This table gives cross-reference parts and alternative options found for C0805C104K5RACTU. The Form Fit Function (FFF) tab will give you the options that are more likely to serve as direct pin-to-pin alternates or drop-in parts. The Functional Equivalents tab will give you options that are likely to match the same function of C0805C104K5RACTU, but it may not fit your design. Always verify details of parts you are evaluating, as these parts are offered as suggestions for what you are looking for and are not guaranteed.
High serial cell count battery (>15s) systems are becoming more and more common for industrial applications. These applications are cost sensitive and require a simple solution that includes monitoring: protection: and control or even SOC (State of Charge) information rather than only basic independent hardware protection. This design offers a platform for the complete pack side solution. All independent hardware protection features are incorporated from the bq76930 and a robust communication interface is implemented for host device to read the battery information.
This is a quasi-resonance (QR) flyback reference design for industrial applications: which illustrates how to convert AC input voltage 85 - 115 Vac to isolated multiple outputs: 24 V/0.5 A: 12 V/0.9 A and 15 V/20 mA using the UCC28600 Controller. The quasi-resonant switching of the UCC28600 allows this design to achieve peak efficiency of up to 87.5% while the no-load losses are less than 82 mW.
This reference design showcases a robust: compact: and efficient main power supply in DCM flyback topology for motor drives using the UCC28740 flyback controller. This design can work with a wide input voltage range of 290–1000 VDC delivering up to 50 W of continuous power. Multiple output rails at 24 V (1.25 A): 15 V (0.67 A): 5 V (2 A): 3.3 V (0.1 A) are available for control: gate drive: sensor: I/O: and other applications; additionally an isolated 5-V (0.1 A) output is provided for isolated communication power. The load and line regulation are within 0.5% over the entire operation range by the use of opto-regulated feedback. Key benefits of the UCC28740 device include valley switching enabling higher efficiency (>85% at 550 VDC: 50 W): internal HV FET enabling self-start without external circuitry: and frequency dithering that reduces EMI.
This reference design provides isolated +24V (45W): ±16 V (4.5W): and +6V (0.5W) outputs to power the control electronics in variable speed drives. The power supply can be either powered directly from 3-phase AC mains (380Vac to 690Vac) or can be powered from the DC-link voltage (400Vdc to 1200Vdc). This design uses a quasi-resonant flyback topology and is rated for 50-Watt total output power. The line and load regulation of the power supply is designed to be within 5% using primary-side regulation (eliminating costly feedback components). The power supply is designed to meet the clearance: creepage: and isolation test voltages as per IEC61800-5 requirements.
The PMP10767 reference design uses Buck converter to convert universal AC input voltage to a 15V/0.13A DC output with UCC28911 controller. Circuit simplicity is achieved with quasi-resonant valley-switching operation and the utilization of Buck topology. Peak 77% efficiency is achieved at f
This high voltage SEPIC converter provides a regulated 200V output from a 200V input and achieves efficiency as high as 96%. Possible applications include televisions, telecom and industrial.
PMP20129 is an isolated synchronous flyback converter with a 3.3V/5A output. The 36-60V input range is suitable for most telecom and Power over Ethernet (PoE) applications that require high efficiency.
The PMP15018 reference design incorporates the TPS54541 42V 5A DC/DC converter and two TPS56C215 17V: 12A DC/DC converters. The solution operates from 15V to 42V input and generates 1.0V @10A and 1.2V@10A voltage rails. The 1.0V and 1.2V converters operate at 1MHz and 400kHz respectively in order to highlight the size vs. performance advantages/disadvantage for low vs. high frequency operation.
This reference design implements a five-segment LED smart stack light with 20 LEDs used in factory floor and industrial process automation of greater complexity. An IO-Link interface is implemented for controlling the stack light and reading back status information. The design features low power consumption to be powered through the IO-Link interface.This signal light reference design demonstrates how the power dissipation of the RGB LED driver can be reduced by 30% and the range of the brightness control can be extended. Automatic brightness control adapts the brightness to ambient light. The reference design uses a simple PWM to modify the output voltage of a switching regulator to implement dynamic headroom control.
This reference design is an automotive front-end power solution for use in high performance cluster applications. This design supports three output voltage rails of 5 V: 3.3 V and 1.2 V. The design also operates with a wide input voltage range and withstands reverse battery conditions. A transient voltage suppressor at the input adds protection for load dump. The above-AM band switching frequencies and dithering reduce the burden of emissions compliance. This reference design also provides results for conducted emissions tests for CISPR 25 Class 5.
