of time at the lowest feasible duty cycle. A portion of this feature can be observed in Figure 19 where the VRDIV node is monitored. Here the VRDIV node provides a connection to the VSTOR voltage (first pulse) and then generates the reference levels for the VBAT_OV and VBAT_OK resistor dividers for a short period of time. The divided down values at each pin arecompared against VBIAS as part of the hysteretic control. Since this biases a resistor string, the current through these resistors is only active when the Nano-Power management circuitry makes the connection—hence reducing the overall quiescent current due to the resistors. This process repeats every 64 ms. The BQ25504 boost charger efficiency is shown for various input power levels in Figure 1 through Figure 7. All data points were captured by averaging the overall input current. This must be done due to the periodic biasing scheme implemented via the Nano-Power management circuitry. In order to properly measure the resulting input current when calculating the output to input efficiency, the input current efficiency data was gathered using a source meter set to average over at least 50 samples. Quiescent current curves into VSTOR over temperature and voltage is shown at Figure 8. 14 Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 8.4 Device Functional Modes The BQ25504 has three functional modes: cold-start operation, main boost charger enabled and thermal shutdown. The cold start circuitry is powered from VIN_DC. The main boost charger circuitry is powered from VSTOR while the boost power stage is powered from VIN_DC. Details of entering and exiting each mode are explained below. 8.4.1 Cold-Start Operation (VSTOR < VSTOR_CHGEN, VIN_DC > VIN(CS) and PIN > PIN(CS)) Whenever VSTOR < VSTOR_CHGEN, VIN_DC ≥ VIN(CS) and PIN > PIN(CS), the cold-start circuit is on. This could happen when there is not input power at VIN_DC to prevent the load from discharging the battery or during a large load transient on VSTOR. During cold start, the voltage at VIN_DC is clamped to VIN(CS) so the energy harvester's output current is critical to providing sufficient cold start input power, PIN(CS) = VIN(CS) X IIN(CS). The cold-start circuit is essentially an unregulated, hysteretic boost converter with lower efficiency compared to the main boost charger. None of the other features function during cold start operation. The cold start circuit's goal is to charge VSTOR higher than VSTOR_CHGEN so that the main boost charger can operate. When a depleted storage element is initially attached to VBAT, as shown in Figure 12 and the harvester can provide a voltage > VIN(CS) and total power at least > PIN(CS), assuming minimal system load or leakage at VSTOR and VBAT, the cold start circuit can charge VSTOR above VSTOR_CHGEN. Once the VSTOR voltage reaches the VSTOR_CHGEN threshold, the IC 1. first performs an initialization pulse on VRDIV to reset the feedback voltages, 2. then disables the charger for 32 ms (typical) to allow the VIN_DC voltage to rise to the harvester's opencircuit voltage which will be used as the input voltage regulation reference voltage until the next MPPT sampling cycle and 3. lastly performs its first feedback sampling using VRDIV, approximately 64 ms after the initialization pulse. Figure 12. Charger Operation After a Depleted Storage Element is Attached and Harvester is Available The energy harvester must supply sufficient power for the IC to exit cold start. Due to the body diode of the PFET connecting VSTOR and VBAT, the cold start circuit must charge both the capacitor on CSTOR up to the VSTOR_CHGEN and the storage element connected to VBAT up to VSTOR_CHGEN less a diode drop. When a rechargeable battery with an open protector is attached, the intial charge time is typically short due to the minimum charge needed to close the battery's protector FETs. When large, discharged super capacitors with high DC leakage currents are attached, the intial charge time can be signficant. Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 15 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com Device Functional Modes (continued) When the VSTOR voltage reaches VSTOR_CHGEN, the main boost charger starts up. When the VSTOR voltage rises to the VBAT_UV threshold, the PMOS switch between VSTOR and VBAT turns on, which provides additional loading on VSTOR and could result in the VSTOR voltage dropping below both the VBAT_UV threshold and the VSTOR_CHGEN voltage, especially if system loads on VSTOR or VBAT are active during this time. Therefore, it is not uncommon for the VSTOR voltage waveform to have incremental pulses (i.e. stair steps) as the IC cycles between cold-start and main boost charger operation before eventually maintaing VSTOR above VSTOR_CHGEN. The cold start circuit initially clamps VIN_DC to VIN(CS) = 600 mV typical. If sufficient input power (i.e.,output current from the harvester clamped to VIN(CS)) is not available, it is possible that the cold start circuit cannot raise the VSTOR voltage above VSTOR_CHGEN in order for the main boost conveter to start up. It is highly recommended to add an external PFET between the system load and VSTOR. An inverted VBAT_OK signal can be used to drive the gate of this system-isolating, external PFET. See the Power Supply Recommendations section for guidance on minimum input power requirements. 8.4.2 Main Boost Charger Enabled (VSTOR > VSTOR_CHGEN, VIN_DC > VIN(DC) and EN = LOW ) One way to avoid cold start is to attach a partially charged storage element as shown in Figure 13. Figure 13. Charger Operation after a Partially Charged Storage Element is Attached and Harvester Power is Available When no input source is attached, the VSTOR node should be discharged to ground before attaching a storage element. Hot-plugging a storage element that is charged (e.g., the battery protector PFET is closed) and with the VSTOR node more than 100 mV above ground results in the PFET between VSTOR and VBAT remaining off until an input source is attached. Assuming the voltages on VSTOR and VBAT are both below 100mV, when a charged storage element is attached (i.e. hot-plugged) to VBAT, the IC. 1. first turns on the internal PFET between the VSTOR and VBAT pins for tBAT_HOT_PLUG (45ms) in order to charge VSTOR to VSTOR_CHGEN then turns off the PFET to prevent the battery from overdischarge, 2. then performs an initialization pulse on VRDIV to reset the feedback voltages, 3. then disables the charger for 32 ms (typical) to allow the VIN_DC voltage to rise to the harvester's opencircuit voltage which will be used as the input voltage regulation reference voltage until the next MPPT sampling cycle and 4. lastly performs its first feedback sampling using VRDIV, approximately 64 ms after the initialization pulse. 16 Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 Device Functional Modes (continued) If the VSTOR pin voltage remains above the internal under voltage threshold (VBAT_UV) for the additional 64 ms after the VRDIV initialization pulse (following the 45-ms PFET on time), the internal PFET turns back on and the main boost charger begins to charge the storage element assuming there is sufficient power available from the harvester at the VIN_DC pin. If VSTOR does not reach the VBAT_UV threshold, then the PFET remains off until the main boost charger can raise the VSTOR voltage to VBAT_UV. If a system load tied to VSTOR discharges VSTOR below VSTOR_GEN or below VBAT_UV during the 32 ms initial MPPT reference voltage measurement or within 110 ms after hot plug, it is recommended to add an external PFET between the system load and VSTOR. An inverted VBAT_OK signal can be used to drive the gate of this system-isolating, external PFET. Otherwise, the VSTOR voltage waveform will have incremental pulses as the IC turns on and off the internal PFET controlled by VBAT_UV or cycles between cold-start and main boost charger operation. Once VSTOR is above VSTOR_CHGEN, the main boost charger employs pulse frequency modulation (PFM) mode of control to regulate the voltage at VIN_DC close to the desired reference voltage. The reference voltage is set by the MPPT control scheme as described in the features section. Input voltage regulation is obtained by transferring charge from the input to VSTOR only when the input voltage is higher than the voltage on pin VREF_SAMP. The current through the inductor is controlled through internal current sense circuitry. The peak current in the inductor is dithered internally to up to three pre-determined levels in order to maintain high efficiency of the charger across a wide input current range. The charger transfers up to a maximum of 100 mA average input current (230mA typical peak inductor current). The boost charger is disabled when the voltage on VSTOR reaches the user set VBAT_OV threshold to protect the battery connected at VBAT from overcharging. In order for the battery to charge to VBAT_OV, the input power must exceed the power needed for the load on VSTOR. See the Power Supply Recommendations section for guidance on minimum input power requirements. Steady state operation for the boost charger is shown in Figure 16. These plots highlight the inductor current, the VSTOR voltage ripple, input voltage regulation and the LBOOST switching node. The cycle-by-cycle minor switching frequency is a function of the boost converter's inductor value, peak current limit and voltage levels on each side of each inductor. Once the VSTOR capacitor, CSTOR, droops below a minimum value, the hysteretic switching repeats. CAUTION If VIN_DC is higher than VSTOR and VSTOR is higher than VBAT_OV, the input VIN_DC is pulled to ground through a small resistance to stop further charging of the attached battery or capacitor. It is critical that if this case is expected, the impedance of the source attached to VIN_DC be higher than 20 Ω and not a low impedance source. 