Fixed Inductors

Part Number	Description / PDF	Quantity
CC453232-820KL J.W. Miller / Bourns	FIXED IND 82UH 200MA 3.5 OHM SMD	0
SRP6030CA-R18M J.W. Miller / Bourns	FIXED IND 180NH 32A 1.75MOHM SMD	0
SRP5030CA-2R2M J.W. Miller / Bourns	FIXED IND 2.2UH 9.7A 14.5MOHM SM	11
SDR1005-822KL J.W. Miller / Bourns	FIXED IND 8.2MH 110MA 34 OHM SMD	686
PM3308-471M-RC J.W. Miller / Bourns	FIXED IND 470UH 200MA 4 OHM SMD	0
SDR0604-6R8ML J.W. Miller / Bourns	FIXED IND 6.8UH 1.6A 120MOHM SMD	627
9230-54-RC J.W. Miller / Bourns	FIXED IND 27UH 185MA 3.5 OHM TH	0
SDR0503-182JL J.W. Miller / Bourns	FIXED IND 1.8MH 55MA 15 OHM SMD	871
RL262-152J-RC J.W. Miller / Bourns	FIXED IND 1.5MH 50MA 11 OHM TH	0
SRR1280A-121K J.W. Miller / Bourns	FIXED IND 120UH 1.95A 200MOHM SM	478
SRN3015-4R7M J.W. Miller / Bourns	FIXED IND 4.7UH 1.4A 136MOHM SMD	935
SDR1307A-100M J.W. Miller / Bourns	FIXED IND 10UH 5.6A 21 MOHM SMD	0
PM3316-1R5M-RC J.W. Miller / Bourns	FIXED IND 1.5UH 6.5A 9 MOHM SMD	1098
1120-470K-RC J.W. Miller / Bourns	FIXED IND 47UH 5.5A 35 MOHM TH	206
SRP4030FA-6R8M J.W. Miller / Bourns	FIXED IND 6.8UH 4A 74.1 MOHM SMD	0
SRP2010-R47M J.W. Miller / Bourns	FIXED IND 470NH 3.3A 40 MOHM SMD	848
SRR4528A-1R2Y J.W. Miller / Bourns	FIXED IND 1.2UH 4.82A .17OHM SMD	0
SDR0906-330KL J.W. Miller / Bourns	FIXED IND 33UH 1.25A 180MOHM SMD	0
CVH160808-R24M J.W. Miller / Bourns	FIXED IND 240NH 1.2A 125MOHM SMD	195
RL895-470K-RC J.W. Miller / Bourns	FIXED IND 47UH 1.3A 100 MOHM TH	0

Fixed Inductors

1. Overview

Fixed inductors are passive electronic components designed to store energy in magnetic fields when electrical current flows through them. Unlike variable inductors, their inductance values remain constant during operation. These components play critical roles in filtering, signal processing, energy storage, and electromagnetic interference (EMI) suppression across modern electronics, including power supplies, communication systems, and automotive electronics.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Wirewound Inductors	High precision, high current handling, low resistance	Power supplies, DC-DC converters
Chip Inductors	Compact SMD package, stable performance at high frequencies	Mobile devices, RF circuits
Ferrite Bead Inductors	Effective high-frequency noise suppression	EMI filtering in digital circuits
Thin-Film Inductors	Ultra-compact, high Q-factor, tight tolerance	5G communication modules, IoT devices

3. Structure and Composition

Typical fixed inductors consist of:

Magnetic Core: Made from ferrite, powdered iron, or composite materials to concentrate magnetic flux
Coil Structure: Copper wire wound around the core (enamelled or silver-plated)
Encapsulation: Molded resin or ceramic coating for mechanical protection and insulation
Terminations: Solder-coated ends for PCB mounting (for SMD types) or leaded connections

4. Key Technical Specifications

Parameter	Description	Importance
Inductance (L)	Measured in henrys (H), determines energy storage capacity	Defines filtering/energy storage performance
Rated Current (I_rated)	Maximum DC current before saturation	Prevents core saturation and failure
DC Resistance (DCR)	Resistance of coil windings	Affects efficiency and thermal performance
Self-Resonant Frequency (SRF)	Frequency where inductor behaves as capacitor	Limits effective operating frequency range
Q Factor	Quality factor indicating efficiency	Higher Q = lower energy losses

5. Application Fields

Consumer Electronics: Smartphones, laptops, LED drivers
Industrial Equipment: Motor drives, power inverters
Automotive Systems: ECU modules, EV battery management
Telecom Infrastructure: Base station filters, optical transceivers

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
Murata	LQH3NPN100M	10 H, 1.2A, 1.8 1.4mm chip inductor
TDK	MLZ2012A100T	100MHz SRF, 1.0 1.25mm for RF circuits
Vishay	IHLP2525CZER1R0M	1 H, 12A, composite construction
Coilcraft	0402DC-103J	10 H, 5% tolerance, ultra-low profile

7. Selection Guidelines

Key considerations during selection:

Calculate required inductance based on switching frequency and ripple current
Verify rated current exceeds maximum operating current by 20-30%
Select SRF higher than circuit operating frequency
Consider package size vs. thermal dissipation requirements
For EMI suppression: Choose ferrite beads with impedance curves matching target frequencies

8. Industry Trends

Current development trends include:

Miniaturization: Sub-0.5mm size inductors for wearable devices
High-Frequency Operation: Components supporting >10GHz 5G applications
Integrated Solutions: Combined inductor-filter modules
Material Innovation: Nanocrystalline cores for higher saturation flux
Automotive Focus: AEC-Q qualified parts for EV/HEV systems