Skip to end of metadata
Go to start of metadata

You are viewing an old version of this page. View the current version.

Compare with Current View Page History

« Previous Version 5 Next »

Important information

This document applies exclusively to the configuration of the NG-LARGE FPGA referenced NX1H140TSP.

For other NanoXplore chips, please refer to the associated documentation.

Introduction to NG-LARGE Configuration

NX1H140TSP is configured by loading the bitstream into internal configuration memory using one of these following modes:

  • JTAG,

  • Slave Parallel 8 bits,

  • Slave Parallel 16 bits,

  • Slave SpaceWire, compliant ECSS-E-ST-50-12C link,

  • Master SPI, compliant with SPI JESD68.01

WARNING: changing MODE value while RST_HARD_N is unasserted is strictly forbidden.

Bitstream size

This NX1H140TSP bitstream size depends on the amount of logic resources used by the application, the number of initialized Flip-flops and the number of user Core RAM and Core Register Files to be initialized.

Maximum user logic configuration (100%)

24.43Mb

Medium configuration (70%)

17.10Mb

Small configuration (50%)

12.22Mb

D-Flip-Flop initialization (1) (129024)

1b/D-Flip-Flop

Core RAM initialization (2) (192 instances)

96.06Kb/RAM block

Core Register File initialization (2) (672 instances)

3.03Kb/Register File

CMIC

64.15Kb

Total

44.53Mb

  1. In a typical design the user can give – or not - an initial value to Flip-Flops at power-up. Reducing the number of initialized Flip-Flops contributes to reduce the bitstream size.

  2. Core RAM and/or Core Register file can also be initialized – or not - at power-up. Reducing the number of initialized memories contributes to reduce the bitstream size.

Most applications do not require to initialize all memories.

These numbers are just estimations.

The actual size can be determined only by running the mapping software.


Configuration Memory Integrity Check (CMIC)

The CMIC is an embedded engine performing automatic verification and repair of the configuration memory.

A CMIC reference memory is initialized during the bitstream download process with reference data computed by the NanoXmap software.

Once the initialization is done, the CMIC engine can be periodically activated to perform the following sequence:

1. Read configuration data

2. Calculate signature

3. Compare the signature with CMIC reference

4. If a mismatch is detected:

a. Calculate faulty address (BAD @) and faulty bit location

b. Read DATA[BAD @]

c. Repair flipped bit

d. Write DATA[BAD @]

For further information, please refer to the NX1H140TSP CMIC Application note.

Device configuration details

Purpose of NX1H140TSP configuration

NX1H140TSP chips are SRAM-based FPGAs. To achieve user-defined functionality their configuration bitstream must be downloaded first.

NX1H140TSP chips configuration modes summary

NX1H140TSP chips are always accessible through JTAG, and also support several configuration modes.

At power-up, MODE [2:0] pins state defines the configuration mode.

RST_HARD_N is a dedicated input pin that allows to reset the configuration engine, and launches the configuration process after RST_HARD_N is released. (It can’t be used to reset the FPGA user’s logic).

MODE [2:0]

Configuration mode

000 0x0

Master Serial SPI

001 0x1

Master Serial SPI with VCC control

010 0x2

Slave Spacewire

011 0x3

JTAG (reserved)

100 0x4

Slave Parallel 8-bit

101 0x5

Slave Parallel 16-bit

110 0x6

Reserved

111 0x7

Test mode

Table: NG-LARGE NX1H140TSP configuration modes

Configuration modes usage

JTAG configuration channel is always active regardless the selected configuration mode. JTAG accesses while the configuration interface is active are not recommended (risk of conflict with the bitstream manager operation and render ineffective the bitstream manager)

In slave modes (SpaceWire, Slave Parallel 8 or Slave Parallel 16), NX1H140TSP chip must be fed its bitstream through the selected interface.

In Master Serial SPI modes, NX1H140TSP chip automatically fetches its bitstream from the external memory (SPI or SPI with Vcc control) after RST_HARD_N is released.

Prog bank pins state during and after configuration

According the selected configuration mode, each of the prog is “multi-usage”. Some of the active pins must be required for correct configuration, and some other pins must be left unconnected. In addition, some prog bank pins can be configured as additional user’s I/O, providing that the supported I/O standard is:

  • LVDS with external impedance adaptation for the dedicated SpaceWire pins.

  • LVCMOS_3.3V for the other prog pins (with 60 mA output drive for the outputs, and 10K to 40K default Pull-Up)

The prog bank pins that are not used or activated by the selected configuration mode are configured as High-Z during the configuration. After the configuration they stay configured as High-Z if not used, or take the user’s defined functionality.

JTAG input pins (TRST, TMS, TDI) get internal default Pull-Up (10K to 40K).

User’s I/O pins state during and after configuration

Before reset, I/Os state are undetermined.

During the configuration process, all user’s I/Os are configured as High-Z with an internal 10K to 40K default Pull-Up.

After configuration the user I/O pins behaves as defined by the bitstream.

Internal default Pull-Up is set on single ended inputs.

NX1H140TSP chips prog interface pin list

The user must provide the 3-bit MODE value to select the configuration mode. In addition, the internal configuration engine requires an external reset signal (RST_HARD_N). RST_HARD_N must be asserted (low) during at least 3 microseconds. When RST_HARD_N is de-asserted, the configuration process starts after up to 3 us delay, according the MODE bits settings.

WARNING: changing MODE value while RST_HARD_N is unasserted is strictly forbidden (undefined behavior).

Depending on the selected configuration MODE, some prog bank pins are activated during the process. Some other remain as inputs with internal Pull-Up during the configuration process.

In addition, some prog bank pins can be used as auxiliary user defined I/Os after completing the configuration.

The next table summarizes the list of pins that can be affected during the configuration process.

Grp

Name

I/O

Description

GLOBAL

MODE(2:0)

I

Input pins sampled at power-up. MODE(2:0). They define the configuration mode to be used for NG-LARGE configuration.

MODE(2:0) cannot be changed when RST_HARD_N = ‘1’

ID(3:0)

I

Device Identification. It must comply with the bitstream device id to allow access bitstream loading.

FABRIC_USER(3:0)

I

Additional IO for user. FABRIC_USER[0] can be connected to low-skew network.

CLK

I

Always required. Can be routed externally to CLK_OSC 100MHz internal oscillator (except in Master SPI modes) or to an external clock in the range [0MHz;100MHz].

