SCLA057 November 2022 SN74AUP1G08 , SN74HCS08 , SN74HCS595 , SN74LVC1G08
For the purpose of this report, a simplified WLAN and Wi-Fi AP block diagram is used to illustrate the logic and translation use cases, see Simplified Block Diagram for WLAN and Wi-Fi access points. Each red block has an associated use-case document. Links are provided in Table 1-1 and Table 1-2. For a more complete block diagram, see the interactive online end equipment reference diagram for WLAN/Wi-Fi access point.
Each use case is linked to a separate short document that provides additional details including a block diagram, design tips, and part recommendations. The nearest block and use-case identifiers are listed to match up exactly to the use cases shown in the provided simplified block diagram.
| Nearest Block | Use-Case Identifier | Use Case |
|---|---|---|
| LED Driver | I/O Expansion | |
| LED Driver | Drive Indicator LEDs | |
| Non-Isolated POL Power | Power Good | Combine Power Good Signals |
| Nearest Block | Use-Case Identifier | Use Case |
|---|---|---|
| Processing | I2C | Translate Voltages for I2C |
| UART | Translate Voltages for UART |
Most, if not all, WLAN and Wi-Fi access points have multiple LED indicators on the front panel to help users see the current status of the device. These usually include power, internet connectivity, and physical ethernet port usage among other indicators.
Using shift registers with output registers like the SN74HCS595 it is easy to control any number of indicator LEDs while only using three outputs from the system controller. Two of the pins can even be shared with an existing SPI mode 0 bus if it is available in the system.
If using SPI bus, replace GPIO1 with SCLK and GPIO2 with SDO. The shift registers will always be loading data from the SPI clock to their internal registers, however the outputs will only change when GPIO 3 transition from low to high, so it is easy to control the 595 devices even with other devices on the SPI bus. Just sent 1 byte (8 bits) of data per shift register on the SPI bus to configure them, then pulse RCLK to save those values to the output registers and drive the indicator LEDs. This process can be done very quickly with the SN74HCS595, supporting clock speeds up to 110 MHz (typical) with a 5-V supply and 74 MHz (typical) with a 3.3-V supply. At 10 MHz (0.1 μs period), it only takes 1.6 μs to load 16 bits to the shift registers shown in Figure 1-2, and another 0.1 μs to pulse RCLK to move those values to the output registers.
For more details, please see the application report .
See more about similar use cases in the application report Designing with Shift Registers and the Logic Minute video Increase the Number of Outputs on a Microcontroller.
| Part Number | Automotive Qualified | Operating Voltage Range | Features |
|---|---|---|---|
| SN74HCS595-Q1 | ✓ | 2 V to 6 V |
8-Bit shift register with output registers HCS family logic has integrated Schmitt-trigger inputs allowing for slow input signals Up to eight LEDs per device Up to 70 mA total (35 mA max per channel) |
| SN74HCS595 | |||
| SN74HCT595-Q1 | ✓ | 4.5 V to 5.5 V |
8-Bit shift register with output registers HCT family logic includes TTL-compatible inputs to support 2.5-V or 3.3-V input signals Up to eight LEDs per device Up to 70 mA total (35 mA max per channel) |
| SN74HCT595 | |||
| SN74LVC244A-Q1 | ✓ | 1.65 V to 3.6 V |
Octal buffer/driver with 3-state outputs Up to eight LEDs per device Up to 100 mA total (50 mA max per channel) |
| SN74LVC244A | |||
| SN74AC244 | 2 V to 6 V |
Octal buffer/driver with 3-state outputs Up to eight LEDs per device Up to 200 mA total (50 mA max per channel) |
For more devices, browse through the online parametric tool where you can sort by desired voltage, output current, and other features.