Produktdetails

Number of series cells 1 Charge current (max) (A) 0.1 Vin (max) (V) 3 Cell chemistry Li-Ion/Li-Polymer, SuperCap Battery charge voltage (min) (V) 2.5 Battery charge voltage (max) (V) 5.25 Absolute max Vin (max) (V) 5.5 Control topology Switch-Mode Boost Control interface Standalone (RC-Settable) Features Input OVP, Solar input/MPPT Vin (min) (V) 0.6 Rating Catalog Operating temperature range (°C) -40 to 85
Number of series cells 1 Charge current (max) (A) 0.1 Vin (max) (V) 3 Cell chemistry Li-Ion/Li-Polymer, SuperCap Battery charge voltage (min) (V) 2.5 Battery charge voltage (max) (V) 5.25 Absolute max Vin (max) (V) 5.5 Control topology Switch-Mode Boost Control interface Standalone (RC-Settable) Features Input OVP, Solar input/MPPT Vin (min) (V) 0.6 Rating Catalog Operating temperature range (°C) -40 to 85
VQFN (RGT) 16 9 mm² 3 x 3
  • Ultra low-power with high-efficiency DC-DC boost converter/charger
    • Continuous energy harvesting from low-input sources: V IN ≥ 130 mV (Typical)
    • Ultra-low quiescent current: I Q < 330 nA (Typical)
    • Cold-start voltage: V IN ≥ 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
  • Ultra low-power with high-efficiency DC-DC boost converter/charger
    • Continuous energy harvesting from low-input sources: V IN ≥ 130 mV (Typical)
    • Ultra-low quiescent current: I Q < 330 nA (Typical)
    • Cold-start voltage: V IN ≥ 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

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.

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 V IN as low as 600 mV, and once started, can continue to harvest energy down to V IN = 130 mV.

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 (C REF).

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.

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.

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 V IN as low as 600 mV, and once started, can continue to harvest energy down to V IN = 130 mV.

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 (C REF).

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.

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Technische Dokumentation

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Typ Titel Datum
* Data sheet BQ25504 Ultra Low-Power Boost Converter With Battery Management For Energy Harvester Applications datasheet (Rev. G) PDF | HTML 18 Aug 2023
Product overview Battery Management Solutions for Wearable and Fitness Devices (Rev. C) 18 Aug 2014
Analog Design Journal Accurately measuring efficiency of ultralow-IQ devices 22 Jan 2014
Product overview Industry’s Most Efficient Nano Power Harvesting Solutions (Rev. A) 08 Nov 2013
Application note Self-Powered Ambient Light Sensor Using bq25504 (Rev. A) 19 Okt 2013
Application note Measuring Efficiency of the bq25504 Energy Harvesting Battery Charger 24 Jul 2013
Product overview Power Bank Charger ICs 25 Feb 2013
Application note BQ25504 Optimization of MPPT algorithm 13 Feb 2012
User guide Ultra Low Power Boost Converter Charger Energy Harvester (Rev. A) 20 Okt 2011

Design und Entwicklung

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Codebeispiel oder Demo

SLUC462 Solar App Design Example V1.3, bq25504

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Test report: PDF
Schaltplan: PDF
Gehäuse Pins CAD-Symbole, Footprints und 3D-Modelle
VQFN (RGT) 16 Ultra Librarian

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  • Materialinhalt
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