RST_HARD_N

I

Mandatory input. When low, it resets the internal configuration engine. RST_HARD_N must be low at least during 3 microseconds to ensure a proper configuration engine reset. When RST_HARD_N goes high, the configuration starts after up to 3 additional microseconds.

RST_SOFT_N

I

It only resets internal configuration registers but does not apply a reset on the configuration memory.

READY

O

Goes high when the configuration is complete (the FPGA enters in user’s mode)

TRIGGER

O

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated TRIGGER_MASK.

ERROR

O

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated ERROR_MASK.

POK

O

Goes high when VDD1V2 Core and VDD2V5A Analog Supply are on.

Slave Parallel 16/8

CS

I

Active high Chip Select input. Used in Slave Parallel 16/8 mode. The master can write or read to/from the configuration engine when CS is high during a CLK rising edge.

TYPE[1:0]

I

2-bits control input. Used in Slave Parallel 16/8 mode. It indicates the type of access:

0b00: ADDR_DEBUG

0b01: READ_DEBUG

0b10: WRITE_DEBUG

0b11: WRITE_CONF

DATA_OE

O

Active high output. Used in Slave Parallel 16/8 mode. It is a data valid signal for reading operations.

D(15 :0)

I/O

16-bit data bus used in Slave Parallel 16/8 mode to write the bitstream and/or read internal NG-LARGE internal state values. In case of Slave Parallel 8, only the first 8 LSB are used.

Master Serial SPI

D(8)

O

Used in Master Serial SPI and Master Serial SPI with Vcc control, as CS output to the external SPI Flash memory.

D(9)

O

Used in Master Serial SPI and Master Serial SPI with Vcc control, as clock output to the external SPI Flash memory.

D(10)

I

Used in Master Serial SPI and Master Serial SPI with Vcc control, as data input (MISO) from the external SPI Flash memory.

D(11)

O

Used in Master Serial SPI and Master Serial SPI with Vcc control, as data output (MOSI) to the external SPI Flash memory (while writing a new bitstream into the SPI Flash.

D(12)

I

Configured as input (with internal Pull-Up) during the configuration. Can be configured as, user’s I/O available after completing the configuration.

D(13)

I/O

Configured as input (with internal PullPup) during the configuration in Master Serial SPI

Configured as high level output during the configuration in Master Serial SPI with Vcc control.

Can be configured as user I/O available after completing the configuration.

D(14)

I/O

D(15)

I/O

SpaceWire

DIN_P

I

SpaceWire interface is available after completing the configuration in Master Serial SPI, Master Serial SPI with Vcc control or Slave Parallel 8 o 16-bit modes.

If SpaceWire is used for the configuration, it can’t be used for other purpose than the configuration.

DIN_N

I

SIN_P

I

SIN_N

I

DOUT_P

O

DOUT_N

O

SOUT_P

O

SOUT_N

O

JTAG

TCK

I

JTAG CLK

TMS

I

JTAG TMS

TDI

I

JTAG TDI

TRST_HARD_N

I

JTAG TRST_HARD_N

TDO

O

JTAG TDO

Table: Configuration related pins

Detailed configuration modes

SPI Modes

On board SPI flash memory programming:

For Master Serial modes, the on-board flash memory programming operation requires changing the MODE[2:0] into Slave mode to ensure the accessibility to the flash.

The NX1H140TSP chip may then be configured through JTAG with a dedicated design to program the memory with the user data, also transmitted by JTAG. NxBase2 provides such design and commands to program a given list of SPI flash memories. Please refer to NanoXplore_NxBase2_User_Manual.

Endianness

The bitstream must be sent by 32bits words with less significant byte first. Each byte must be sent with most significant bit first.

As an example, 0x12345678 is the first word of each bitstream. It must be sent as follows:

Bistream manager clock

In Master SPI or in Master SPI + Vcc control, only an external clock can be used to connect to CLK IO.

Do not loop CLK_OSC to CLK in these modes.

Master Serial SPI configuration details:

The next figure shows a suggestion of schematic to implement the Master Serial SPI configuration, then the pin list table describes the behavior of the prog bank pins when this mode is selected.

Master Serial SPI Mode

Prog bank (INTERFACE) pins used and/or impacted by configuration

Group

Pin name

I, O or I/O

User I/O

During configuration

Required

Impacted

Pin behavior

GLOBAL

MODE(2:0)

I

No

Yes

000

Input pins sampled at power-up. MODE(2:0). They define the configuration mode to be used for NG-LARGE configuration.

MODE(2:0) cannot be changed when RST_HARD_N = ‘1’

ID(3:0)

I

No

Yes

-

Device Identification. It must comply with the bitstream device id to allow access bitstream loading or the bitstream device id e equal to 0xF (broadcast mode).

FABRIC_USER(3:0)

I

Yes

No

-

Additional IO for user. FABRIC_USER[0] can be connected to low-skew network.

CLK

I

No

Yes

-

Always required. Must be routed to an external clock in the range [0MHz;100MHz].

RST_HARD_N

I

No

Yes

-

Mandatory input. When low, it resets the internal configuration engine. RST_HARD_N must be low at least during 3 microseconds to ensure a proper configuration engine reset. When RST_HARD_N goes high, the configuration starts after up to 3 additional microseconds.

RST_SOFT_N

I

No

No

-

It only resets internal configuration registers but does not apply a reset on the configuration memory.

READY

O

No

No

Yes

Goes high when the configuration is complete (the FPGA enters in user’s mode)

TRIGGER

O

No

No

Yes

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated TRIGGER_MASK.

ERROR

O

No

No

Yes

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated ERROR_MASK.

POK

O

No

No

No

Goes high when VDD1V2 Core and VDD2V5A Analog Supply are on.

Slave Parallel 8

CS

I

No

No

Yes

Unused but unavailable. Must be left unconnected

TYPE[1:0]

I

No

No

Yes

Unused but unavailable. Must be left unconnected

DATA_OE

O

No

No

Yes

Unused but unavailable. Must be left unconnected

D(7:0)

I

No

No

Yes

Unused but unavailable. Must be left unconnected

Slave par ext

D(8)

O

No

Yes

-

External memory Chip Select (active Low)

Requires a diode + Pull-Up (see diagram)

When the bitstream download is completed this pin is driven to ‘1’

D(9)

O

No

Yes

-

External bitstream memory Clock

When the bitstream download is completed this pin is driven to ‘0’

D(10)

I

No

Yes

-

MISO (data in from external memory)

D(11)

O

No

Yes

-

MOSI (data out to external memory)

When the bitstream download is completed this pin is driven to ‘0’

D(12)

I

Yes

No

No

Available as User’s I/O

D(13)

I/O

Yes

No

No

Available as User’s I/O

D(14)

I/O

Yes

No

No

Available as User’s I/O

D(15)

I/O

Yes

No

No

Available as User’s I/O

SPACEWIRE

DIN_P

I

Yes(*)

No

No

When Master Serial SPI is selected the SpaceWire internal IP can be used after completing the configuration

(*) The SpaceWire internal IP is available for the user’s application.