8.4.3 Thermal Shutdown Rechargeable Li-ion batteries need protection from damage due to operation at elevated temperatures. The application should provide this battery protection and ensure that the ambient temperature is never elevated greater than the expected operational range of 85°C. The BQ25504 uses an integrated temperature sensor to monitor the junction temperature of the device. If the OT_PROG pin is tied low, then the temperature threshold for thermal protection is set to TSD_ProtL which is 65°C typically. If the OT_PROG is tied high, then the temperature is set to TSD_ProtH which is 120°C typically. Once the temperature threshold is exceeded, the boost converter/charger is disabled and charging ceases. Once the temperature of the device drops below this threshold, the boost converter and or charger can resume operation. To avoid unstable operation near the overtemp threshold, a built-in hysteresis of approximately 5°C has been implemented. Care should be taken to not over discharge the battery in this condition since the boost converter/charger is disabled. However, if the supply voltage drops to the VBAT_UV setting, then the switch between VBAT and VSTOR will open and protect the battery even if the device is in thermal shutdown. Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 17 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com 9 Application and Implementation NOTE Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality. 9.1 Application Information 9.1.1 Storage Element Selection In order for the charge management circuitry to protect the storage element from over-charging or discharging, the storage element must be connected to VBAT pin and the system load tied to the VSTOR pin. Many types of elements can be used, such as capacitors, super capacitors or various battery chemistries. A storage element with 100 uF equivalent capacitance is required to filter the pulse currents of the PFM switching charger. The equivalent capacitance of a battery can be computed as computed as: CEQ = 2 x mAHrBAT(CHRGD) x 3600 s/Hr / VBAT(CHRGD) (6) In order for the storage element to be able to charge VSTOR capacitor (CSTOR) within the tVB_HOT_PLUG (50 ms typical) window at hot-plug; therefore preventing the IC from entering cold start, the time constant created by the storage element's series resistance (plus the resistance of the internal PFET switch) and equivalent capacitance must be less than tVB_HOT_PLUG . For example, a battery's resistance can be computed as: RBAT = VBAT / IBAT(CONTINUOUS) from the battery specifications. (7) The storage element must be sized large enough to provide all of the system load during periods when the harvester is no longer providing power. The harvester is expected to provide at least enough power to fully charge the storage element while the system is in low power or sleep mode. Assuming no load on VSTOR (i.e., the system is in low power or sleep mode), the following equation estimates charge time from voltage VBAT1 to VBAT2 for given input power is: Refer to SLUC462 for a design example that sizes the storage element. PIN × ηEST × tCHRG = 1/2 × CEQ X (VBAT22 - VBAT12) (8) Note that if there are large load transients or the storage element has significant impedance then it may be necessary to increase the CSTOR capacitor from the 4.7uF minimum or add additional capacitance to VBAT in order to prevent a droop in the VSTOR voltage. See below for guidance on sizing capacitors. 