TL16C2752 Series

1.8-V to 5-V Dual UART with 64-Byte FIFOs

Catalog

1.8-V to 5-V Dual UART with 64-Byte FIFOs

Part	Protocol	Voltage - Supply [Min]	Voltage - Supply [Max]	Supplier Device Package [x]	Supplier Device Package [y]	Supplier Device Package	Package / Case	Features	With False Start Bit Detection	With Modem Control	With Auto Flow Control	Mounting Type	Number of Channels	With IrDA Encoder/Decoder
Texas Instruments TL16C2752IFN	RS485	1.8 V	5 V	16.58	16.58	44-PLCC	44-LCC (J-Lead)	Internal Oscillator				Surface Mount	2
Texas Instruments TL16C2752FN	RS485	1.8 V	5 V	16.58	16.58	44-PLCC	44-LCC (J-Lead)	Internal Oscillator				Surface Mount	2

Catalog

1.8-V to 5-V Dual UART with 64-Byte FIFOs

Key Features

• Larger FIFOs Reduce CPU OverheadProgrammable Auto-RTSand Auto-CTSIn Auto-CTSMode,CTSControls the TransmitterIn Auto-RTSMode, RCV FIFO Contents, and Threshold ControlRTSSerial and Modem Control Outputs Drive a RJ11 Cable Directly When Equipment is on the Same Power DropCapable of Running With All Existing TL16C450 SoftwareAfter Reset, All Registers Are Identical to the TL16C450 Register SetUp to 48-MHz Clock Rate for up to 3-Mbps (Standard 16× Sampling) Operation, or up to6-Mbps (Optional 8× Sampling) Operation With VCC= 5 V NominalUp to 32-MHz Clock Rate for up to 2-Mbps (Standard 16× Sampling) Operation, or up to4-Mbps (Optional 8× Sampling) Operation With VCC= 3.3 V NominalUp to 24-MHz Clock Rate for up to 1.5-Mbps (Standard 16× Sampling) Operation, or up to3-Mbps (Optional 8× Sampling) Operation With VCC= 2.5 V NominalUp to 16-MHz Clock Rate for up to 1-Mbps (Standard 16× Sampling) Operation, or up to 2-Mbps (Optional 8× Sampling) Operation With VCC= 1.8 V NominalIn TL16C450 Mode, Hold and Shift Registers Eliminate the Need for Precise Synchronization Between the CPU and Serial DataProgrammable Baud-Rate Generator Allows Division of Any Input Reference Clock by 1 to (216– 1) and Generates an Internal 16× ClockStandard Asynchronous Communication Bits (Start, Stop, and Parity) Added to or Deleted From the Serial Data Stream5-V, 3.3-V, 2.5-V, and 1.8-V OperationIndependent Receiver Clock InputTransmit, Receive, Line Status, and Data Set Interrupts Independently ControlledFully Programmable Serial Interface Characteristics5-, 6-, 7-, or 8-Bit CharactersEven-, Odd-, or No-Parity Bit Generation and Detection1-, 1 =-, or 2-Stop Bit GenerationBaud Generation (DC to 1 Mbit/s)False-Start Bit DetectionComplete Status Reporting Capabilities3-State Output TTL Drive Capabilities for Bidirectional Data Bus and Control BusLine Break Generation and DetectionInternal Diagnostic CapabilitiesLoopback Controls for Communications Link Fault IsolationBreak, Parity, Overrun, and Framing Error SimulationFully Prioritized Interrupt System ControlsModem Control Functions (CTS,RTS,DSR,DTR,RI, andDCD)Available in 44-Pin PLCC (FN) or 32-Pin QFN (RHB) PackagesEach UART’s Internal Register Set May Be Written Concurrently to Save Setup TimeMultifunction (MF) Output Allows Users to Select Among Several Functions, Saving Package PinsAPPLICATIONSPoint-of-Sale TerminalsGaming TerminalsPortable ApplicationsRouter ControlCellular DataFactory AutomationLarger FIFOs Reduce CPU OverheadProgrammable Auto-RTSand Auto-CTSIn Auto-CTSMode,CTSControls the TransmitterIn Auto-RTSMode, RCV FIFO Contents, and Threshold ControlRTSSerial and Modem Control Outputs Drive a RJ11 Cable Directly When Equipment is on the Same Power DropCapable of Running With All Existing TL16C450 SoftwareAfter Reset, All Registers Are Identical to the TL16C450 Register SetUp to 48-MHz Clock Rate for up to 3-Mbps (Standard 16× Sampling) Operation, or up to6-Mbps (Optional 8× Sampling) Operation With VCC= 5 V NominalUp to 32-MHz Clock Rate for up to 2-Mbps (Standard 16× Sampling) Operation, or up to4-Mbps (Optional 8× Sampling) Operation With VCC= 3.3 V NominalUp to 24-MHz Clock Rate for up to 1.5-Mbps (Standard 16× Sampling) Operation, or up to3-Mbps (Optional 8× Sampling) Operation With VCC= 2.5 V NominalUp to 16-MHz Clock Rate for up to 1-Mbps (Standard 16× Sampling) Operation, or up to 2-Mbps (Optional 8× Sampling) Operation With VCC= 1.8 V NominalIn TL16C450 Mode, Hold and Shift Registers Eliminate the Need for Precise Synchronization Between the CPU and Serial DataProgrammable Baud-Rate Generator Allows Division of Any Input Reference Clock by 1 to (216– 1) and Generates an Internal 16× ClockStandard Asynchronous Communication Bits (Start, Stop, and Parity) Added to or Deleted From the Serial Data Stream5-V, 3.3-V, 2.5-V, and 1.8-V OperationIndependent Receiver Clock InputTransmit, Receive, Line Status, and Data Set Interrupts Independently ControlledFully Programmable Serial Interface Characteristics5-, 6-, 7-, or 8-Bit CharactersEven-, Odd-, or No-Parity Bit Generation and Detection1-, 1 =-, or 2-Stop Bit GenerationBaud Generation (DC to 1 Mbit/s)False-Start Bit DetectionComplete Status Reporting Capabilities3-State Output TTL Drive Capabilities for Bidirectional Data Bus and Control BusLine Break Generation and DetectionInternal Diagnostic CapabilitiesLoopback Controls for Communications Link Fault IsolationBreak, Parity, Overrun, and Framing Error SimulationFully Prioritized Interrupt System ControlsModem Control Functions (CTS,RTS,DSR,DTR,RI, andDCD)Available in 44-Pin PLCC (FN) or 32-Pin QFN (RHB) PackagesEach UART’s Internal Register Set May Be Written Concurrently to Save Setup TimeMultifunction (MF) Output Allows Users to Select Among Several Functions, Saving Package PinsAPPLICATIONSPoint-of-Sale TerminalsGaming TerminalsPortable ApplicationsRouter ControlCellular DataFactory Automation

