Intel 537EX manual +FRH=m, +FRS=m

Page 68

Fax Class 1 AT Commands

Table 24. Fax Mode Command Descriptions (Continued)

Command

Default

Description

 

 

 

 

 

Receive HDLC Data: The +FRH=<mod> command causes the modem to receive

 

 

HDLC-framed data using the modulation mode selected in <mod>. The modem then

 

 

delivers the next-received frame to the DTE.

 

 

If the modem detects the selected carrier signal with an HDLC flag, the modem sends

 

 

a ‘CONNECT’ result code to the DTE. If the modem detects a different signal, the

 

 

modem sends the ‘+FCERROR’ (fax connect error) result code to the DTE and returns

 

 

to command mode. Upon loss of carrier, the modem returns to command mode and

 

 

sends a ‘NO CARRIER’ result code to the DTE.

 

 

After receiving the HDLC flags, the modem strips away the flags and buffers the

 

 

received frames. The modem then transfers the received data to the DTE, starting with

 

 

the first non-flag byte and continuing through the last FCS byte. The DTE should

 

 

ignore the value of the FCS bytes. The modem also performs HDLC zero-bit deletion

 

 

and error checking.

 

 

After the FCS bytes are transferred, the modem marks the end of the frame with

 

 

<DLE><ETX> and reports the status of the frame reception to the DTE. If the frame

+FRH=m

none

was received correctly (FCS is correct), the modem returns a ‘OK’ result code. If the

frame was received in error (FCS is not correct, carrier lost, or data lost due to data

 

 

overflow), the DCE returns an ‘ERROR’ result code. The DTE should then discard this

 

 

frame.

 

 

After sending the status result code, the modem is ready to accept new commands

 

 

from the DTE.

 

 

The modem obeys the configured flow control from the DTE. If the DTE sends any

 

 

character to the modem other than DC1 or DC3 while the modem is in this mode, the

 

 

modem enters command mode and return an ‘OK’ result code.

 

 

After sending the result code indicating that frame reception is complete, the modem

 

 

continues to receive and buffer the data in the selected mode. If the DTE issues

 

 

another +FRH=<mod> command, the modem returns another ‘CONNECT’ result

 

 

code and continues with HDLC reception. If the DTE issues any command that

 

 

changes modulation, the DCE stops the receive process; the DCE then discards any

 

 

buffered data and processes the command.

 

 

Range: <mod> = 3

 

 

Refer to Table 23 on page 65.

 

 

 

 

 

Receive Data: The +FRM=<mod> command causes the modem to enter receive

 

 

mode using the modulation scheme specified in <mod>. <mod> may have the values

 

 

shown in Table 23 on page 65.

 

 

When the selected carrier is detected, the modem sends a ‘CONNECT’ result to the

 

 

DTE. If a different signal is detected, the modem sends a ‘+FCERROR’ (connect error)

 

 

result code to the DTE and returns to command mode.

 

 

After receiving the selected carrier, the modem transfers all received data patterns to

+FRM=m

none

the DTE as consecutive start-stop framed bytes, including leading marking conditions

 

 

or flags. The modem marks the end of the data stream with <DLE><ETX>.

 

 

Upon loss of carrier, the modem returns to command state and sends a ‘NO

 

 

CARRIER’ result code to the DTE.

 

 

NOTE: If the modem is on-hook, then the modem always returns an ‘ERROR’

 

 

message to the DTE after receiving the +FRM=<mod> command.

 

 

Range: <mod> = 24, 48, 72, 73, 74, 96, 97, 98, 121, 122, 145, 146

 

 

Refer to Table 23 on page 65.

 

 

 

 

 

Wait for Silence: The +FRS=<TIME> command causes the modem to send an ‘OK’

 

 

result code to the DTE when silence has been detected on the line for the amount of

 

 

time specified. The value <TIME> is in 10 ms intervals. The command terminates

+FRS=m

none

when the required amount of silence has been detected on the line or the DTE sends

 

 

the modem another character that is discarded. In either event, the DTE returns the

 

 

‘OK’ result code.

 

 

Range: <TIME> = 1–255 (10 ms)

 

 

 

NOTE: An asterisk (*) denotes the factory-default setting.