9.1.2 Inductor Selection The boost charger needs an appropriately sized inductor for proper operation. The inductor's saturation current should be at least 25% higher than the expected peak inductor currents recommended below if system load transients on VSTOR are expected. Since this device uses hysteretic control, the boost charger is considered naturally stable systems (single order transfer function). For the boost charger to operate properly, an inductor of appropriate value must be connected between LBOOST, pin 20, and VIN_DC, pin 2. The boost charger internal control circuitry is designed to control the switching behavior with a nominal inductance of 22 µH ± 20%. The inductor must have a peak current capability of > 300 mA with a low series resistance (DCR) to maintain high efficiency. A list of inductors recommended for this device is shown in Table 1. Table 1. Recommended Inductors (1) 18 Inductance (µH) Dimensions (mm) Part Number Manufacturer (1) 22 4.0x4.0x1.7 LPS4018-223M Coilcraft 22 3.8x3.8x1.65 744031220 Wurth 22 2.8x2.8x2.8 744025220 Wurth See WHAT? concerning recommended third-party products. Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 9.1.3 Capacitor Selection In general, all the capacitors need to be low leakage. Any leakage the capacitors have will reduce efficiency, increase the quiescent current and diminish the effectiveness of the IC for energy harvesting. 9.1.3.1 VREF_SAMP Capacitance The MPPT operation depends on the sampled value of the open circuit voltage and the input regulation follows the voltage stored on the CREF capacitor. This capacitor is sensitive to leakage since the holding period is around 16 seconds. As the capacitor voltage drops due to any leakage, the input regulation voltage also drops preventing proper operation from extraction the maximum power from the input source. Therefore, it is recommended that the capacitor be an X7R or COG low leakage capacitor. 9.1.3.2 VIN_DC Capacitance Energy from the energy harvester input source is initially stored on a capacitor, CIN, connected to VIN_DC, pin 2, and VSS, pin 1. For energy harvesters which have a source impedance which is dominated by a capacitive behavior, the value of the harvester capacitor should scaled according to the value of the output capacitance of the energy source, but a minimum value of 4.7 µF is recommended. 9.1.3.3 VSTOR Capacitance Operation of the BQ25504 requires two capacitors to be connected between VSTOR, pin 15, and VSS, pin 1. A high frequency bypass capacitor of at 0.1 µF should be placed as close as possible between VSTOR and VSS. In addition, a low ESR capacitor of at least 4.7 µF should be connected in parallel. 9.1.3.4 Additional Capacitance on VSTOR or VBAT If there are large, fast system load transients and/or the storage element has high resistance, then the CSTOR capacitors may momentarily discharge below the VBAT_UV threshold in response to the transient. This causes the BQ25504 to turn off the PFET switch between VSTOR and VBAT and turn on the boost charger. The CSTOR capacitors may further discharge below the VSTOR_CHGEN threshold and cause the BQ25504 to enter Cold Start. For instance, some Li-ion batteries or thin-film batteries may not have the current capacity to meet the surge current requirements of an attached low power radio. To prevent VSTOR from drooping, either increasing the CSTOR capacitance or adding additional capacitance in parallel with the storage element is recommended. For example, if boost charger is configured to charge the storage element to 4.2 V and a 500 mA load transient of 50 µs duration infrequently occurs, then, solving I = C x dv/dt for CSTOR gives: CSTOR ³ 500 mA ´ 50 ms = 10.5 mF (4.2 V - 1.8 V) (9) Note that increasing CSTOR is the recommended solution but will cause the boost charger to operate in the less efficient cold start mode for a longer period at startup compared to using CSTOR = 4.7 µF. If longer cold start run times are not acceptable, then place the additional capacitance in parallel with the storage element. For a recommended list of standard components, see the EVM User’s Guide (SLUUAA8). Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 19 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com 9.2 Typical Applications 9.2.1 Solar Application Circuit LBST CBYP (1) (2) CSTOR 4.7 µF (min) 22µH Solar Cell + Battery(>100µF) VSTOR CHVR 4.7µF 1 - 16 15 LBST VSTOR ` 14 13 VBAT VSS VSS AVSS 12 VBAT_OK 2 ROC2 VIN_DC 11 ROK1 bq25504 4.42 MΩ ROC 1 15.62MΩ VBAT_OK 3 VOC_SAMP 4 VREF_SAMP OK_PROG CREF 0.01µF OK_HYST 10 9 OT_PROG VBAT_OV VRDIV VBAT _UV 5 6 7 ROV2 4.02MΩ ROV1 5.90MΩ (1) Place close as possible to IC pin 15 (VSTOR) and pin 13 (VSS) (2) See the Capacitor Selection section for guidance on sizing CSTOR 8 4.42 MΩ ROK2 4.22 MΩ ROK3 1.43MΩ RUV2 4.42 MΩ RUV 1 5.60 MΩ Figure 14. Typical Solar Application Circuit 9.2.1.1 Design Requirements The desired voltage levels are VBAT_OV = 3.15 V, VBAT_UV = 2.20 V, VBAT_OK = 2.44 V, VBAT_OK_HYST = 2.80 V and MPP (VOC) = 78% which is typical for solar panels. There are no large load transients expected. The IC must stop charging if its junction