DIN_N

I

Yes(*)

No

No

SIN_P

I

Yes(*)

No

No

SIN_N

I

Yes(*)

No

No

DOUT_P

O

Yes(*)

No

No

DOUT_N

O

Yes(*)

No

No

SOUT_P

O

Yes(*)

No

No

SOUT_N

O

Yes(*)

No

No

JTAG

TCK

I

No

No

No

JTAG is available in all modes.

Don’t use it while configuration is in progress.

TMS

I

No

No

No

TDI

I

No

No

No

TRST_HARD_N

I

No

No

No

TDO

O

No

No

No

Table: Master Serial SPI configuration pin description

Master Serial SPI with Vcc control configuration details:

The next figure shows a suggestion of schematic to implement the Master Serial SPI with VCC control configuration, then the pin list table describes the behavior of the prog bank pins when this mode is selected.

This configuration mode is the same as Master Slave SPI, with the only difference that the SPI Flash memory is powered by using 3 pins of the NG-LARGE prog bank to supply the external SPI. This can contribute to reduce the risk of corruption of bitstream/data stored into the external SPI memory device.

Figure: Master Serial SPI with Vcc configuration diagram example

Master Serial SPI Mode with VCC control

Prog bank (INTERFACE) pins used and/or impacted by configuration

Group

Pin name

I, O or I/O

User I/O

During configuration

Required

Impacted

Pin behavior

GLOBAL

MODE(2:0)

I

No

Yes

001

Input pins sampled at power-up. MODE(2:0). They define the configuration mode to be used for NG-LARGE configuration.

MODE(2:0) cannot be changed when RST_HARD_N = ‘1’

ID(3:0)

I

No

Yes

-

Device Identification. It must comply with the bitstream device id to allow access bitstream loading.

FABRIC_USER(3:0)

I

Yes

No

-

Additional IO for user. FABRIC_USER[0] can be connected to low-skew network.

CLK

I

No

Yes

-

Always required. Must be routed to an external clock in the range [0MHz;100MHz].

RST_HARD_N

I

No

Yes

-

Mandatory input. When low, it resets the internal configuration engine. RST_HARD_N must be low at least during 3 microseconds to ensure a proper configuration engine reset. When RST_HARD_N goes high, the configuration starts after up to 3 additional microseconds.

RST_SOFT_N

I

No

No

-

It only resets internal configuration registers but does not apply a reset on the configuration memory.

READY

O

No

No

Yes

Goes high when the configuration is complete (the FPGA enters in user’s mode)

TRIGGER

O

No

No

Yes

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated TRIGGER_MASK.

ERROR

O

No

No

Yes

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated ERROR_MASK.

POK

O

No

No

No

Goes high when VDD1V2 Core and VDD2V5A Analog Supply are on.

Slave Parallel

CS

I

No

No

Yes

Unused but unavailable. Must be left unconnected

TYPE[1:0]

I

No

No

Yes

Unused but unavailable. Must be left unconnected

DATA_OE

O

No

No

Yes

Unused but unavailable. Must be left unconnected

D(7:0)

I

No

No

Yes

Unused but unavailable. Must be left unconnected

Slave Par ext

D(8)

O

No

Yes

-

External memory Chip Select (active Low)

When the bitstream download is completed, this pin is driven to ‘1’

D(9)

O

No

Yes

-

External bitstream memory Clock

When the bitstream download is completed, this pin is driven to ‘0’

D(10)

I

No

Yes

-

MISO (data in from external memory)

D(11)

O

No

Yes

--

MOSI (data out to external memory)

When the bitstream download is completed, this pin is driven to ‘0’

D(12)

I

Yes

No

No

Available as User’s I/O

D(13)

I/O

Yes

Yes

-

To Vcc SPI Flash memory

When the bitstream download is completed, this pin is driven to ‘0’

D(14)

I/O

Yes

Yes

-

To Vcc SPI Flash memory

When the bitstream download is completed, this pin is driven to ‘0’

D(15)

I/O

Yes

Yes

-

To Vcc SPI Flash memory

When the bitstream download is completed, this pin is driven to ‘0’

SPACEWIRE

DIN_P

I

Yes(*)

No

No

When Master Serial SPI with Vcc Control is selected the SpaceWire internal IP can be used after completing the configuration

(*) The SpaceWire internal IP is available for the user’s application.

DIN_N

I

Yes(*)

No

No

SIN_P

I

Yes(*)

No

No

SIN_N

I

Yes(*)

No

No

DOUT_P

O

Yes(*)

No

No

DOUT_N

O

Yes(*)

No

No

SOUT_P

O

Yes(*)

No

No

SOUT_N

O

Yes(*)

No

No

JTAG

TCK

I

No

No

No

JTAG is available in all modes. Don’t use it while configuration is in progress.

TMS

I

No

No

No

TDI

I

No

No

No

TRST_HARD_N

I

No

No

No

TDO

O

No

No

No

Table: Master Serial SPI configuration pin description

Slave SpaceWire configuration details:

The next figure shows a suggestion of schematic to implement the Slave SpaceWire configuration, then the pin list table describes the behavior of the prog bank pins when this mode is selected.

Slave SpaceWire

Prog bank (INTERFACE) pins used and/or impacted by configuration

Group

Pin name

I, O or I/O

User I/O

During configuration

Required

Impacted

Pin behavior

GLOBAL

MODE(2:0)

I

No

Yes

010

Input pins sampled at power-up. MODE(2:0). They define the configuration mode to be used for NG-LARGE configuration.

MODE(2:0) cannot be changed when RST_HARD_N = ‘1’

ID(3:0)

I

No

Yes

-

Device Identification. It must comply with the bitstream device id to allow access bitstream loading.

FABRIC_USER(3:0)

I

Yes

No

-

Additional IO for user. FABRIC_USER[0] can be connected to low-skew network.

