Agilent Technologies 667xA Status Byte Register, Service Request Enable Register, Output Queue

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Status Byte Register

Status Byte Register

This register summarizes the information from all other status groups as defined in the "IEEE 488.2 Standard Digital Interface for Programmable Instrumentation" standard. The bit configuration is shown in Table 4-1. The register can be read either by a serial poll or by *STB?. Both methods return the same data, except for bit 6. Sending *STB? returns MSS in bit 6, while poring the register returns RQS in bit 6.

The RQS Bit

Whenever the power supply requests service, it sets the SRQ interrupt line true and latches RQS into bit 6 of the Status Byte register. When the controller services the interrupt, RQS is cleared inside the register and returned in bit position 6 of the response. The remaining bits of the Status Byte register are not disturbed.

The MSS Bit

This is a real-time (unlatched) summary of all Status Byte register bits that are enabled by the Service Request Enable register. MSS is set whenever the power supply has at least one reason (and possibly more) for requesting service. Sending *STB? reads the MSS in bit position 6 of the response. No bits of the Status Byte register are cleared by reading it.

Determining the Cause of a Service Interrupt

You can determine the reason for an SRQ by the following actions:

Use a serial poll or the *STB? query to determine which summary bits are active.

Read the corresponding Event register for each summary bit to determine which events caused the summary bit to be set. When an Event register is read, it is cleared. This also clears the corresponding summary bit.

The interrupt will recur until the specific condition that caused each event is removed. If this is not possible, the event may be disabled by programming the corresponding bit of the status group Enable register or NTRPTR filter. A faster way to prevent the interrupt is to disable the service request by programming the appropriate bit of the Service Request Enable register.

Service Request Enable Register

This register is a mask that determines which bits from the Status Byte register will be ORed to generate a service request (SRQ). The register is programmed with the *SRE common command. When the register is cleared, no service requests can be generated to the controller.

Output Queue

The Output Queue is a first-in, first-out (FIFO) data register that stores power supply-to-controller messages until the controller reads them. Whenever the queue holds one or more bytes, it sets the MAV bit (4) of the Status Byte register. If too many unread error messages are accumulated in the queue, a system error message is generated (see Table 5-1 in "Chapter 5 - Error Messages"). The Output Queue is cleared at power on and by *CLS.

Initial Conditions At Power On

Status Registers

When the power supply is turned on, a sequence of commands initializes the status registers. For the factory-default *RST power-on state, Table 4-4 shows the register states and corresponding power-on commands.

54 Status Reporting

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Contents PROGRAMMING GUIDE GPIB DC POWER SUPPLIES Agilent Part NoMicrofiche Part No JulySafety Guidelines Printing HistoryContents GENERAL INFORMATIONREMOTE PROGRAMMING LANGUAGE DICTIONARYDescription of Subsystem Commands ERROR MESSAGES STATUS REPORTINGSCPI CONFORMANCE INFORMATION COMPATIBILITY LANGUAGEGeneral Information About this GuideDocumentation Summary User’s GuidePrerequisites for Using this Guide VXIplug&play Power Product Instrument DriversDownloading and Installing the Driver Accessing Online HelpGPIB Capabilities Of The Power Supply Remote ProgrammingIntroduction To SCPI ConventionsTypes of SCPI Commands SCPI MessagesStructure of a SCPI Message Common CommandsParts of a SCPI Message Figure 2-1.Command Message StructureMessage Component VOLT LEV PROT CURRTraversing the Command Tree Query IndicatorMessage Unit Separator Root SpecifierFigure 2-2.Partial Command Tree Active Header PathThe Effect of Optional Headers Moving Among SubsystemsIncluding Common Commands SCPI QueriesValue Coupling SCPI Data FormatsExamples Listening FormatsTable 2-2.Suffixes and Multipliers ClassControlling the Output Disable the outputEnable the output Programming Voltage and CurrentWriting to the Display Saving and Recalling StatesProgramming Status Programming the Digital I/O Port System ConsiderationsThe GPIB Address A direct primary address and a secondary address DOS Drivers Agilent BASIC ControllersSample Program Code Error HandlingProgramming Some Power Supply Functions Controller Using Agilent 82335A InterfaceProgramming Some Power Supply Functions continued 22 Remote ProgrammingProgramming Some Power Supply Functions continued 24 Remote Programming Related Commands Common CommandsSubsystem Commands Language DictionaryDescription Of Common Commands Figure 3-1.Common Commands Syntax DiagramDescription Meaning and Type0 to ESR? IDN?Related Commands Query SyntaxOPC? OPT?Power-onStatus Clear Device Initialization PSC 0 *PSCMeaning and Type DescriptionMeaning and Type STB? Bit Configuration of Status Byte RegisterTST? Description of Subsystem Commands Calibration CommandsABOR Figure 3-2.Subsystem Commands Tree DiagramCurrent Subsystem CURR CURR TRIGCURR PROT STAT CURRENT:LEVEL 200 MADisplay Subsystem DIG DATADISP Digital I/O Port Programming ChartDISP MODE DISP TEXTDISP TEXT DEFAULT MODE enclosed in either single ‘ or double quotesInitiate Subsystem Measure SubsystemINIT INIT:CONT MEAS CURR? MEAS VOLT?Output Subsystem OUTPOUTP PROT CLE OUTP PROT DEL 0 orOUTP REL OUTP REL POLOUTP REL 1 OUTP REL OFF OUTP REL POL NORMStatus Subsystem STAT PRESStatus Operation Registers STAT OPER?STAT OPER NTR STAT OPER PTR STAT OPER ENABSTATUS OPERATION ENABLE? Status Questionable Registers STAT QUES?STAT:QUES:COND? STAT QUES ENABSystem Commands STAT QUES NTR STAT QUES PTRSYST ERR? corresponding Questionable Event registerTrigger Subsystem SYST LANGSYST VERS? TRIGVoltage Subsystem TRIG SOURVOLT VOLT TRIG VOLTAGE LEVEL 200 MVCommand Summary VOLT:PROTCommand Summary CommandCommand Parameters Characteristics in the Operating Guide Programming ParametersParameter Agilent Model and ValuePower Supply Status Structure Register CommandsStatus Reporting Operation Status GroupTable 4-2.Bit Configurations of Status Registers SignalFigure 4-1.Power Supply Status Model MeaningQuestionable Status Group Standard Event Status GroupTable 4-3.Status Questionable Commands CLS *ESR?Service Request Enable Register Initial Conditions At Power OnDetermining the Cause of a Service Interrupt Status Byte RegisterThe PON Power-OnBit Servicing an Operation Status Mode EventTable 4-4.Default Power On Register States Caused ByMonitoring Both Phases of a Status Transition Adding More Operation EventsServicing Questionable Status Events Table 4-5.Generating RQS from the CC EventSCPI Command Completion DFI Discrete Fault IndicatorRI Remote Inhibit Techniques in ANSI/IEEE StdError Messages Power Supply Hardware Error MessagesCalibration Error Messages System Error Messages60 Error Messages SCPI Confirmed Commands1 SCPI Approved CommandsSCPI Conformance Information SCPI VersionNON-SCPICommands1 Compatibility Language ARPS Command1 Table B-1.ARPS CommandsSimilar SCPI Table B-1.ARPS Commands continued Table B-1.ARPS Commands continued Index 68 Index Page Agilent Sales and Support Office United StatesLatin America Canada
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668xA, 669xA, 667xA, 664xA, 665xA specifications

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