회사 소식 Beyond Basic Pixels: Leveraging the LC7981 Controller for Advanced, Low-Overhead Industrial HMIs

Introduction: The Unseen Burden of the "Simple" Display
In the world of industrial Human-Machine Interfaces (HMIs) for test equipment, PLC interfaces, or diagnostic tools, engineers often face a critical trade-off. The need is for a display that shows more than just pre-defined characters: real-time bar graphs, custom icons, multi-field data screens, and interactive menus. The obvious path might be a color TFT, but this introduces complexity: faster MCUs, significant RAM for frame buffers, and complex graphics libraries.

There exists a strategic alternative that is often overlooked: a highly programmable monochrome graphic LCD module. The 2.96-inch 160x80 Graphic LCD Module, model SFBM16080YB-7371BN from Saef Technology Limited, powered by the LC7981 (or equivalent) controller, represents this alternative. It's not just a display; it's a co-processor for your user interface. This article is for engineers in Stuttgart, Munich, or Chicago who need sophisticated display functionality without the overhead of a full graphics subsystem.

Part 1: The Core Challenge – Dynamic Content on a "Static" Screen
Consider a typical industrial use case: a sensor calibrator. It needs to display a live numerical reading, a historical trend graph, a battery icon, a menu status bar, and unit indicators—all simultaneously, updating in real-time. On a basic dot-matrix display, this forces the host microcontroller (MCU) to continuously calculate and write raw pixel data for the entire graph and icons, consuming precious processing time and bandwidth.

• The Problem: MCU becomes bogged down in pixel-pushing, detracting from its primary function (sensor data acquisition, control logic).

Part 2: The LC7981 Controller: Your Display Co-Processor
The SFBM16080YB-7371BN elevates the solution by integrating the LC7981. Reviewing the extensive Function Specifications (Pages 8-14) reveals its capabilities:

1. Dual Display Modes (Character & Graphic): The controller natively manages both modes. You can define a custom character set (CGRAM) for icons (battery, signal strength, logos) and then place them on screen using simple character codes, just like text. Simultaneously, other screen areas can be in graphic mode for drawing arbitrary shapes or graphs.

2. Hardware Cursor & Bit Manipulation: Instructions like "Set Bit" and "Clear Bit" (Page 12) allow you to toggle individual pixels within a byte of display RAM by sending a single command. This is incredibly efficient for updating a single icon state (e.g., filling one bar of a battery icon) without rewriting the entire icon or surrounding pixels.

3. Hardware Screen Management: The controller handles display start address registers (Page 10). This enables hardware-level scrolling or the creation of multiple virtual screens in memory, with instant switching between them via a register write, not massive data transfers from the MCU.

4. Reduced Bus Burden: The 8080-series 8-bit parallel interface (/RD, /WR, CS) is straightforward and fast for 8-bit or 16-bit MCUs. The AC Timing Characteristics (Page 7) show relaxed timing (e.g., tWR min 80ns), making it easy to interface even with older or resource-constrained industrial microcontrollers without wait states.

Part 3: Implementation Roadmap: Building an Efficient HMI
How does this translate into a real design for a calibration tool or meter?

• Step 1 – Define the Layout: Partition your 72.0mm x 40.0mm viewing area (Page 4) into zones: a fixed header (character mode for titles), a main graphic area for the live waveform, and a footer with icons (character mode using CGRAM).

• Step 2 – Offload Graphics: Store the static UI elements (border, fixed labels, icon bitmaps) in the display's internal RAM during initialization. The MCU only needs to send this data once.

• Step 3 – Dynamic Updates: To update the live graph, the MCU calculates new points and uses block writes to the relevant graphic RAM area. To update the battery icon from 3 to 2 bars, it issues a single "Clear Bit" command for the specific pixel. This minimizes data traffic and MCU workload dramatically.

• Step 4 – Add Interactivity (The Modern Touch): A monochrome display doesn't mean a legacy interface. Saef Technology Limited can integrate a durable Resistive Touch Panel (RTP) over this display. The touch input, handled via a separate ADC or touch controller, provides coordinates. Your MCU firmware translates these coordinates into actions (e.g., "tap on the 'Save' icon character"), creating an intuitive, menu-driven HMI that feels modern while being built on a robust, low-power, and cost-effective display core.

Why This Matters for German & US Engineering
This approach aligns with core engineering values: efficiency, reliability, and longevity. The 5V logic level (VCC=+5.0V, Page 6) simplifies interfacing in legacy 5V systems still prevalent in industrial settings. The wide operating temperature range (-20°C to +70°C) and detailed Reliability Testing profile (Page 18) ensure suitability for harsh environments. The design reduces firmware complexity and MCU specifications, potentially lowering system cost and power consumption while increasing determinism—a critical factor in safety-related or mission-critical devices.

Conclusion: Choosing Intelligence Over Brute Force
The SFBM16080YB-7371BN is more than a component; it's a design philosophy. By leveraging the integrated intelligence of the LC7981 controller, engineers can create rich, responsive, and customized user interfaces that offload the host processor, simplify firmware, and enhance overall system reliability. In an era of increasing complexity, it represents a smart, elegant solution for robust industrial HMI design.

To explore the full set of display control instructions, timing diagrams, and electrical specifications, download the complete SFBM16080YB-7371BN Datasheet.pdf.