temperature is above 65°C. The simulated solar panel open circuit voltage is 1.0 V. 9.2.1.2 Detailed Design Procedure The recommended L1 = 22 µH, CBYP = 0.01 µF and low leakage CREF = 10 nF are selected. In order to ensure the fastest recovery of the harvester output voltage to the MPPT level following power extraction, the minimum recommended CIN = 4.7 µF is selected. Because no large system load transients are expected and to ensure fast charge time during cold start, the minimum recommended CSTOR = 4.7 µF. To stop charging when the IC junction temperature is above 65°C, the OT_PROG pin is tied to ground. • With VBAT_UV < VBAT_OV ≤ 5.5 V, to size the VBAT_OV resistors, first choose RSUMOV = ROV1 + ROV2 = 10 MΩ then solve Equation 3 for 3 RSUMOV ´ VBIAS 3 10 MW ´ 1.25 V ROV1 = ´ ´ = 5.95 MW ® 5.90 MW closest 1% value then 2 VBAT _ OV 2 3.15 V (10) • 20 ROV2 = RSUMOV - ROV1 = 10 MΩ - 5.95 MΩ = 4.05 MΩ → 4.02 MΩ resulting in VBAT_OV = 3.15 V Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 Typical Applications (continued) • To size the VBAT_UV resistors, first choose RSUMUV = RUV1 + RUV2 = 10 MΩ then solve Equation 2 for RSUMUV ´ VBIAS 10 MW ´ 1.25 V RUV1 = = = 5.68 MW ® 5.60 MW closest 1% value then VBATUV 2.2 V • RUV2 = RSUMUV - RUV1 = 10 MΩ - 5.60 MΩ = 4.4 MΩ → 4.42 MΩ closest 1% resistor resulting in VBAT_UV = 2.2 V. With VBAT_OV ≥ VBAT_OK_HYST > VBAT_OK ≥ VBAT_UV, to size the VBAT_OK and VBAT_OK_HYST resistors, first choose RSUMOK = ROK1 + ROK2 + ROK3 = 10 MΩ then solve Equation 4 and Equation 5 for VBIAS ´ RSUMOK æ 1.25 V ö ROK1 = =ç ´ 10 MW = 4.46 MW ® 4.42 MW closest 1% resistor then VBAT _ OK _ HYST è 2.8 V ø÷ (12) • • • æ VBAT _ OK _ PROG ö æ 2.45 V ö - 1÷ ´ ROK1 = ç - 1÷ ´ 4.24 MW = 4.07 MW, then ROK2 = ç VBIAS 1.2 5 V è ø è ø (13) ROK3 = RSUMOK - ROK1 - ROK2 = 10 MΩ - 4.42 MΩ - 4.22 MΩ = 1.36 MΩ → 1.43 MΩ to give VBAT_OK = 2.44 V and VBAT_OK_HYST = 2.85 V. Keeping in mind that VREF_SAMP stores the MPP voltage for the harvester, first choose RSUMOC = ROC1 + ROC2 = 20 MΩ then solve Equation 1 for æ VREF _ SAMP ö ROC1 = ç ÷ ´ RSUMOC = 0.78 ´ 20 MW = 15.6 MW, then è VIN _ DC(OC) ø • (11) (14) æ VREF _ SAMP ö ROC2 = RSUMOC ´ ç 1 ÷ = 20 MW (1 - 0.78 ) = 4.4 MW closest 1% resistors VIN _ DC(OC) ø è SLURAQ1 provides help on sizing and selecting the resistors. (15) 9.2.1.3 Application Curves VINDC = sourcemeter with VSOURCE = 1.0 V and compliance of 2.75 mA VBAT connected to 0.1 F depleted supercap No resistance load on VSTOR Figure 15. Startup into Depleted Storage Element VIN_DC = sourcemeter with VSOURCE = 1 V and compliance of 10.5 mA VBAT = 0.1 F supercap VSTOR = 2 kΩ resistive load Figure 16. Boost Charger Operational Waveforms Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 21 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com Typical Applications (continued) VIN_DC = sourcemeter with VSOURCE = 1 V and compliance of 10.5 mA VBAT = 0.1 F supercap VSTOR = open to 500 Ω to open resistive load (IL = load current on VSTOR) VIN_DC = sourcemeter with VSOURCE = 1 V and compliance of 10.5 mA VBAT = sourcemeter with VSOURCE = 2.8V and compliance of 1A IL = inductor current Figure 17. 5 mA Load Transient on VSTOR VIN_DC = sourcemeter with VSOURCE = 1 V and compliance of 10.5 mA VBAT = sourcemeter with VSOURCE = 2.8 V and compliance of 1A Figure 18. MPPT Operation VIN_DC = sourcemeter with VSOURCE = 1 V and compliance of 2.75 mA No storage element on VBAT VSTOR artificially ramped from 0V to 3.15 V to 0 V using a power amp driven by a function generator Figure 20. VBAT_OK Operation Figure 19. VRDIV Operation 22 Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 Typical Applications (continued) 9.2.2 TEG Application Circuit L BST CBYP (1) (2) CSTOR 4.7 µF (min) 22µH Battery(>100µF) VSTOR CHVR 4.7µF 16 15 LBST VSTOR ` 14 13 VBAT VSS 1 VSS 2 VIN_DC 3 VOC_SAMP OK_PROG VREF _SAMP OK_HYST AVSS 12 VBAT_OK Thermo electric generator ROC2 10 MΩ 11 ROK1 bq25504 10 MΩ ROC1 VBAT_OK CREF 4 0.01µF 10 9 6 7 ROK2 6.12 MΩ ROK3 OT_PROG VBAT_OV VRDIV VBAT_UV 5 3.32 MΩ 8 542kΩ VSTOR ROV2 5.62MΩ ROV1 4.42MΩ (1) Place close as possible to IC pin 15 (VSTOR) and pin 13 (VSS) (2) See the Capacitor Selection section for guidance on sizing CSTOR RUV 2 6.12MΩ RUV 1 3.83MΩ Figure 21. Typical TEG Application Circuit 9.2.2.1 Design Requirements The desired voltage levels are VBAT_OV = 4.25 V, VBAT_UV = 3.20 V, VBAT_OK = 3.55 V, VBAT_OK_HYST = 3.76 V and MPP (VOC) = 50% which is typical for TEG harvesters. The IC must stop charging if its junction temperature is above 120°C. The simulated TEG open circuit voltage is 1.0 V. 9.2.2.2 Detailed Design Procedure The recommended L1 = 