High-Performance ALM and Interconnect

The Intel® Stratix® series of high-density, high-performance FPGAs leverage Intel's innovative adaptive logic module (ALM) logic structure to provide the most efficient logic fabric ever in any FPGA. Stratix® V FPGAs leverage an enhanced adaptive logic module and MultiTrack Interconnect to provide a highly efficient, high-performance FPGA.

Enhanced Adaptive Logic Module

Stratix V devices use an enhanced ALM to implement logic functions more efficiently. The enhanced ALM has eight inputs with a fracturable look-up table (LUT), two dedicated embedded adders, and four dedicated registers, as shown in Figure 1.

Figure 1. ALM block diagram.

The enhanced ALM also:

  • Packs six percent more logic compared to the previous-generation ALM found in Stratix® IV devices.
  • Implements select 7-input LUT-based functions, all 6-input logic functions, and two independent functions consisting of smaller LUT sizes (such as two independent 4-input LUTs) to optimize core utilization.
  • Provides 4 registers per 8-input fracturable LUT. This enables Stratix V devices to maximize core performance at higher core logic utilization and provide easier timing closure for register-rich and heavily pipelined designs.

The Intel® Quartus® software leverages the Stratix V ALM logic structure to deliver the highest performance, optimal logic utilization, and lowest compile times. The Intel Quartus software simplifies design reuse as it automatically maps legacy Stratix designs into the new ALM architecture.

The ALMs are routed with the MultiTrack Interconnect architecture, enabling an Intel Stratix series FPGA to implement high-speed logic, arithmetic, and register functions.

For more details on the logic architectures of previous Intel Stratix series FPGA families, see the respective handbook chapters from the device documentation section of our literature page.

Table 1 outlines the features and benefits of moving to the enhanced ALM structure in Stratix V FPGAs.

Table 1. ALM Features and Advantages

Available Resources Per ALM


8-Input fracturable LUT

    Can implement any 6-input logic function and certain 7-input functions and be fractured into independent smaller LUTs, such as two independent 4-input LUTs

    The Intel Quartus design software integrates this fracturability and optimizes it for performance, efficiency, power, and area

Two Embedded Adders

    Allows for two two-bit additions or two three-bit additions without any additional resources

    Operands can be generated from the same ALM and do not require any additional logic

Four Registers

    Optimal register-to-logic ratio to ensure device is not register-limited

    Abundance in registers for register-rich applications or pipeline designs for performance

Four Outputs

    Inputs of a single ALM can be divided between the two output functions, allowing wide input functions to run fast and narrow input functions to efficiently use remaining resources


    The core of an Intel Stratix series FPGA includes a logic array block (LAB), comprised of regular ALMs or configured as a simple, 640-bit dual-port SRAM block (known as a MLAB)

    MLABs can be configured as 64 x 10 or 32 x 20 simple dual-port SRAM blocks. The MLABs are optimized to implement filter delay lines, small FIFO buffers, and shift registers with maximum performance of 600-MHz clock speeds

Refer to the Logic Array Blocks and Adaptive Logic Modules chapter of the Stratix V device handbook for more information.

MultiTrack Interconnect

High-performance Intel Stratix series FPGAs leverage the MultiTrack Interconnect technology. This technology consists of continuous, performance-optimized routing lines of different lengths used for communication within and between distinct design blocks.

The MultiTrack Interconnect technology, shown in Figure 2, is used in Intel Stratix series FPGAs to:

  • Provide the industry's best connectivity with up to five times the logic in a single hop (compared to the competition.)
  • Provide more accessibility to any surrounding LAB with much fewer connections, thus improving performance and reducing power.
  • Avoid area congestion to provide better logic packing.

Figure 2. Stratix FPGA series MultiTrack Interconnect connectivity.


Reachable Logic Elements (LEs)