CLK

I

No

Yes

-

Always required. Can be routed externally to CLK_OSC 100MHz internal oscillator or to an external clock in the range [0MHz;100MHz].

RST_HARD_N

I

No

Yes

-

Mandatory input. When low, it resets the internal configuration engine. RST_HARD_N must be low at least during 3 microseconds to ensure a proper configuration engine reset. When RST_HARD_N goes high, the configuration starts after up to 3 additional microseconds.

RST_SOFT_N

I

No

No

-

It only resets internal configuration registers but does not apply a reset on the configuration memory.

READY

O

No

No

Yes

Goes high when the configuration is complete (the FPGA enters in user’s mode)

TRIGGER

O

No

No

Yes

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated TRIGGER_MASK.

ERROR

O

No

No

Yes

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated ERROR_MASK.

POK

O

No

No

No

Goes high when VDD1V2 Core and VDD2V5A Analog Supply are on.

Slave Parallel

CS

I

No

No

Yes

Unused but unavailable. Must be left unconnected

TYPE[1:0]

I

No

No

Yes

Unused but unavailable. Must be left unconnected

DATA_OE

O

No

No

Yes

Unused but unavailable. Must be left unconnected

D(7:0)

I

No

No

Yes

Unused but unavailable. Must be left unconnected

Slave Par ext

D(8)

O

No

No

-

Available as User’s I/O

D(9)

O

No

No

-

Available as User’s I/O

D(10)

I

No

No

-

Available as User’s I/O

D(11)

O

No

No

-

Available as User’s I/O

D(12)

I

Yes

No

No

Available as User’s I/O

D(13)

I/O

Yes

No

-

Available as User’s I/O

D(14)

I/O

Yes

No

-

Available as User’s I/O

D(15)

I/O

Yes

No

-

Available as User’s I/O

SPACEWIRE

DIN_P

I

No

Yes

-

When Slave SpaceWire configuration mode is selected, the SpaceWire IP remains dedicated to configuration monitoring functions.

DIN_N

I

No

Yes

-

SIN_P

I

No

Yes

-

SIN_N

I

No

Yes

-

DOUT_P

O

No

Yes

-

DOUT_N

O

No

Yes

-

SOUT_P

O

No

Yes

-

SOUT_N

O

No

Yes

-

JTAG

TCK

I

No

No

No

JTAG is available in all modes. Don’t use it while configuration is in progress.

TMS

I

No

No

No

TDI

I

No

No

No

TRST_HARD_N

I

No

No

No

TDO

O

No

No

No

Table: Slave Spacewire configuration pin description

Strobe and Data input signals must comply with the following figure focusing on input capacitors and resistors:

Capacitors are needed in case of signals come from another board not connected to the same ground.

Resistors are needed to center the signal around VDDIO_SPW/2.

Spacewire configuration instructions

The supported SPW instructions by the NG-LARGE FPGA are as stated in the table below.

Command Code

Command

0x01

ADDR_DEBUG

0x02

READ_DEBUG

0x04

WRITE_DEBUG

0x08

WRITE_CONF

Table: NG-LARGE SPW instructions

ADDR_DEBUG instruction

The ADDR_DEBUG instruction is used to set the address of the loader register which will be accessed in all subsequent instructions. Following figure illustrates the format of the packet. Note that if many reads and writes will be performed to the same register only one ADDR_DEBUG instruction is needed.

READ_DEBUG instruction

The READ_DEBUG instruction is used to read the loader register value from the address defined by the previous ADDR_DEBUG instruction. READ_DEBUG instruction is a 1-byte packet containing only the instruction code (0x02) as shown in 5 below. The FPGA responds with a 4-bytes packet containing the read value which is sent LSB first as shown in 6.

WRITE_DEBUG instruction

The WRITE_DEBUG instruction is used to write a value to the address of the loader register defined by the previous ADDR_DEBUG instruction. WRITE_DEBUG instruction contains the instructions code (0x04) followed by 4-bytes data to be written. Data is sent LSB first as shown in the following figure:

WRITE_CONF instruction

The WRITE_CONF instruction is used to program the NG-LARGE FPGA.

The SPW packet size depends on bitstream size and it has the following fields:

  • Instruction code: 0x08 for WRITE_CONF

  • FPGA bitstream: the bitstream to be programmed into the FPGA.

This field is obtained by converting each 32bits bitstream word to 4 bytes sent LSB first as illustrated in the figure below:

Slave parallel configuration details:

The next figure shows a suggestion of schematic to implement the Slave Parallel 8 configuration, then the pin list table describes the behavior of the prog bank pins when this mode is selected.

.

Slave Parallel 8 – Slave Parallel 16

Prog bank (INTERFACE) pins used and/or impacted by configuration

Group

Pin name

I, O or I/O

User I/O

During configuration

Required

Impacted

Pin behavior

GLOBAL

MODE(2:0)

I

No

Yes

PAR8: 100

PAR16: 101

Input pins sampled at power-up. MODE(2:0). They define the configuration mode to be used for NG-LARGE configuration.

MODE(2:0) cannot be changed when RST_HARD_N = ‘1’

ID(3:0)

I

No

Yes

-

Device Identification. It must comply with the bitstream device id to allow access bitstream loading.

FABRIC_USER(3:0)

I

Yes

No

-

Additional IO for user. FABRIC_USER[0] can be connected to low-skew network.

CLK

I

No

Yes

-

Always required. Can be routed externally to CLK_OSC 100MHz internal oscillator or to an external clock in the range [0MHz;100MHz].

RST_HARD_N

I

No

Yes

-

Mandatory input. When low, it resets the internal configuration engine. RST_HARD_N must be low at least during 3 microseconds to ensure a proper configuration engine reset. When RST_HARD_N goes high, the configuration starts after up to 3 additional microseconds.

RST_SOFT_N

I

No

No

-

It only resets internal configuration registers but does not apply a reset on the configuration memory.

READY

O

No

No

Yes

Goes high when the configuration is complete (the FPGA enters in user’s mode)

TRIGGER

O

No

No

Yes

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated TRIGGER_MASK.

ERROR

O

No

No

Yes

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated ERROR_MASK.

POK

O

No

No

No

Goes high when VDD1V2 Core and VDD2V5A Analog Supply are on.

