SN74LVC828APWIn StockTexas Instruments
SN74LVC828APW is a 10-bit 3-state bus buffer/driver from Texas Instruments in the LVC logic family, featuring dual output enable and 50pF load capacitance support for high-speed bus interfacing. From $0.73 in stock, worldwide shipping.
- Manufacturer
- Texas Instruments
- Package
- Small Outline Packages
- Pin Count
- 24
- Lifecycle
- ACTIVE
- Datasheet
- SN74LVC828APW Datasheet PDF
- Category
- Integrated Circuit
- Price
- From $0.7316(MOQ 25)
- Temp Range
- -40.0°C to 85.0°C
- RoHS
- Compliant
- Lead Time
- 3–7 business days
- Shipping
- DHL Express · Worldwide
Key Features
- 10-bit 3-state bus buffer/driver with unidirectional data flow for high-speed bus interfacing
- Dual output enable (active-low) for flexible bus control and signal isolation
- LVC/LCX/Z family: operates at 1.65V–3.6V, compatible with 5V tolerant inputs
- 24-pin TSSOP (JESD-30 R-PDSO-G24) compact package for space-constrained designs
- 50pF load capacitance rating with JEDEC e4 RoHS-compliant green packaging
Applications
The SN74LVC828APW is widely used in microprocessor and microcontroller data bus expansion, enabling efficient data routing between multiple bus segments. It is ideal for memory interface buffering, FPGA I/O expansion, and communication backplane designs where 3-state control and low-voltage logic translation are required. Its dual output enable feature makes it suitable for arbitrated bus systems in industrial automation and networking equipment.
Specifications
| Pbfree Code | Yes |
| YTEOL | 15 |
| Additional Feature | WITH DUAL OUTPUT ENABLE |
| Control Type | ENABLE LOW |
| Count Direction | UNIDIRECTIONAL |
| Family | LVC/LCX/Z |
| JESD-30 Code | R-PDSO-G24 |
| JESD-609 Code | e4 |
| Load Capacitance (CL) | 50pF |
| Logic IC Type | BUS DRIVER |
| Max I(ol) | 0.024A |
| Number of Bits | 10 |
| Number of Functions | 10 |
| Number of Ports | 2 |
| Output Characteristics | 3-STATE |
| Output Polarity | INVERTED |
| Package Body Material | PLASTIC/EPOXY |
| Package Equivalence Code | TSSOP24,.25 |
| Package Shape | RECTANGULAR |
| Package Style | SMALL OUTLINE, THIN PROFILE, SHRINK PITCH |
| Packing Method | TUBE |
| Peak Reflow Temperature (Cel) | 260 |
| Power Supply Current-Max (ICC) | 0.01mA |
| Prop. Delay@Nom-Sup | 6.7ns |
| Propagation Delay (tpd) | 7.1ns |
| Qualification Status | Not Qualified |
| Supply Voltage-Max (Vsup) | 3.6V |
| Supply Voltage-Min (Vsup) | 1.65V |
| Supply Voltage-Nom (Vsup) | 3.3V |
| Surface Mount | YES |
| Technology | CMOS |
| Temperature Grade | INDUSTRIAL |
| Terminal Finish | Nickel/Palladium/Gold (Ni/Pd/Au) |
| Terminal Form | GULL WING |
| Terminal Pitch | 0.65mm |
| Terminal Position | DUAL |
| Time@Peak Reflow Temperature-Max (s) | 30 |
| Package | Small Outline Packages |
Compliance & Regulatory
| RoHS Status | Compliant |
| Lead-Free | Yes (Pb-Free) |
| Moisture Sensitivity Level | MSL 1 |
| ECCN | EAR99 |
| HTS Code | 8542.39.00.90 |
| Country of Origin | Malaysia |
Alternate & Equivalent Parts
Compatible alternatives and drop-in replacements for SN74LVC828APW:
Bus Driver, LVC/LCX/Z Series, 10-Func, 10-Bit, Inverted Output, CMOS, PDSO24
Bus Driver, LVC/LCX/Z Series, 10-Func, 10-Bit, True Output, CMOS, PDSO24
Frequently Asked Questions
What is the operating voltage range of the SN74LVC828APW?
The SN74LVC828APW operates from 1.65V to 3.6V supply voltage, making it ideal for low-voltage digital systems. Its inputs are 5V tolerant, allowing direct interfacing with 5V logic without level shifters.
How does the dual output enable work on the SN74LVC828APW?
The SN74LVC828APW features two active-low output enable pins (OE1 and OE2) that must both be low to enable the outputs. When either enable is high, all 10 outputs are driven to the high-impedance (3-state) condition, allowing multiple devices to share a common bus.
What package does the SN74LVC828APW come in and what are the alternatives?
The SN74LVC828APW comes in a 24-pin TSSOP (Thin Shrink Small Outline Package) with 0.65mm pitch. Functionally equivalent alternatives include the SN74LVC828ADWR in SOIC-24 package and the SN74LVC828ADBR in SSOP-24 format, offering flexibility for different PCB layout requirements.
What is the maximum propagation delay of the SN74LVC828APW?
The SN74LVC828APW offers a typical propagation delay of around 3.5ns at 3.3V supply with a 50pF load capacitance, making it suitable for high-speed bus buffering applications in systems operating up to several hundred MHz.
Related Guides
Ultra Low Power Microcontroller Comparison 2026: STM32L4 vs MSP430 vs MSP432 vs CC2640
Engineer-grade 2026 comparison of ultra-low-power MCUs — STM32L476, MSP430A139, MSP432P401R, CC2640F128 across standby current, active current, and battery life.
May 5, 2026
BOM Cost Reduction: 7 Strategies for Electronics Manufacturers in 2026
Practical 2026 BOM optimization playbook — 7 proven strategies, ranked by payback time and risk. With realistic per-unit savings and verification steps.
May 5, 2026
STM32F072C8T6 Pin-Compatible Alternatives 2026: Cheaper Drop-In Options Compared
Engineer-grade compatibility analysis for STM32F072C8T6 alternatives in 2026 — pin compatibility, firmware portability, cost and lead time for each option.
May 5, 2026
Top Microcontrollers for IoT 2026: ESP32 vs Arduino vs STM32 vs RPi Pico
The five IoT MCU platforms compared on 2026 pricing, lead time, and use case — ESP32-S3, Arduino, STM32F0, RP2040, TI CC2640/CC1352P.
May 5, 2026
Why Buy from FindMyChip
About Texas Instruments
Texas Instruments (TI) is a global semiconductor company headquartered in Dallas, Texas. TI designs and manufactures analog and embedded processing chips used in industrial, automotive, consumer, communications, and enterprise systems.
More from Texas Instruments
| Qty. | Unit Price | Ext. Price |
|---|---|---|
| 25+ | $1.0100 | $25.25 |
| 120+ | $0.9730 | $116.76 |
| 300+ | $0.9580 | $287.40 |
| 10000+ | $0.8732 | $8732.00 |
| 100000+ | $0.7316 | $73160.00 |
In Stock · 24h Response · Worldwide Shipping
Response within 24 hours · Worldwide shipping
“Their engineering team helped us find a pin-compatible alternative when our original MCU went EOL.”