Description

The TL16C2752 is a speed and functional upgrade of the TL16C2552. Since they are pinout and software compatible, designs can easily migrate from the TL16C2552 to the TL16C2752 if needed. The additional functionality within the TL16C2752 is accessed via an extended register set. Some of the key new features are larger receive and transmit FIFOs, embedded IrDA encoders and decoders, RS-485 transceiver controls, software flow control (Xon/Xoff) modes, programmable transmit FIFO thresholds, extended receive and transmit threshold levels for interrupts, and extended receive threshold levels for flow control halt/resume operation. The TL16C2752 is a dual universal asynchronous receiver and transmitter (UART). It incorporates the functionality of two independent UARTs: each UART having its own register set and transmit and receive FIFOs. The two UARTs share only the data bus interface and clock source, otherwise they operate independently. Another name for the UART function is asynchronous communications element (ACE), and these terms will be used interchangeably. The bulk of this document describes the behavior of each ACE, with the understanding that two such devices are incorporated into the TL16C2752. Functionally equivalent to the TL16C450 on power up or reset (single character or TL16C450 mode), each ACE can be placed in an alternate FIFO mode. This relieves the CPU of excessive software overhead by buffering received and to-be-transmitted characters. Each receiver and transmitter store up to 64 bytes in their respective FIFOs, with the receive FIFO including three additional bits per byte for error status. In the FIFO mode, selectable hardware or software autoflow control features can significantly reduce program overload and increase system efficiency by automatically controlling serial data flow. Each ACE performs serial-to-parallel conversions on data received from a peripheral device or modem and stores the parallel data in its receive buffer or FIFO, and each ACE performs parallel-to-serial conversions on data sent from its CPU after storing the parallel data in its transmit buffer or FIFO. The CPU can read the status of either ACE at any time. Each ACE includes complete modem control capability and a processor interrupt system that can be tailored to the application. Each ACE includes a programmable baud rate generator capable of dividing a reference clock with divisors of from 1 to 65535, thus producing a 16× or 8× internal reference clock for the transmitter and receiver logic. Each ACE accommodates up to a 3-Mbaud serial data rate (48-MHz input clock). As a reference point, that speed would generate a 333-ns bit time and a 3.33-=s character time (for 8,N,1 serial data), with the internal clock running at 48 MHz and 16× sampling. Each ACE has aTXRDYandRXRDY(viaMF) output that can be used to interface to a DMA controller. The TL16C2752 is a speed and functional upgrade of the TL16C2552. Since they are pinout and software compatible, designs can easily migrate from the TL16C2552 to the TL16C2752 if needed. The additional functionality within the TL16C2752 is accessed via an extended register set. Some of the key new features are larger receive and transmit FIFOs, embedded IrDA encoders and decoders, RS-485 transceiver controls, software flow control (Xon/Xoff) modes, programmable transmit FIFO thresholds, extended receive and transmit threshold levels for interrupts, and extended receive threshold levels for flow control halt/resume operation. The TL16C2752 is a dual universal asynchronous receiver and transmitter (UART). It incorporates the functionality of two independent UARTs: each UART having its own register set and transmit and receive FIFOs. The two UARTs share only the data bus interface and clock source, otherwise they operate independently. Another name for the UART function is asynchronous communications element (ACE), and these terms will be used interchangeably. The bulk of this document describes the behavior of each ACE, with the understanding that two such devices are incorporated into the TL16C2752. Functionally equivalent to the TL16C450 on power up or reset (single character or TL16C450 mode), each ACE can be placed in an alternate FIFO mode. This relieves the CPU of excessive software overhead by buffering received and to-be-transmitted characters. Each receiver and transmitter store up to 64 bytes in their respective FIFOs, with the receive FIFO including three additional bits per byte for error status. In the FIFO mode, selectable hardware or software autoflow control features can significantly reduce program overload and increase system efficiency by automatically controlling serial data flow. Each ACE performs serial-to-parallel conversions on data received from a peripheral device or modem and stores the parallel data in its receive buffer or FIFO, and each ACE performs parallel-to-serial conversions on data sent from its CPU after storing the parallel data in its transmit buffer or FIFO. The CPU can read the status of either ACE at any time. Each ACE includes complete modem control capability and a processor interrupt system that can be tailored to the application. Each ACE includes a programmable baud rate generator capable of dividing a reference clock with divisors of from 1 to 65535, thus producing a 16× or 8× internal reference clock for the transmitter and receiver logic. Each ACE accommodates up to a 3-Mbaud serial data rate (48-MHz input clock). As a reference point, that speed would generate a 333-ns bit time and a 3.33-=s character time (for 8,N,1 serial data), with the internal clock running at 48 MHz and 16× sampling. Each ACE has aTXRDYandRXRDY(viaMF) output that can be used to interface to a DMA controller.