Slave Parallel

CS

I

No

Yes

-

Active high

Chip Select input

TYPE[1:0]

I

No

Yes

-

2-bits control input. It indicates the type of access:

0b00: ADDR_DEBUG

0b01: READ_DEBUG

0b10: WRITE_DEBUG

0b11: WRITE_CONF

DATA_OE

O

No

Yes

-

Active high output. It is a data valid signal for reading operations.

D(7 :0)

I/O

No

Yes

-

8-bit data bus (input during the configuration)

Slave Par ext

D(8)

I/O

Yes

No

No

Slave Parallel 8 :

Available as User’s I/O

Slave Parallel 16 :

D(9)

I/O

Yes

No

No

D(10)

I/O

Yes

No

No

D(11)

I/O

Yes

No

No

D(12)

I/O

Yes

No

No

D(13)

I/O

Yes

No

No

D(14)

I/O

Yes

No

No

D(15)

I/O

Yes

No

No

SPACEWIRE

DIN_P

I

Yes(*)

No

No

When Slave Parallel 8 is selected the SpaceWire internal IP can be used after completing the configuration

(*) The SpaceWire internal IP is available for the user’s application.

DIN_N

I

Yes(*)

No

No

SIN_P

I

Yes(*)

No

No

SIN_N

I

Yes(*)

No

No

DOUT_P

O

Yes(*)

No

No

DOUT_N

O

Yes(*)

No

No

SOUT_P

O

Yes(*)

No

No

SOUT_N

O

Yes(*)

No

No

JTAG

TCK

I

No

No

No

JTAG is available in all modes.

Don’t use it during configuration

TMS

I

No

No

No

TDI

I

No

No

No

TRST_HARD_N

I

No

No

No

TDO

O

No

No

No

Table: Slave Parallel 8 – Slave Parallel 16 configuration pins description

Slave Parallel interface usage

In Slave Parallel 8 and Slave Parallel 16 modes, the configuration clock must be provided to the FPGA on the dedicated CLK input pin. Its frequency can range in [0MHz;100MHz], in any case it must be strictly greater than twice the JTAG (TCK) frequency – if used.

In order to avoid setup/hold time problems, the master can use the falling CLK edge to generate CS, TYPE[1:0] and D(7:0) or D(15:0).

The master can start downloading the bitstream bytes after 50 configuration clock (CLK) cycles.

Each data access is done on the rising edge of CLK, while CS is activated (high level) and TYPE[1:0] informing type of access. Dummy cycles can be inserted – if required by the master by de-asserting CS during one or more cycles between two data. The next figure illustrates an example of timing diagram.

Data are 32 bits long and are sent in the following order:

  • In Slave Parallel 16 mode, DATA[15:0] and then DATA[31:16].

  • In Slave Parallel 8 mode, DATA[7:0], then DATA[16:8], then DATA[23:16] and then DATA[31:24].


Internal interface between fabric and BSM

I/O direction is given for fabric side.

Global signals

The following signals can be used by the fabric and consequently get an impact in the design if needed by users:

Grp

Name

I/O

Description

GLOBAL

CLK_BSM

I

Always required. Can be routed externally to CLK_OSC 100MHz internal oscillator or to an external clock in the range [0MHz;100MHz].

COLD_START

I

Goes high if the FPGA is ready and not reboot because of error occurred.

READY

I

Goes high when the configuration is complete (the FPGA enters in user’s mode)

TRIGGER

I

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated TRIGGER_MASK.

ERROR

I

Generates a high-level pulse (~20 ns or one CLK cycle) each time an error is encountered during the configuration and during design processing. Error is taken into account only if it is not masked by the associated ERROR_MASK.

Slave Parallel 8 interface

There is an internal interface between the Bitstream Manager and the fabric. It operates as slave parallel 8 interface.

The difference is Bitstream Manager registers write/read accesses are made from the fabric and give the ability to use these control and status registers in the design.

Grp

Name

I/O

Description

Parallel User

CS

O

Description is the same than Slave Parallel 8 except that for this interface, commands are sent from the fabric.

DVAL is equivalent to DATA_OE.

TYPE[1:0]

O

DI[7:0]

O

DVAL

I

DO[7:0]

I

Boundary scan

IEEE 1149 JTAG implementation

NX1H140TSP devices support IEEE Std 1149.1 JTAG boundary scan operation for board and device testing.

The EXTEST, INTEST, SAMPLE, BYPASS, IDCODE, USERCODE, and HIGHZ instructions are all included. The tap also supports internal user-defined registers (USER1, USER2) and instructions for device configuration and test.

JTAG interface pins include the standard TCK, TMS, TDI and TDO pads, as well as the optional TRST pad.

NX1H140TSP chips JTAG instructions

NX1H140TSP chips boundary scan instructions are the following:

Hex

Instruction

Function

0x0

EXTEST

Boundary scan external test

0x1

SAMPLE

Boundary scan sample

0x1

PRELOAD

Boundary scan preload

0x2

WR_CONF

Nanoxplore bitstream download

0x3

WR_DEBUG

Write debug instruction

0x4

RD_DEBUG

Read debug instruction

0x5

ADDR_DEBUG

Address debug instruction

0x6

INTEST

Boundary scan in internal test

0x7

IDCODE

Boundary scan design identification

0x8

USRCODE

User design identification register

0x9

USER1

User registers access

0xA

USER2

User registers access

0xC

HIGHZ

Tri-state all device I/Os

0xF

BYPASS

Single-clock bypass TDI to TDO

Table: Boundary scan instructions

NX1H140TSP devices provide a 1046-bit scan chain, described in each device BSDL file.

The WRITE_CONF instruction is used to program the NG-LARGE FPGA.

The ADDR_DEBUG instruction is used to set the address of the loader register which will be accessed in all subsequent instructions.

The READ_DEBUG instruction is used to read the loader register value from the address defined by the previous ADDR_DEBUG instruction.

The WRITE_DEBUG instruction is used to write a value to the address of the loader register defined by the previous ADDR_DEBUG instruction.

The IDCODE instruction returns the NG-LARGE Identification’s code: 0x675.

The USRCODE instruction returns the user-defined code (0xFFFFFFFF by default).

The USER1 instruction is used to access to the user1 registers from the FPGA fabric.

The USER2 instruction is used to access to the user2 registers from the FPGA fabric.

The HIGHZ instruction is used to deactivate the outputs of all pins.

The BYPASS instruction is used to bypass the device.

Endianness

The JTAG commands must be sent by 32bits words with less significant bit first.

