Many graphic (passive/active (TFT)) LCDs require multiple positive and negative supply voltages. At “power on” and “power off,” these bias voltages must be sequenced properly, along with the LCD’s data and control signals, to prevent damage to the LCDs. Figure 1 shows a circuit that can provide the needed sequencing.

The inverters are 74HC14 Schmitt types. The resistor-diode-capacitor networks form the delay circuits, with the diodes enabling different charging and discharging time constants. In the circuit, three programmable delay stages generate V₁, V₂, and V₃. Additional stages are possible for LCDs that require more than three supply voltages.

A supervisory IC generates the Power On Reset signal (active low nRESET), which disables all voltages and data/control signals to the LCD. At Power On Reset, the 74HC74 D flip-flops output and V_X is at logic low level. (Two flip-flops are used to prevent any Power On transition on EN from clocking the flip-flops.) Also, the capacitors are uncharged, and V₁, V₂, and V₃ = 0 V. This is the bias voltage’s Power Off state. A bus switch is used to disable the data and control signals to the LCD.

The EN signal should appear only after the LCD controller is initialized and the signals are active. (EN can also be connected to V_SYNC, so that when the LCD controller is initialized, LCD power is auto-enabled.) One STN passive-type LCD requires the power-on sequence to be: V_CC, then LCD data/control signals, then 22-V bias (with greater than 20ms delay in between). In this example, V₁ controls V_CC to the LCD using a positive voltage switch (Fig. 2a), V₂ controls the bus switch, and V₃ controls the 22-V bias using the negative voltage switch (Fig. 2b). The negative switch is designed specifically for 22-V bias switching. The MOSFET in the positive switch should have a logic-level threshold. Both switches use active-high power Enable signals.

When the supervisory processor pulses EN twice, V₁, V₂, and V₃ go high after the delay determined by time constants R2C1 (Δt₁), R4C2 (Δt₃), and R6C3 (Δt₅), respectively (Fig. 3). The diode connected to negative V_CC discharges the capacitor if V_CC dies off fast at Power Off. When power goes down, nRESET goes low (before the power fully goes down), and C1, C2, and C3 discharge with different time constants: R1C1 (Δt₂), R3C2 (Δt₄), and R5C3 (Δt₆), respectively.

Note that by adjusting the time constants, the 22-V bias is enabled only when power and data signals are applied, and data signals are enabled only after V_CC is applied. The resistance could be 10 to 47 kΩ, and the capacitors can be 0.1to 0.47µF, X7R types.

The data and control signals can be controlled by a bus switch, such as the CBT, FST, or PI5C families, or their 3.3-V counterparts. Or, they can be controlled with 8, 20, or 24-bit wide switches like the xxx245, 16210, and 16211.

Reprints

Printer-Friendly

Email this Article

RSS

Submit PlanetEE del.icio.us Digg Reddit Newsvine StumbleUpon Netscape Yahoo MyWeb Live Bookmarks Fark  Submit

Font Size

What's This?

Network-On-Chip Tools Arrive for The Masses Tackling System Design Challenges Through Early Verification ESL Tools Take Center Stage As Designers Move Up Parasitic Extraction Tool Targets Next-Generation Custom ICs Synopsys Jumps Into ESL-Synthesis Pool Verify Control Systems Before Committing To Hardware You're Using How Many FPGAs? Tool Up For The FPGA Blitz

1) Build A Smart Battery Charger Using A Single-Transistor Circuit (178 views today) 2) Hot Hands For Some Cool Rock: Motion Sensing Meets Audio Engineering (167 views today) 3) What's All This Transimpedance Amplifier Stuff, Anyhow? (Part 1) (83 views today) 4) GPS-Derived Grandmaster Clock Delivers Ultra-Precise Time And Frequency Sync (72 views today) 5) Downconverting Mixers Lower Power Consumption While Improving Performance (58 views today) ALL TOP 20

POST YOUR COMMENTS HERE Name: Email:
Your Comments: Enter the text from the image below Please refresh the page if you have trouble reading this text.