22 µH, CBYP = 0.01 µF and low leakage CREF = 10 nF are selected. In order to ensure the fastest recovery of the harvester output voltage to the MPPT level following power extraction, the minimum recommended CIN = 4.7 µF is selected. Because no large system load transients are expected and to ensure fast charge time during cold start, the minimum recommended CSTOR = 4.7 µF. To stop charging when the IC junction temperature is above 120°C, the OT_PROG pin is tied to VSTOR. Referring back to the procedure in Detailed Design Procedure or using the spreadsheet calculator at SLURAQ1 gives the following values: • ROV1 = 4.42 MΩ, ROV2 = 5.49 MΩ resulting in VBAT_OV = 4.26 V due to rounding to the nearest 1% resistor. • RUV1 = 3.83 MΩ, RUV2 = 6.04 MΩ resulting in VBAT_UV = 3.22 V due to rounding to the nearest 1% resistor • ROK1 = 3.32 MΩ, ROK2 = 6.04 MΩ, ROK3 = 0.536 MΩ resulting in VBAT_OK = 3.52 V and VBAT_OK_HYST = 3.73 V after rounding. • ROC1 = 10 MΩ and ROC2 = 10 MΩ gives 50% MPP voltage. Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 23 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com Typical Applications (continued) 9.2.2.3 Application Curves VINDC = sourcemeter with VSOURCE = 2.0 V and compliance of 1 mA VBAT connected to LiIon battery VSTOR = 50 kΩ resistor Figure 22. Startup by Attaching Charged Storage Element VIN_DC = sourcemeter with VSOURCE = 2.0 V and compliance of 1 mA VBAT connected to LiIon battery VSTOR = open to 50Ω to open resistive load (IL = load current on VSTOR) VIN_DC = sourcemeter with VSOURCE = 2.0 V and compliance of 100 mA VBAT connected to LiIon battery VSTOR = 100 kΩ resistive load (IL = inductor current) Figure 23. Boost Charger Operational Waveforms VIN_DC = sourcemeter with VSOURCE = 2.0 V and compliance of 1 mA VBAT connected to LiIon battery IL = inductor current Figure 24. 50 mA Load Transient on VSTOR VIN_DC = sourcemeter with VSOURCE = 2.0 V and compliance of 1 mA VBAT connected to LiIon battery Figure 25. MPPT Operation VIN_DC = sourcemeter with VSOURCE = 2.0 V and compliance of 1 mA No storage element on VBAT VSTOR artificially ramped from 0V to 4.25V to 0V using a power amp driven by a function generator Figure 27. VBAT_OK Operation Figure 26. VRDIV Operation 24 Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 Typical Applications (continued) 9.2.3 MPPT Disabled, Low Impedance Source Application Circuit L BST Primary Battery or other Low Z source CBYP (2) (1) CSTOR 22µH VSTOR CHVR 4.7µF 16 15 LBST VSTOR ` 14 13 VBAT VSS 1 VSS 2 VIN_DC 3 VOC_SAMP OK_PROG 10 4 VREF _SAMP OK_HYST 9 AVSS 12 VBAT_OK VBAT_OK 11 ROK1 bq25504 VSTOR OT_PROG VBAT_OV VRDIV VBAT_UV 5 6 7 8 ROK2 ROK3 VSTOR ROV2 ROV1 (1) Place close as possible to IC pin 15 (VSTOR) and pin 13 (VSS) (2) See the Capacitor Selection section for guidance on sizing CSTOR Figure 28. Typical MPPT Disabled Application Circuit (Low Iq Boost Converter from Low Impedance Source) 9.2.3.1 Design Requirements The input source is a low impedance 1.2 V battery therefore MPPT is not needed. The output will be a low ESR capacitor therefore VSTOR can be tied to VBAT and VBAT_UV is not needed. The desired voltage levels are VBAT_OV = 3.30 V, VBAT_OK = 2.80 V, VBAT_OK_HYST = 3.10 V, and MPPT disabled. The IC must stop charging if its junction temperature is above 65°C. Load transients are expected. 9.2.3.2 Detailed Design Procedure The recommended L1 = 22 µH, CBYP = 0.01 µF and low leakage CREF = 10 nF are selected. The minimum recommended CIN = 4.7 µF is selected. To prevent VSTOR from drooping during system load transients, CSTOR is set to 100 µF. To disable the sampling for MPPT, the VOC_SAMP pin is tied to VSTOR. To disable the input voltage regulation circuit, the VREF_SAMP pin is tied to GND. Since the VBAT_UV function is not needed, the VBAT_UV can be tied to VSTOR. To stop charging when the IC junction temperature is above 65°C, the OT_PROG pin is tied to GND. Referring back to the procedure in Detailed Design Procedure or using the spreadsheet calculator at SLURAQ1 gives the following values: • ROV1 = 5.62 MΩ, ROV2 = 4.22 MΩ resulting in VBAT_OV = 3.28 V due to rounding to the nearest 1% resistor. • ROK1 = 4.12 MΩ, ROK2 = 5.11 MΩ, ROK3 = 0.976 MΩ resulting in VBAT_OK = 2.80 V and VBAT_OK_HYST = 3.10 V after rounding. Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 25 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com Typical Applications (continued) 9.2.3.3 Application Curves VIN_DC = low impedance voltage source = 1.5 V VBAT = VSTOR = 100 µF VSTOR = 500 Ω resistor VIN_DC = low impedance voltage source = 1.5 V VBAT = VSTOR = 100 µF VSTOR = 330 Ω resistive load (IL = inductor current) Figure 29. Startup Figure 30. Boost Charger Operational Waveforms VIN_DC = low impedance voltage source = 1.5 V ) VBAT = VSTOR = 100 µF VSTOR = open to 75 Ω to open resistive load (IL = load current on VSTOR VIN_DC = low impedance voltage source = 1.5 V VBAT = VSTOR = 100 µF Figure 31. 