Hereafter an example of bitstream loading using WR_CONF command. The first word 0x12345678 is sent with the following sequence “0001 1110 0110 … 0100 1000”

In order to write or read a Bitstream Manager register, it needs a ADDR_DEBUG command followed by respectively a WR_DEBUG or RD_DEBUG command. The address is 32 bits long and data are 96 bits long.

NX1H140TSP boundary scan usage

NX1H140TSP chips are fully programmable devices, so boundary scan instructions usage requires some minimal device configuration using a limited bitstream, especially for the EXTEST instruction:

- pads to be used as outputs need a minimum output drive configuration.

- pads to be used as inputs need a minimum input thresholds configuration.


NX1H140TSP boundary scan errata

NX1H140TSP chips boundary-scan architecture presents some implementation bugs, listed below:

Chip initialization with unused JTAG interface

Problem:

When JTAG interface is not used, the NX1H140TSP chip initialization may fail on a boundary scan initialization error. The interface initialization requires at least one rising edge on the TCK JTAG clock.

Workaround:

- unused JTAG input pads TCK, TMS and TDI should be provided a 10-100KΩ pull-up resistor to VDDIO_SERVICE.

- unused TRST input should be provided a 1KΩ pull-down resistor

- TCK should be driven by a diode (anode) connected to RST_HARD_N (cathod) prog interface reset pin, so that the end-of-reset rising edge provides the required TCK.

Dedicated clock inputs in boundary scan INTEST

Problem:

In boundary scan INTEST instruction execution, the dedicated clock inputs on the SIMPLE banks (0, 1, 6 and 8) are seen by the internal design as simple inputs but not as clock inputs.

Dedicated clock inputs on the COMPLEX banks (2, 5, 9 and 12) are fully functional in boundary scan INTEST.

ANGIE JTAG adaptator

In order to debug a component, it can be very useful to use ANGIE adaptor and NxBase2 software.

An EEPROM is recommended in order to work in non-OEM mode. In this way, the board will be automatically recognized by the software.

Please refer to NxBase2 User Manual documentation in ANGIE chapter.

NG_LARGE register

To access a register, the user needs to use the ADDR_DEBUG instruction first, and then the WR_DEBUG or RD_DEBUG instructions.

Note all NG-MEDIUM registers are kept in NG-LARGE and get the same addresses.

Address

Register Name

R/W

Description

0x00

STATUS

R

Status register

0x0b

JTAG_IDCODE

R

JTAG identification code

0x0c

JTAG_USERCODE

RW

JTAG user code

0x0d

SPI_CTRL

RW

SPI configuration

0x0e

ERROR1

R

Error Flags

0x0f

ERROR1_MASK

RW

Error Mask

0x10

ERROR2

R

Error Flags

0x11

ERROR2_MASK

RW

Error Mask

0x12

EVENT_CNT1

R

Event Counter 1

0x13

EVENT_CNT2

R

Event Counter 2

0x14

MAX_ERROR_CNT

RW

Error counter

0x15

DEVICE_ID

R

FPGA Device ID

0x1a

THSENS_CTRL

RW

Thermal Sensor Configuration

0x1b

THSENS_DATA

R

Thermal Sensor Data

0x1c

DUMP_CTRL

RW

DUMP configuration

0x1d

SPW_CTRL1

RW

SpaceWire Configuration

0x1e

SPW_CTRL2

RW

SpaceWire Configuration

0x1f

LOADER_CTRL

RW

Loader Controller

0x22

ERROR3

R

Error Flags

0x23

ERROR3_MASK

RW

Error Mask

0x24

TRIGGER1_MASK

RW

Trigger Mask

0x25

TRIGGER2_MASK

RW

Trigger Mask

0x26

TRIGGER3_MASK

RW

Trigger Mask

0x27

DRIVER_FORCE

RW

Driver Force

0x28

PARUSR_CTRL

RW

Parallel User Configuration

0x29

PAREXT_CTRL

RW

Parallel External Configuration

0x2a

SPI_TIMING

RW

SPI Timing

0x2b

SPI_ADDR

RW

SPI Address

0x2c

BSM_CTRL

RW

Bitstream Manager Control

STATUS

Name

Address

Access

Reset Value

Description

STATUS

0x00

Read-only

0x0000

Status register

Bits

Field name

Rst

Description

[18]

flag_ready

0x0

1 when ready is rise

[17]

had_trigger

0x0

1 when ERRORx contents flags errors (with application of mask vector)

[16]

status_driver_cmb_bit

0x0

1 when the driver compare bit is set

[15]

had_error_unmasked

0x0

1 when ERRORx contents flags errors (without application of mask vector)

[14]

had_error

0x0

1 when ERRORx contents flags errors (with application of mask vector)

[13]

status_cmic_run

0x0

1 when CMIC is running

[5]

status_max_error

0x0

1 when the Max Error is reach

[4]

status_error

0x0

1 when the Error Flag is rise

[3]

status_download

0x0

1 when the loader downloads a bitstream

[2]

status_prog

0x0

1 when the Programmation Flag is rise

[1]

status_cold_start

0x0

1 when the Ready Flag is first run

[0]

status_ready

0x0

1 when the Ready Flag is rise

JTAG_IDCODE

Name

Address

Access

Reset Value

Description

JTAG_IDCODE

0x0b

Read-only

0x00000675

JTAG identification code

Bits

Field name

Rst

Description

[31:28]

jtag_idcode_version

0x0

Version number

[27:12]

jtag_idcode_part

0x0000

Part number

[11:1]

jtag_idcode_manufacturer

0x33a

Manufacturer ID: 11:8 (4bits) bank, 7:1 (7bits) manufacturer id

[0]

jtag_idcode_one

0x1

Constant Always 1

JTAG_USERCODE

Name

Address

Access

Reset Value

Description

JTAG_USERCODE

0x0c

Read-write

0xffffffff

JTAG user code

Bits

Field name

Rst

Description

[31:0]

jtag_usercode

0xffffffff

JTAG user code

SPI_CTRL

Name

Address

Access

Reset Value

Description

SPI_CTRL

0x0d

Read-write

0x0038

SPI configuration

Bits

Field name

Rst

Description

[18]

spi_restart

0x0

SPI disable for 1 cycle when this bit go to 1 (just 1 cycle)

[17]

spi_disable

0x0

SPI interface is disabled (if disable, then always reset)

[16]

spi_address_size

0x0

SPI Address Size (0 : 24, 1 : 32)