68

536EX Chipset Developer’s Manual

Intel Confidential

Page 67 Page 69
Image 68
Page 67 Page 69
Contents 537EX Chipset Developer’s ManualIntel Confidential Contents Figures Tables 001 Initial release Revision HistoryDate Revision Description Introduction Controllerless Modem Driver OverviewWindows 95 and Windows V.90/V.92 and V.34 Data Modes TapiUnimodem Intelsdb.VXDModem Connection Overview AT Commands Overview DTE-to-DCE Data Rates for Each ModeDCE-to-DCE Data Rates for Each Mode DCE-to-ISP Data Rates for V.90 ModeSending Commands Delayed CallDTE-Modem Data Rate Response Codes Numeric TextCommand Function AT Escape SequencesDial Modifier Dialing digitsData Mode Command Summary Command Function Default Range Reported By &VnIntel Confidential Intel Confidential Intel Confidential +EB +ESA+ESR +ETBM44/V.42/V.42 bis MNP Command Summary Processes flow control characters and passes to local Fax Identity Command Summary Fax Class 1 Command SummaryResponse Hex Code Function IS-101 Voice Command SummaryVoice DTE→DCE Character Pairs Voice DTE →DCE Character Pairs Voice DTE←DCE Character PairsDEL ESCRegister Function Default Range Units Reported by &Vn Dial ModifiersRegister Summary AsciiRegister Function Default Range Units Modem Setup Host Modem Response Command Using AT Commands to Access the S-Registers Sn?, Sn=x, ?Modem Responses and Command Echo En, Vn, Xn, Wn, Qn DTE Disable EnableData Reporting Wn Mapping Resets and then configures the modem to Nvram user profile Product Identification Information AT Commands Product InformationEstablishing a Modem Connection A, D, DS = n, S0 Modem-to-Modem Connection Data Rates Online Command Mode Escape Codes, OnHanging Up Hn, S10, Zn, &D2 Intel Confidential Modem-on-Hold Incoming Voice Call in Data Mode Modem-on-Hold Initiating a Voice Call in Data Mode Intel Confidential Supported Modulation Types Carrier DescriptionDiagnostic Testing S18, &Tn Local Analog Loopback AT&T1Local Analog Loopback With Self-Test AT&T8 Local Modem or Test ModemLicensing Requirements for Hayes Escape Sequence AT Escape SequencesTime-Independent Escape Sequence Example Hayes* Escape Sequence Data Mode Command DescriptionsCommand Default Description Previously stored in the Nvram with the AT&Zn=x command Host in either online or off-line command modeEcho disabled Echo enabledSn=x ATI2DTE Command Modem dials a telephone number touch tone dialingNumeric or verbose form Numeric formDisconnecting Subsequent commands to be ignoredResets the modem and recalls user profile DCD or Rlsd signalAT&V0 Active ProfileStored Profile Telephone NumbersS-register configurations into the Nvram user profile ‘n’ Command to see the stored telephone numberSelect profile = 0-9 a B C D # * T P R W @Command Default Indication Definition+EB CRC generation and checking disabled Nrzi encoding and decoding disabledSecondary channel operation, and vice versa 12/V.34+ESR +ETBM+GMR +GSN+IFC +ILRR=m+MS command description +MA? will display a list of enabled alternative modulations= carrier,carrier,…carrier If +MS = ,0,, no alternative modulations will be availableCarrier Description BELL103BELL212 +MS=m See ‘m’+PHSW= +PMHFValue Description +PMHRConjunction with the +PSS command Enable Short Phase 1 and Short PhaseEnable Short Phase Disable short Phase 1 and Short PhaseMode Features Operating Modes44/V.42/V.42 bis and MNP Data Modem Command Descriptions +ES Settings Answer ModemResulting +ES Connection Types +ES=1, 0 +ES=4, 4 +ES=3, 0 +ES=3, 2\Bn \Kn +DR=m Direction+DS=m Max string3768 +EFCS=mDisplay messages when +ER = Decimal value and the format is as follows+ER=m +ER LapmSetting is ignored if origrqst=6 Control during non-error control operationNon-error control operation +ES=mFax Identity Commands Fax Class 1 CommandsFax Identity Command Descriptions +FMFR?/+FMIMod Selection Table Value Modulation Speed bps30 Hdlc Frame Format Class 1 DTE-Generated Hdlc Frame Information AT+FTH=mod+FCLASS Fax Mode Command Descriptions+FCLASS? +FRH=m +FRS=m+FTH=m IS-101 Voice Mode AT Commands Relay Control Voice Mode Command DescriptionsDtmf Detection Reporting +FLO=m Enable report Function +VDR=m See ‘m’Defaults = ‘C’, BB860980, BFE63883, BB863EE0 Caller ID report Command Reserved Distinctive ringing AllEvent Description +VEM=m See ‘m’HEX Digit Location EIGHT-DIGIT HEX Code B B 8 6 3 E EEX Value BIT Value Event +VIP Local telephone, or speaker128 Nominal transmit level +VLS=m Preassigned Voice I/O LabelsLabel Primitive Code Description Voice I/O Primitive CodesRelay/Playback Control +VRX +VSD=m See ‘m’+VSM=? command to obtain supported sampling rates 141 AD3 3-bit Adaptive differential pulse code modulation+VSM=m Range 4800, 7200, 8000, and 11025 samples/secondCml SerialHard Disk CompressionFactory default is ‘0’ 100 Default value 1 second100 Range 5-255 units of 0.01 secondsDual tones may be sent using the following format +VTS=m NoneSpecified by +VTD=m This sends a 500 ms period of silenceCommand Default Description Register Command Descriptions S10 S16 Range Seconds Default 0 secondsEscape sequences S21 S22 118S25 S30Modem exits sleep mode whenever the host reads or writes to Modem or when a ring signal is detectedSleep mode is disabled by setting S33 to ‘0’ Inactive state whenCaller ID Tags for Formatted Reporting Tag DescriptionRing Uart Emulation in the Controllerless Modem Uart Emulation in Intelsdb.VxDRBR UartTHR Parallel Host Interface Uart Register Bit Assignments Modem Status Register MSR Uart Register DefinitionsScratch Register SCR Bit Framing error OE Overrun Error-Not supportedLine Status Register LSR StackIER Interrupt Enable register Procedure is as followsModem Control Register MCR Line Control Register LCRFifo Control Register FCR BitID1 ID0 Interrupt Identity Register IIRInterrupt Control Functions Interrupt Enable Register IER ID bit 2 for Fifo modeTransmitter Holding Register THR Dlab =Receiver Buffer Register RBR Divisor Latch Registers DLM and DLLProgrammable Data Rates Data Rate Divisor Number Divisor Latch HexFifo Interrupt Mode Operation Fifo Polled Mode Operation16C550A Uart Fifo Operation 102536EX Chipset Developer’s Manual 103

