External Memory Interfaces Agilex™ 7 F-Series and I-Series FPGA IP User Guide

ID 683216
Date 9/19/2024
Public
Document Table of Contents

7.4.2. Reference Stackup

This topic illustrates the reference stackup on which EMIF routing design guidelines are based.

It is important to understand that trace geometry such as width, thickness, and edge-to-edge spacing, and the distance to reference planes, all impact trace impedance and crosstalk levels.

Table 147.  Reference stackup details
Layer Type Thickness
SM TOP 0.5
L1 signal 1.8
D1 prepreg 2.7
L2 gnd/power 1.2
D2 core 4.0
L3 signal 1.2
D3 prepreg 6.3
L4 gnd/power 1.2
D4 core 4.0
L5 signal 1.2
D5 prepreg 6.3
L6 gnd/power 1.2
D6 core 4.0
L7 signal 1.2
D7 prepreg 6.3
L8 gnd 1.2
D8 core 4
  Power 1.2
  prepreg 6.3
  power 1.2
  core 4
  gnd 1.2
  prepreg 6.3
  power 1.2
  core 4
L9 gnd 1.2
D9 prepreg 6.3
L10 signal 1.2
D10 core 4.0
L11 gnd/power 1.2
D11 prepreg 6.3
L12 signal 1.2
D12 core 4.0
L13 gnd/power 1.2
D13 prepreg 6.3
L14 signal 1.2
D14 core 4.0
L15 gnd/power 1.2
D15 prepreg 2.7
L16 signal 1.8
SM BOT 0.5
  Total 120.1
Figure 154. Reference trace geometries

The reference stackup height is selected to be 120 mil to cover maximum signal via coupling (110mil) in simulation while extracting EMIF design guideline. Intel® recommends that board designers do not exceed 110mil signal via coupling (stripline routing on inner layers) in the EMIF layout PCB design.

If the PCB stackup exceeds 120 mil in height, Intel® recommends routing EMIF signals on upper layers, not to exceed more than 110 mil of signal via coupling.

The reference stackup materials in the above figure are selected as FR4, to represent worse-case signal loss in design phase simulation. In case of low-loss materials, the maximum end-to-end routing length shall be larger than the recommended end-to-end routing length in the design guidelines; however, you must perform time-domain channel simulation to ensure that timing requirements are met.

The Intel® Agilex™ 7 F-Series and I-Series family pin floorplan is a HEX pattern with 1mm pitch. The following figure shows an example of routing for an IO12 (one-byte data) on PCB within FPGA fan-out region.

Figure 155.  Intel® Agilex™ 7 F-Series and I-Series 1mm HEX pin pattern/floorplan and recommended routing for one byte of data (IO12)

The following general notes apply to the EMIF routing guidelines for QDR-IV topologies:

  • All spacing requirements are the minimum requirement to be met on PCB in EMIF routing guideline table.
  • Breakout (BO1/BO2) spacings have two different values in guideline tables. The first value represents minimum spacing between two signals routed as a pair (tightly coupled signals); this value is marked as A (5 mil) in the above figure. The second value represents minimum spacing between two pairs, and is marked as B (17 mil) in the above figure.
  • Main route (M) spacings have both value in mil and formula. In formula, h represents the trace-to-nearest-reference-plane height or distance. In cases using a stackup different than the reference stackup, board designers shall use formula to calculate the correct spacing requirements.
  • There is no differential impedance target for CLK nor QK/DK. Board designers shall follow single-ended impedance target and keep the signals within the pair closely coupled, within 3-4 mil spacing. For information on QK/DK and CLK/CLKB, refer to Skew Matching Guidelines for QDR-IV Configurations .
  • In guideline tables, SL stands for stripline routing recommendation and US stands for upper surface (Microstrip) routing recommendation.
  • The trace width value/geometry in guideline tables stands for trace designed for target impedance based on the reference stackup. This trace geometry shall be designed based on actual stackup and target impedance in guideline table.
  • In guideline tables, BO1 and BO2 represent fan-out routing lengths. M stands for out of fan-out (PCB main) routing lengths