40 mA Load Transient on VSTOR Figure 32. VRDIV Operation VIN_DC = low impedance voltage source = 1.5 V VBAT = VSTOR = 100 µF VSTOR artificially ramped from 0 V to 3.3 V to 0 V using a power amp driven by a function generator Figure 33. VBAT_OK Operation 26 Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 10 Power Supply Recommendations The energy harvesting source (e.g., solar panel, TEG, vibration element) must provide a minimum level of power for the IC to operate as designed. The IC's minimum input power required to exit cold start can be estimated as: (1.8V )2 PIN > PIN(CS) = VIN(CS) ´ IIN(CS) > (I - STR _ ELM _ LEAK@1.8V ´ 1.8V )+ RSTOR(CS) 0.05 (16) where I-STR_ELM_LEAK@1.8V is the storage element leakage current at 1.8V and RSTOR(CS) is the equivalent resistive load on VSTOR during cold start and 0.05 is an estimate of the worst case efficiency of the cold start circuit. Once the IC is out of cold start and the system load has been activated (e.g., using the VBAT_OK signal), the energy harvesting element must provide the main boost charger with at least enough power to meet the average system load. Assuming RSTOR(AVG) represents the average resistive load on VSTOR, the simplified equation below gives an estimate of the IC's minimum input power needed during system operation: PIN ´ hEST > PLOAD = (VBAT _ OV )2 RSTOR(AVG) + VBAT _ OV ´ I - STR _ ELM _ LEAK @ VBAT _ OV (17) where ηEST can be derived from the datasheet efficiency curves for the given input voltage and current and VBAT_OV. The simplified equation above assumes that, while the harvester is still providing power, the system goes into low power or sleep mode long enough to charge the storage element so that it can power the system when the harvester eventually is down. Refer to spreadsheet SLUC462 for a design example that sizes the energy harvester. 11 Layout 11.1 Layout Guidelines As for all switching power supplies, the PCB layout is an important step in the design, especially at high peak currents and high switching frequencies. If the layout is not carefully done, the boost charger could show stability problems as well as EMI problems. Therefore, use wide and short traces for the main current path and for the power ground paths. The input and output capacitors as well as the inductors should be placed as close as possible to the IC. For the boost charger, first priority are the output capacitors, including the 0.1 uF bypass capacitor (CBYP), followed by CSTOR, which should be placed as close as possible between VSTOR, pin 15, and VSS, pin 1 or 13. Next, the input capacitor, CIN, should be placed as close as possible between VIN_DC, pin 2, and VSS, pin 1. Last in priority is the boost charger inductor, L1, which should be placed close to LBOOST, pin 16, and VIN_DC, pin 2 if possible. It is best to use vias and bottom traces for connecting the inductor to its respective pins instead of the capacitors. To minimize noise pickup by the high impedance voltage setting nodes (VBAT_OV, VBAT_UV, OK_PROG, OK_HYST), the external resistors should be placed so that the traces connecting the midpoints of each divider to their respective pins are as short as possible. When laying out the non-power ground return paths (e.g. from resistors and CREF), it is recommended to use short traces as well, separated from the power ground traces and connected to AVSS pin 12. This avoids ground shift problems, which can occur due to superimposition of power ground current and control ground current. The PowerPad should not be used as a power ground return path. The remaining pins are digital signals with minimal layout restrictions. See Figure 34 for an example layout. In order to maximize efficiency at light load, the use of voltage level setting resistors > 1 MΩ is recommended. In addition, the sample and hold circuit output capacitor on VREF_SAMP must hold the voltage for 16 s. During board assembly, contaminants such as solder flux and even some board cleaning agents can leave residue that may form parasitic resistors across the physical resistors/capacitors and/or from one end of a resistor/capacitor to ground, especially in humid, fast airflow environments. This can result in the voltage regulation and threshold levels changing significantly from those expected per the installed components. Therefore, it