537EX specifications

The Intel 537EX is a powerful and innovative embedded processor designed for a range of applications, particularly in the fields of industrial automation, telecommunications, and transport management systems. This processor is a member of Intel's embedded product line, tailored specifically to meet the demands of systems that require high reliability and long lifecycle support.

One of the main features of the Intel 537EX is its multi-core architecture, which enables efficient parallel processing capabilities. This allows for the execution of multiple tasks simultaneously, significantly improving overall system performance. The processor also incorporates Intel’s advanced power management technology, which ensures that the device consumes energy efficiently, enhances thermal performance, and prolongs the lifespan of the system.

The Intel 537EX supports a range of connectivity options, including high-speed Ethernet and Serial ATA interfaces. This ensures that it can easily integrate into existing systems, seamlessly supporting applications that require robust data transfer capabilities. Additionally, the processor is equipped with multiple I/O ports, facilitating the connection of various peripherals and sensors, which is crucial in industrial applications.

One of the standout technologies within the Intel 537EX is its support for hardware virtualization. This feature allows for the creation of multiple virtual environments within a single physical structure, optimizing resource utilization and enhancing system flexibility. Additionally, Intel’s integrated security technologies provide a significant layer of protection against potential threats, ensuring that embedded systems remain secure.

Another characteristic of the Intel 537EX is its extensive software support, which includes compatibility with various operating systems and development environments. This versatility makes it an attractive choice for developers looking to build or upgrade their embedded systems. With access to Intel's comprehensive software tools, developers can quickly optimize applications to take full advantage of the processor's capabilities.

The Intel 537EX also boasts excellent thermal performance, allowing it to operate efficiently in harsh environments. This is crucial for embedded applications in industrial settings where temperature fluctuations are common. Overall, the Intel 537EX is engineered to deliver high-performance processing power, superior connectivity, and enhanced security, solidifying its position as a reliable choice for demanding embedded applications.
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