Vector Delay - 2022.2 English

Vitis Model Composer User Guide (UG1483)

Document ID
UG1483
Release Date
2023-01-13
Version
2022.2 English

The Vector Delay block supports delay operation on vector type inputs.

Hardware notes: A delay line is a chain, each link of which is an SRL16 followed by a flip-flop.

Description

The Vector Delay block implements a fixed delay of L cycles.

The delay value is displayed on the block in the form z-L, which is the Z-transform of the block’s transfer function. Any data provided to the input of the block will appear at the output after L cycles. The rate and type of the data of the output is inherited from the input. This block is used mainly for matching pipeline delays in other portions of the circuit. The delay block differs from the register block in that the register allows a latency of only 1 cycle and contains an initial value parameter. The Vector Delay block supports a specified latency, but no initial value other than zeros. The figure below shows the Vector Delay block behavior when L=4 and Period=1s.

Figure 1. Vector Delay block behavior when L=4 and Period=1s

For delays that need to be adjusted during runtime, you should use the Addressable Shift Register block. Delays that are not an integer number of clock cycles are not supported and such delays should not be used in synchronous design (with a few rare exceptions).

Block Parameters

Open the Block Parameters dialog box by double-clicking the icon in your Simulink® model.

Basic tab
Parameters specific to the Basic tab are as follows:
Optional Ports
Provide synchronous reset port
Activates an optional reset (rst) pin on the block. When the reset signal is asserted the block goes back to its initial state. Reset signal has precedence over the optional enable signal available on the block. The reset signal has to run at a multiple of the block's sample rate. The signal driving the reset port must be Boolean.
Provide enable port
Activates an optional enable (en) pin on the block. When the enable signal is not asserted the block holds its current state until the enable signal is asserted again or the reset signal is asserted. Reset signal has precedence over the enable signal. The enable signal has to run at a multiple of the block 's sample rate. The signal driving the enable port must be Boolean.
Latency
Latency is the number of cycles of delay. The latency can be zero, provided that the Provide enable port check box is not checked. The latency must be a non-negative integer. If the latency is zero, the Vector Delay block collapses to a wire during logic synthesis. If the latency is set to L=1, the block will generally be synthesized as a flip-flop (or multiple flip-flops if the data width is greater than 1).
Super Sample Rate (SSR)
This configurable GUI parameter is primarily used to control processing of multiple data samples on every sample period. This block enables 1-D vector support for the primary block operation.
Implementation tab

Parameters specific to the Implementation tab are as follows:

Implement using behavioral HDL
Uses behavioral HDL as the implementation. This allows the downstream logic synthesis tool to choose the best implementation.

Other parameters used by this block are explained in the topic Common Options in Block Parameter Dialog Boxes.

Logic Synthesis using Behavioral HDL

This setting is recommended if you are using Synplify Pro as the downstream logic synthesis tool. The logic synthesis tool will implement the delay as it desires, performing optimizations such as moving parts of the delay line back or forward into block RAMs, DSP48s, or embedded IOB flip-flops; employing the dedicated SRL cascade outputs for long delay lines based on the architecture selected; and using flip-flops to terminate either or both ends of the delay line based on path delays. Using this setting also allows the logic synthesis tool, if sophisticated enough, to perform retiming by moving portions of the delay line back into combinational logic clouds.

Logic Synthesis using Structural HDL

If you do not check the Implement using behavioral HDL box, then structural HDL is used. This is the default setting and results in a known, but less-flexible, implementation which is often better for use with Vivado® synthesis. In general, this setting produces structural HDL comprising an SRL (Shift-Register LUT) delay of (L-1) cycles followed by a flip-flop, with the SRL and the flip-flop getting packed into the same slice. For a latency greater than L=33, multiple SRL/flip-flop sets are cascaded, albeit without using the dedicated cascade routes. For example, the following is the synthesis result for a 1-bit wide Vector Delay block with a latency of L=64.