is highly Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 27 BQ25504 SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 www.ti.com Layout Guidelines (continued) recommended that no ground planes be poured near the voltage setting resistors or the sample and hold capacitor. In addition, the boards must be carefully cleaned, possibly rotated at least once during cleaning, and then rinsed with de-ionized water until the ionic contamination of that water is well above 50 Mohm. If this is not feasible, then it is recommended that the sum of the voltage setting resistors be reduced to at least 5X below the measured ionic contamination. V sy S T O st R em to lo ad 11.2 Layout Example TOP GND TOP VIN ge ra to sto VBAT t en elem VBAT_OK signal BOT GND BOT GND Figure 34. Recommended Layout 11.3 Thermal Considerations Implementation of integrated circuits in low-profile and fine-pitch surface-mount packages typically requires special attention to power dissipation. Many system-dependent issues such as thermal coupling, airflow, added heat sinks and convection surfaces, and the presence of other heat-generating components affect the powerdissipation limits of a given component. Three basic approaches for enhancing thermal performance are listed below. • Improving the power-dissipation capability of the PCB design • Improving the thermal coupling of the component to the PCB • Introducing airflow in the system For more details on how to use the thermal parameters in the Thermal Table, check the Thermal Characteristics Application Note (SZZA017) and the IC Package Thermal Metrics Application Note (SPRA953). 28 Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 BQ25504 www.ti.com SLUSAH0F – OCTOBER 2011 – REVISED NOVEMBER 2019 12 Device and Documentation Support 12.1 Device Support 12.1.1 Third-Party Products Disclaimer TI'S PUBLICATION OF INFORMATION REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT CONSTITUTE AN ENDORSEMENT REGARDING THE SUITABILITY OF SUCH PRODUCTS OR SERVICES OR A WARRANTY, REPRESENTATION OR ENDORSEMENT OF SUCH PRODUCTS OR SERVICES, EITHER ALONE OR IN COMBINATION WITH ANY TI PRODUCT OR SERVICE. 12.1.2 Zip Files • • • http://www.ti.com/lit/zip/SLUC484 http://www.ti.com/lit/zip/SLURAQ1 http://www.ti.com/lit/zip/SLUC462 12.2 Documentation Support 12.2.1 Related Documentation For related documentation see the following: • EVM User’s Guide, SLUUAA8 • Thermal Characteristics Application Note, SZZA017 • IC Package Thermal Metrics Application Note, SPRA953 12.3 Receiving Notification of Documentation Updates To receive notification of documentation updates, navigate to the device product folder on ti.com. In the upper right corner, click on Alert me to register and receive a weekly digest of any product information that has changed. For change details, review the revision history included in any revised document. 12.4 Support Resources TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight from the experts. Search existing answers or ask your own question to get the quick design help you need. Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of Use. 12.5 Trademarks E2E is a trademark of Texas Instruments. All other trademarks are the property of their respective owners. 12.6 Electrostatic Discharge Caution These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam during storage or handling to prevent electrostatic damage to the MOS gates. 12.7 Glossary SLYZ022 — TI Glossary. This glossary lists and explains terms, acronyms, and definitions. 13 Mechanical, Packaging, and Orderable Information The following pages include mechanical, packaging, and orderable information. This information is the most current data available for the designated devices. This data is subject to change without notice and revision of this document. For browser-based versions of this data sheet, refer to the left-hand navigation. Submit Documentation Feedback Copyright © 2011–2019, Texas Instruments Incorporated Product Folder Links: BQ25504 29 PACKAGE OPTION ADDENDUM www.ti.com 10-Dec-2020 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Pins Package Drawing Qty Eco Plan (2) Lead finish/ Ball material MSL Peak Temp Op Temp (°C) Device Marking (3) (4/5) (6) BQ25504RGTR ACTIVE VQFN RGT 16 3000 RoHS & Green NIPDAU Level-2-260C-1 YEAR -40 to 85 B5504 BQ25504RGTT ACTIVE VQFN RGT 16 250 RoHS & Green NIPDAU Level-2-260C-1 YEAR -40 to 85 B5504 (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may reference these types of products as "Pb-Free". RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption. Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of