Skip to main content

Memory Controllers

Memory Controllers are essential building blocks in modern electronics design and procurement. Octatronics catalogs 50+ listed parts in this category from manufacturers such as Renesas, AMD/Xilinx and Analog Technologies, with searchable part numbers, package data, lifecycle signals, and RFQ support for engineering and purchasing teams.

Request Quote
50+Products
10+Manufacturers
100%Original & New
GlobalDelivery

Browse Memory Controllers Products

Showing 10 of 50 products
PART NUMBERMANUFACTURERDESCRIPTIONSTOCKQTY / ACTION
DS1312S-2+T&RAnalog TechnologiesPackage / Case: 8-SOIC (0.154", 3.90mm Width) | Mounting Type: Surface Mount | Operating Temperature: -40°C ~ 85°C | Supplier Device Package: 8-SOIC | Voltage - Supply: 4.75V ~ 5.5V | Controller Type: Nonvolatile RAM15,598
DS1312S+T&RAnalog TechnologiesPackage / Case: 16-SOIC (0.295", 7.50mm Width) | Mounting Type: Surface Mount | Operating Temperature: -40°C ~ 85°C | Supplier Device Package: 16-SOIC | Voltage - Supply: 4.75V ~ 5.5V | Controller Type: Nonvolatile RAM24,900
4DB0232KC2AVG8RenesasDescription: FCCSP 7.50X3.00X1.20 MM, 0.50MM1,159
4DB0226KB0AVG8RenesasDescription: FCCSP 7.50X3.00X1.20 MM, 0.50MM653
4DB0226EMKB0AVG8RenesasDescription: IC DATA BUFFER FOR DDR4 FCCSP29
4DB0226EMKB0AVGRenesasDescription: IC DATA BUFFER FOR DDR4 FCCSP1,987
PM8650A1-FEIMicrochip TechnologyDescription: Memory Controllers Flashtec NVMe 3108 PCIe 8ch Dual-Port Flash Controller9,720
PM8088C1-F3GIMicrochip TechnologyDescription: Memory Controllers PM8015: SRCv 24x6G1,409
PM8628C1-F3EIMicrochip TechnologyDescription: IC PCIE FLASH CTRLR 16CH 1304FBG538
PM8607B-F3EIMicrochip TechnologyDescription: NVME20161,445

How to Choose Memory Controllers

A practical selection framework for Memory Controllers covering specifications, packaging, lifecycle, and sourcing on Octatronics.

  1. Define electrical and environmental requirements

    Start with the required function and operating conditions for Memory Controllers, then lock in critical parameters such as function, supply voltage, interface, package, and temperature grade. Match these against datasheet limits, not catalog summaries alone.

  2. Validate package and land pattern compatibility

    Confirm the Memory Controllers package matches your PCB footprint, pick-and-place constraints, and moisture sensitivity handling. Verify reel/tape or tube packaging for production.

  3. Check lifecycle, compliance, and alternates

    Review lifecycle status (Active, NRND, EOL), RoHS, and approved alternate sources for Memory Controllers before committing to high-volume builds. Use Octatronics cross-reference data when a drop-in replacement is needed.

  4. Compare manufacturers and request pricing

    Filter Memory Controllers by manufacturers such as Renesas and AMD/Xilinx, compare key specs side by side, then submit an RFQ with quantity, target delivery, and traceability requirements.

About Memory Controllers

Frequently Asked Questions

Octatronics can help source a wide range of Memory Controllers from major manufacturers worldwide, including active production parts, long-lead-time items, and hard-to-find components.

Yes. You can submit a single part number or upload a BOM with multiple parts. Our team will check stock, date code, lead time, and pricing for each item.

Availability depends on the specific part number and supplier source. For important orders, buyers can request packaging photos, labels, date code information, and traceability documents.

Yes. Octatronics supports sourcing for active, end-of-life, obsolete, and hard-to-find components through our global supplier network.

Please provide the part number, manufacturer, quantity, required date code, target price, delivery country, and whether original packaging or COC is required.

Articles & Technology

View All →
How to Choose Electronic Components for Reliable Hardware Design

How to Choose Electronic Components for Reliable Hardware Design

Learn how to choose electronic components for reliable hardware design, including specifications, lifecycle status, sourcing risks, quality checks, and BOM optimization.

Pin-to-Pin Replacement Parts: How to Check Compatibility Before Sourcing

Pin-to-Pin Replacement Parts: How to Check Compatibility Before Sourcing

When an original electronic component becomes obsolete, unavailable, or too expensive, a pin-to-pin replacement part can help avoid PCB redesign and keep production or repair projects moving. However, pin-to-pin compatibility does not automatically mean the part is a safe drop-in replacement. This guide explains how to check package, footprint, pinout, electrical ratings, thermal performance, timing behavior, firmware requirements, compliance status, and lifecycle risk before sourcing replacement parts. It also provides a practical checklist to help engineers, buyers, and maintenance teams reduce sourcing mistakes and verify compatibility before purchase.

How to Find Pin-Compatible Alternatives for Obsolete ICs

How to Find Pin-Compatible Alternatives for Obsolete ICs

Finding a pin-compatible alternative for an obsolete IC is not just about matching the package. It requires a structured review of pinout, footprint, electrical parameters, functional behavior, lifecycle status, sourcing reliability, and sample validation.

DDR6 RAM: What We Know So Far About Next-Generation Memory

DDR6 RAM: What We Know So Far About Next-Generation Memory

DDR6 RAM is the next planned generation of DDR memory technology after DDR5, designed to support higher bandwidth, improved efficiency, and future computing platforms with greater data movement requirements. Although DDR6 is not yet a mainstream commercial product, major memory manufacturers and platform developers are already preparing for the next stage of DRAM evolution.

IC Top Marking Codes Explained: How to Identify SMD Chips from Package Markings

IC Top Marking Codes Explained: How to Identify SMD Chips from Package Markings

IC top marking codes are abbreviated package markings used to identify semiconductor devices, especially small SMD chips that cannot fit a full part number. Buyers should use the marking as a starting point, then verify manufacturer logo, package, pin count, date code, lot code, datasheet, packing label, and supplier documentation. Official manufacturer marking tools and datasheets should be used before relying on third-party SMD code databases.

Circuit Board Component Identification: How to Identify PCB Components by Markings, Shape, and Codes

Circuit Board Component Identification: How to Identify PCB Components by Markings, Shape, and Codes

Circuit board component identification means recognizing PCB parts by their reference designators, physical appearance, body markings, polarity marks, package type, and electrical function. The fastest way to identify a component is to start with the PCB silkscreen, match the reference letter to a component type, inspect its shape and package, read any value or top marking, then confirm the result with a datasheet, schematic, BOM, or measurement tool. This guide explains how to identify common PCB components such as resistors, capacitors, inductors, diodes, transistors, MOSFETs, ICs, connectors, fuses, relays, crystals, and test points. It also includes practical examples, common marking codes, polarity clues, mistakes to avoid, and a replacement sourcing checklist.

DDR4 vs DDR5: Key Differences in Speed, Latency, Power, Capacity, and Compatibility

DDR5 is the newer memory standard, offering higher bandwidth, lower nominal operating voltage, improved module architecture, and better capacity scaling than DDR4. However, DDR4 remains widely used in existing PCs, embedded systems, industrial equipment, and cost-sensitive platforms. The best choice depends on your motherboard, processor, workload, budget, and long-term sourcing requirements.