[14:12]

spi_dummy_cycle

0x0

Number of Dummy cycle

[11:4]

spi_read_code

0x3

SPI Read Code

[3:0]

spi_clk_ratio

0x8

SPI Clock frequency is divided by spi_clk_ratio+2 (default : 10Mhz)

ERROR1

Name

Address

Access

Reset Value

Description

ERROR1

0x0e

Read-only

0x00000000

Error Flags

Bits

Field name

Rst

Description

[31]

flag_error_spi_sel

0x0

SPI selection error flag

[30]

flag_error_parallel_read_access_ovf

0x0

Parallel read access overflow

[29]

flag_error_parallel_write_access_conflict

0x0

Parallel write access conflict

[28]

flag_error_fifo_serializer_full

0x0

FIFO of serializer full

[27]

flag_error_reg_read_unaccepted

0x0

Register read access is rejected

[26]

flag_error_reg_write_unaccepted

0x0

Register write access is rejected

[25]

flag_error_bl_read_unaccepted

0x0

Bootloader read is rejected

[24]

flag_error_cfgctx_read_unaccepted

0x0

CFGCTX read is rejected

[23]

flag_error_cfgctx_write_unaccepted

0x0

CFGCTX write is rejected

[22]

flag_error_clear_unaccepted

0x0

Clear command rejected

[21]

flag_error_bltest_unaccepted

0x0

Bootloader test command is rejected

[20]

flag_error_reg_read_busy

0x0

Register read busy error

[19]

flag_error_reg_write_busy

0x0

Register write busy error

[18]

flag_error_bl_read_busy

0x0

Bootloader read busy error

[17]

flag_error_cfgctx_read_busy

0x0

CFGCTX read busy error

[16]

flag_error_cfgctx_write_busy

0x0

CFGCTX write busy error

[15]

flag_error_clear_busy

0x0

Clear busy error

[14]

flag_error_bltest_busy

0x0

Bootloader test busy error

[13]

flag_error_invalid_address

0x0

Address is invalid

[12]

flag_error_direct_engine_rsp_busy

0x0

Direct engine response is busy

[11]

flag_error_direct_engine_rsp_conflict

0x0

Direct engine response in conflict

[10]

flag_error_direct_engine_req_invalid_loader

0x0

Direct engine request signals invalid loader

[9]

flag_error_access_write_conflict

0x0

Write access conflict detected

[8]

flag_error_frame_engine_edac_uncorrected

0x0

Uncorrected error on frame engine's EDAC

[7]

flag_error_frame_engine_crc_frame

0x0

CRC error detected on frame

[6]

flag_error_frame_engine_crc_bitstream

0x0

CRC error detected on bitstream

[5]

flag_error_frame_engine_watchdog_timeout

0x0

Watchdog's timeout is reached

[4]

flag_error_frame_engine_unexpected_frame

0x0

Frame received but not expected

[3]

flag_error_frame_engine_req_invalid_loader

0x0

Invalid loader error detected on frame request

[2]

flag_error_frame_access_conflict

0x0

Access conflict detected on frame

[1]

flag_error_direct_access_rsp_conflict

0x0

Direct access response conflict detected

[0]

flag_error_direct_access_req_conflict

0x0

Direct access request conflict detected

ERROR1_MASK

Name

Address

Access

Reset Value

Description

ERROR1_MASK

0x0f

Read-write

0x1FFE000

Error Mask

Bits

Field name

Rst

Description

[31:0]

flag_error1_mask

0x1FFE000

Error mask register for ERROR1

ERROR2

Name

Address

Access

Reset Value

Description

ERROR2

0x10

Read-only

0x00000

Error Flags

Bits

Field name

Rst

Description

[19]

error_driver_access_conflict

0x0

[18]

error_driver_rsp_parity

0x0

[17]

error_driver_req_parity

0x0

[16]

flag_error_frame_engine_conflict_io_id_bitstream_i

0x0

[15]

flag_error_frame_engine_conflict_io_id_deserializer_i

0x0

[14]

flag_error_frame_access_invalid_io_id_i

0x0

[13]

flag_error_direct_access_rsp_invalid_io_id_i

0x0

[12]

flag_error_direct_access_req_invalid_io_id_i

0x0

[11]

flag_error_parusr_type_conflict_i

0x0

Conflict detected on parusr access

[10]

flag_error_parext_type_conflict_i

0x0

Conflict detected on parext access

[9]

flag_error_spw_link_broken

0x0

SPW link disconnection error detected

[8]

flag_error_spw_err_int

0x0

SPW internal error detected

[7]

flag_error_spw_nom_int

0x0

SPW NOM error

[6]

flag_error_cmic_max_run

0x0

CMIC max run error

[5]

flag_error_cmic_check_uncorrected

0x0

CMIC error is uncorrected

[4]

flag_error_cmic_ref_edac_uncorrected

0x0

CMIC reference for EDAC is uncorrected

[3]

flag_error_cmic_ref_addr_ovf

0x0

CMIC reference address overflow detected

[2]

flag_error_cmic_access_conflict

0x0

Conflict detected on CMIC access

[1]

flag_error_spw_unexpected_packet

0x0

Unexpected SPW packet detected

[0]

flag_error_spw_eep

0x0

SPW EEP marker detected

ERROR2_MASK

Name

Address

Access

Reset Value

Description

ERROR2_MASK

0x11

Read-write

0xe087c

Error Mask

Bits

Field name

Rst

Description

[19:0]

flag_error2_mask

0x000E087C

Error mask register for ERROR2

EVENT_CNT1

Name

Address

Access

Reset Value

Description

EVENT_CNT1

0x12

Read

0x0000

Event counter 1

Bits

Field name

rst

Description

[15:0]

ERROR_CNT

0x00

Number of errors since last hardware reset

EVENT_CNT2

Name

Address

Access

Reset Value

Description

EVENT_CNT2

0x13

Read

0x00000000

Event counter 2

Bits

Field name

rst

Description

[31:24]

CMIC_CHECK_SIGNATURE_CNT

0x00

CMIC signature error counter

[23:16]

CMIC_CHECK_CORRECTED_CNT

0x00

CMIC corrected error counter

[15:8]

CMIC_REF_EDAC_CORRECT_CNT

0x00

Reference EDAC corrected error counter

[7:0]

FRAME_ENGINE_EDAC_CORRECT_CNT

0x00

Frame engine EDAC corrected error counter

MAX_ERROR_CNT

Name

Address

Access

Reset Value

Description

MAX_ERROR_CNT

0x14

Read-write

0xf

Error counter

Bits

Field name

Rst

Description

[3:0]

