Diamond Systems PR-Z32-E-ST Base + Read Analog Input Status, STS Wait Dacbsy OVF Scanen

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Base + 3

Read

Analog Input Status

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Bit No.

7

 

6

5

4

 

3

2

1

0

 

 

 

 

 

 

 

 

 

 

 

Name

STS

 

SD

WAIT

DACBSY

 

OVF

SCANEN

G1

G0

 

 

 

 

 

 

 

 

 

STS

A/D status. 1 = A/D conversion or scan in progress, 0 = A/D is idle.

 

 

If SCANEN = 0 (single conversion mode), STS goes high when an A/D conversion is

 

started and stays high until the conversion is finished. If SCANEN = 1 (scan mode

 

enabled), STS stays high during the entire scan. After starting a conversion in

 

software, the program must monitor STS and wait for it to become 0 prior to reading

 

A/D values from Base + 0 and Base + 1.

 

 

 

 

SD

Single-ended / Differential mode indicator. 1 = SE, 0 = DI.

 

 

WAIT

A/D input circuit status. 1 = A/D circuit is settling on a new value, 0 = ok to start

 

conversion.

 

 

 

 

 

 

 

 

 

WAIT goes high after the channel register (Base + 2) or the gain register (Base + 3)

 

is changed. It stays high for 9 microseconds. The program should monitor this bit

 

after writing to either register and wait for it to become 0 prior to starting an A/D

 

conversion.

 

 

 

 

 

 

 

 

DACBSY

Indicates the DAC is busy updating (approx. 30 µS). 1 = Busy, 0 = Idle. Do not

 

attempt to write to the DAC (registers 6 and 7) while DACBSY = 1.

 

OVF

FIFO Overflow bit. This bit indicates that the FIFO has overflowed, meaning that the

 

A/D circuit has attempted to write data to it when it is full. This condition occurs when

 

data is written into the FIFO faster than it is read out.

 

 

 

When overflow occurs, the FIFO will not accept any more data until it is reset. The

 

OVF condition is sticky, meaning that it remains true until the FIFO is reset, so the

 

application program will be able to determine if overflow occurs. If overflow occurs,

 

then you must either reduce the sample rate or increase the efficiency of your

 

interrupt routine and/or operating system.

 

 

 

 

SCANEN

Scan mode readback (see Base + 3 Write above).

 

 

 

G1-G0

A/D gain setting readback (see Base + 3 Write above).

 

 

