
In many electronic systems, stable operation depends on how power is generated, distributed, and sequenced across different circuit blocks. If power rails turn on in the wrong order or voltage levels are unstable, processors may fail to boot, memory can lose data, and sensitive components may get damaged. Managing this using multiple discrete regulators and control circuits increases design complexity and failure risk. A Power Management IC helps solve this by controlling multiple power functions inside a single device.
| Image | Part Number / Manufacturer | Description / Specs | MOQ | Datasheet | RFQ | |
|---|---|---|---|---|---|---|
![]() | UCD1H220MC1LGS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 22UF 20% 50V SMD | 1 | |||
![]() | UCD1H100MC1LGS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 10UF 20% 50V SMD | 1 | |||
![]() | UCD1H470MC6LGS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 47UF 20% 50V SMD | 1 | |||
![]() | UCD1E560MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 56UF 20% 25V SMD | 1 | |||
![]() | UCD1C560MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 56UF 20% 16V SMD | 1 | |||
![]() | UCD1A680MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 68UF 20% 10V SMD | 1 | |||
![]() | UCD1A560MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 56UF 20% 10V SMD | 1 | |||
![]() | UCD0J151MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 150UF 20% 6.3V SMD | 1 | |||
![]() | UCD1H100MC6LGS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 10UF 20% 50V SMD | 1 | |||
![]() | UCD1C330MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 33UF 20% 16V SMD | 1 | |||
![]() | UCD1C270MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 27UF 20% 16V SMD | 1 | |||
![]() | UCD0J560MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 56UF 20% 6.3V SMD | 1 | |||
![]() | UCD1A270MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 27UF 20% 10V SMD | 1 | |||
![]() | UCD0J330MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 33UF 20% 6.3V SMD | 1 | |||
![]() | UCD0J270MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 27UF 20% 6.3V SMD | 1 | |||
![]() | UCD1H3R3MCL1GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 3.3UF 20% 50V SMD | 1 | |||
![]() | UCD1V151MCL6GS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 150UF 20% 35V SMD | 1 | |||
![]() | UCD1J151MNQ1MS Manufacturer: Nichicon Category: Aluminum Electrolytic Capacitors | CAP ALUM 150UF 20% 63V SMD | 1 | |||
![]() | 10AX820MEFC10X9 Manufacturer: Rubycon Category: Aluminum Electrolytic Capacitors | CAP ALUM 820UF 20% 10V RADIAL | 1 | |||
![]() | 10AX180MEFC5X11 Manufacturer: Rubycon Category: Aluminum Electrolytic Capacitors | CAP ALUM 180UF 20% 10V RADIAL | 1 |
Many systems in operation rely on PMICs selected during original product design. These devices are often tightly linked to processor requirements, board power architecture, and system startup behavior. When a PMIC reaches end-of-life, replacing it can be difficult. Differences in pin layout, sequencing behavior, voltage accuracy, or protection response can affect system stability.
This is common in industrial, automotive, and medical systems where equipment remains active for many years. Maintenance teams often require the same PMIC to avoid redesign or system requalification. Delays in sourcing compatible PMICs can increase downtime and service cost.
Maketronics supports global engineering and procurement teams with reliable sourcing of both active and obsolete Power Management ICs.
A PMIC is an integrated circuit that manages voltage regulation, power sequencing, monitoring, and protection to ensure stable system operation.
Correct power sequencing ensures processors, memory, and peripherals start safely and operate reliably without damage or data corruption.
PMICs are widely used in embedded systems, mobile devices, industrial equipment, automotive electronics, and communication hardware.
Replacing an obsolete PMIC may require redesign and system validation because differences in pin layout, sequencing behavior, and protection features can affect stability.