MAX_ERROR_CNT

0xf

Maximum error count permitted before lighting error led

DEVICE_ID

Name

Address

Access

Reset Value

Description

DEVICE_ID

0x15

Read-only

0x0

FPGA Device ID

Bits

Field name

Rst

Description

[3:0]

device_id

0x0

FPGA device id

THSENS_CTRL

Name

Address

Access

Reset Value

Description

THSENS_CTRL

0x1a

Read-write

0x0000

Thermal Sensor Configuration

Bits

Field name

Rst

Description

[15:6]

thsens_clk_ratio

0x0

Clock ratio between bitstream manager and thermal sensor

Clock frequency is divided by thsens_clk_ratio+2

[5:1]

thsens_dcorrect

0x0

Digital code to correct

[0]

thsens_power_up

0x0

Thermal Sensor is powered

THSENS_DATA

Name

Address

Access

Reset Value

Description

THSENS_DATA

0x1b

Read-only

0x000

Thermal Sensor Data

Bits

Field name

Rst

Description

[8:2]

thsens_data

0x0

Thermal Sensor Ouput

[1]

thsens_overflow

0x0

Overflow of digital

[0]

thsens_enable

0x0

Thermal Sensor is online

DUMP_CTRL

Name

Address

Access

Reset Value

Description

DUMP_CTRL

0x1c

Read-write

0x8

DUMP configuration

Bits

Field name

Rst

Description

[3:0]

dump_clk_ratio

0x8

DUMP Clock frequency is divided by dump_clk_ratio+2

SPW_CTRL1

Name

Address

Access

Reset Value

Description

SPW_CTRL1

0x1d

Read-write

0x00009

SpaceWire Configuration

Bits

Field name

Rst

Description

[19]

spw_user

0x0

In bitstream manager mode : support of USER Packet

[18:16]

spw_freq_user_ratio

0x0

Divider ratio (N+2)

[15:8]

spw_freq_run

0x0

frequency used in run state

Clock frequency divided by (spw_freq_run+1)

[7:0]

spw_freq_init

0x9

frequency used in init state

Clock frequency divided by (spw_freq_init+1)

SPW_CTRL2

Name

Address

Access

Reset Value

Description

SPW_CTRL2

0x1e

Read-write

0x28055

SpaceWire Configuration

Bits

Field name

Rst

Description

[17:8]

spw_delay_prg

0x280

delay of 6.4 us

Number of clock cycles needed for 6.4 us

[7:0]

spw_DisCntLim

0x55

Disconnect time limit (850ns)
Number of clock cycles needed for 850ns

LOADER_CTRL

Name

Address

Access

Reset Value

Description

LOADER_CTRL

0x01

Read-write

0x01

Loader Controller

Bits

Field name

Rst

Description

[6]

cold_start_we_disable

0x0

Don't write in cold_start counter

[5]

ready_init_on_error

0x0

Ready is reset on error

[4]

ready_init_on_rst

0x0

Ready is reset on soft rst (always rst on rst_hard)

[3]

config_force

0x0

Force configuration (force bitstream load)

[2]

ready_force

0x0

Force ready flag

[1]

ready

0x0

Set ready flag when postamble frame occurs

[0]

cmic_enable

0x1

CMIC Feature Enable

ERROR3

Name

Address

Access

Reset Value

Description

ERROR3

0x22

Read-only

0x00

Error Flags

Bits

Field name

Rst

Description

[3]

flag_error_cmic_check_signature

0x0

TBD

[2]

flag_error_cmic_check_corrected

0x0

TBD

[1]

flag_error_cmic_ref_edac_corrected

0x0

TBD

[0]

flag_error_frame_engine_edac_corrected

0x0

TBD

ERROR3_MASK

Name

Address

Access

Reset Value

Description

ERROR3_MASK

0x23

Read-write

0xf

Error Mask

Bits

Field name

Rst

Description

[3:0]

flag_error3_mask

0xf

Error mask register for ERROR3

TRIGGER1_MASK

Name

Address

Access

Reset Value

Description

TRIGGER1_MASK

0x24

Read-write

0x1fffe000

Trigger Mask

Bits

Field name

Rst

Description

[31:0]

flag_trigger1_mask

0x1fffe000

Trigger mask register for ERROR1

TRIGGER2_MASK

Name

Address

Access

Reset Value

Description

TRIGGER2_MASK

0x25

Read-write

0xe087c

Trigger Mask

Bits

Field name

Rst

Description

[31:0]

flag_trigger2_mask

0xe087c

Trigger mask register for ERROR2

TRIGGER3_MASK

Name

Address

Access

Reset Value

Description

TRIGGER3_MASK

0x26

Read-write

0xf

Trigger Mask

Bits

Field name

Rst

Description

[3:0]

flag_trigger3_mask

0xf

Trigger mask register for ERROR3

PARUSR_CTRL

Name

Address

Access

Reset Value

Description

PARUSR_CTRL

0x28

Read-write

0x0

Parallel User Configuration

Bits

Field name

Rst

Description

[0]

parusr_enable

0x0

Parallel User enable (Under reset if disabled)

PAREXT_CTRL

Name

Address

Access

Reset Value

Description

PAREXT_CTRL

0x29

Read-write

0x0

Parallel External Configuration

Bits

Field name

Rst

Description

[0]

parext_data_latency

0x0

Latency between DATA_OE and DATA. Data is delayed

SPI_TIMING

Name

Address

Access

Reset Value

Description

SPI_TIMING

0x2a

Read-write

0x00650bb8

SPI Timing

Bits

Field name

Rst

Description

[31:16]

spi_powerdown_cycle

0x0065

PowerDown duration (needs 10 us)

[15:0]

spi_powerup_cycle

0x0bb8

PowerUp duration (needs 300 us)

SPI_ADDR

Name

Address

Access

Reset Value

Description

SPI_ADDR

0x2b

Read-write

0x00000000

SPI Address

Bits

Field name

Rst

Description

[31:0]

spi_address

0x0

SPI access address

BSM_CTRL

Name

Address

Access

Reset Value

Description

BSM_CTRL

0x2c

Read-write

0x10

BSM Control Code

Bits

Field name

Rst

Description

[6:3]

clk_osc_ratio

0x2

CLK_OSC is divided by (clk_ratio+2)

[2:0]

clk_osc_disable

0x0

CLK_OSC is disabled

  • No labels