Prometheus CPU User Manual V1.44

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Contents Prometheus Table of Contents 22.4 22.2CPU DescriptionSystem Features FeaturesProcessor Section Analog Input Counter/TimersAnalog Output Digital I/OPrometheus Board Drawing O Headers Main I/O Connector J3Cable a Cable BCOM1 COM4 Connector Part NumbersLPT1 IR RX, IR TXInput Power J11 Ethernet J4 Output Power J12USB J5 Watchdog/Failsafe Features J6 Auxiliary Serial Port Connector J15IDE Drive J8 Floppy Drive J7Signal Name Definition Data Acquisition I/O Connector J14 Model PR-Z32-EA onlyJ2 PC/104 16-bit bus connector J1 PC/104 8-bit bus connector 11 PC/104 Bus ConnectorsJ10 System Configuration Jumper ConfigurationCmos RAM J6 Watchdog Timer & System Recovery System Resources System FeaturesCPU Chip Selects Console Redirection to a Serial Port Watchdog Timer Backup Battery Failsafe Mode / Bios RecoverySystem Reset Flash MemoryBios Settings BiosDOS Bios Download / Recovery Disk-On-Board Flash File Storage Initial SetupOperating System Formatting Life Cycle Management and Calculations Known LimitationsEthernet System I/OParallel Port Serial PortsInstalling an OS From a Floppy Drive onto a Flashdisk Module Booting to DOS From a Floppy DriveInstalling an OS from a Hard Disk onto a Flashdisk Module Data Acquisition Circuit Base Address Data Acquisition Circuitry I/O MAPBase + Write Function Read Function LSBAD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 Data Acquisition Circuit Register MapRegister Bit Definitions Command RegisterBase + Value = Base + 0 value + Base + 1 value Base + ReadBase + Write Not Used Read AD9 AD8Base + Read/Write Channel Register Base + Write Analog Input Gain STS Wait Dacbsy OVF Scanen Base + Read Analog Input StatusCKSEL1 CKFRQ1 CKFRQ0 Adclk Dmaen Tinte Dinte Ainte Base + Read/Write Interrupt / DMA / Counter ControlBase + Read/Write Fifo Threshold FT5 FT4 FT3 FT2 FT1 FT0DA7 DA6 DA5 DA4 DA3 DA2 DA1 DA0 Base + WriteBase + Read Channel and Fifo Status FD5 FD4 FD3 FD2 FD1 FD0DACH1 DACH0 Base + Write DAC MSB + Channel NoDA9 DA8 Base + Read Analog Operation StatusBase + Read / Write Digital I/O Control Register Base + Read / WriteDioctr Dira Dirch Dirb Dircl Dioctr =Base + Read/Write Counter/Timer D15 Base + Read/Write Counter/Timer D7Base + Read/Write Counter/Timer D23 Ctrno Latch Gtdis Gten Ctdis Cten Load CLR Base + Write Counter/Timer Control RegisterREV7 REV6 REV5 REV4 REV3 REV2 REV1 REV0 Base + Read Fpga Revision CodeData Acquisition Circuit Configuration Single-ended / Differential Inputs Analog Output ConfigurationUnipolar / Bipolar Inputs Input Range Resolution 1 LSB Analog Input Ranges and ResolutionOverview Input Range SelectionPerforming AN A/D Conversion LSB = inpbase MSB = inpbase+1 Perform an A/D conversion on the current channelInput voltage = A/D value / 32768 * Full-scale input range 15.A/D SCAN, INTERRUPT, and Fifo Operation LOW, High Prometheus A/D Operating ModesAinte Scanen Resolution Analog Output Ranges and ResolutionDescription LSB = Output voltage rangeREF 1 LSB 16.4 D/A Conversion Formulas and TablesConversion Formulas for Bipolar Output Ranges Generating AN Analog Output 18.1 A/D bipolar offset Analog Circuit Calibration18.2 A/D unipolar offset 18.3 A/D full-scaleDigital I/O Operation Counter 0 A/D Sample Control COUNTER/TIMER OperationCounter 1 Counting/Totalizing Functions Counter Command SequencesCounter Outpbase+15,0x01 Outpbase+15,0x81 Data Acquisition Specifications Using the Flashdisk with Another IDE Drive ConfigurationPower Supply Flashdisk Module23. I/O Panel Board Panel Board Top Side / External Use I/O Connectors Panel Board I/O ConnectorsLocation Type Description USB aJ12 pinout to/from DC/DC power supply Panel Board Power ConnectionsJ3 Pinout J5 USB J9 Pinout InstallationFlash Disk Programmer Board Photo No Cable No Description 25.I/O CablesCable Kit C-PRZ-KIT PL5 pin no PL5 Signal J25 pin no J25 Signal VGA Accessory BoardPL5 pin no DB15F pin no Signal Mounting Prometheus on a Baseboard Prometheus Connector Manufacturer Manufacturer Part NoLinks Website informationPage 28.PC/104 Mechanical Drawing

PR-Z32-E-ST, PR-Z32-EA-ST specifications

The Diamond Systems PR-Z32-EA-ST and PR-Z32-E-ST are pioneering solutions in the realm of embedded computing systems, designed to meet the challenging demands of various industrial applications. These boards harness advanced technologies and a comprehensive feature set to ensure exceptional performance, flexibility, and reliability.

At the heart of the PR-Z32 series is a robust processor architecture that combines efficiency with processing power. The systems are built around the Zynq-7000 SoC (System on Chip), which integrates a dual-core ARM Cortex-A9 processor with Xilinx FPGA technology. This hybrid architecture provides the ability to run complex algorithms and custom logic concurrently, making the boards ideal for applications requiring intense computational tasks such as image processing, data acquisition, and real-time control.

One of the main features of the PR-Z32-EA-ST and PR-Z32-E-ST is their versatility. Both variants support a wide range of I/O options, including USB, Ethernet, CAN, and serial interfaces. This range of connectivity allows for integrations with various sensors, actuators, and other peripheral devices, making it suitable for industrial automation, robotics, and IoT projects. The inclusion of multiple GPIO pins also enhances the capability of the boards to interface with additional hardware.

In terms of performance, the PR-Z32 series supports substantial amounts of on-board memory, which can be essential for applications requiring the storage and processing of large datasets. The configurations are often customizable, allowing users to select the appropriate amount of RAM and on-board flash memory for their specific applications.

Reliability is a critical characteristic of the Diamond Systems PR-Z32 series. The boards are built to withstand adverse environmental conditions, making them suitable for deployment in industrial environments. They are often designed to operate over a wide temperature range, ensuring functionality in both hot and cold climates. Additionally, the boards are compliant with various industry standards, assuring users of their robustness and durability.

Moreover, the PR-Z32-EA-ST and PR-Z32-E-ST support real-time operating systems (RTOS) and conventional operating systems such as Linux. This support provides developers with the flexibility to choose the best environment for their applications, whether they require real-time performance or full-fledged operating system features.

In conclusion, the Diamond Systems PR-Z32-EA-ST and PR-Z32-E-ST are formidable options for those seeking powerful, versatile, and reliable embedded computing solutions. With their advanced SoC architecture, flexible I/O options, extensive memory configurations, and environmental resilience, these boards are well-equipped to tackle the challenges of modern industrial applications.
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