Generic AXI ADC

This page presents a generic framework, which is used to design and develop an AXI based IP core for interfacing an Analog to Digital Converter (ADC) device with a high speed serial (JESD204B) or source synchronous parallel interface (LVDS/CMOS). This is a generic framework, there can be minor differences on each and every IP, the user should study this wiki page along with the IP’s wiki page.

The main role of this page to ease the understanding of each ADC IP, and to provide a base knowledge which can be used to develop new IPs for currently unsupported devices.

Important

Any kind of feedback regarding the ADC IP architecture or the following document is highly appreciated and can be addressed through the EngineerZone community forum.

Files

Name	Description
library/common/up_adc_common.v	Verilog source for the ADC Common regmap.
library/common/up_adc_channel.v	Verilog source for the ADC Channel regmap.

Architecture

The main function of an AXI ADC IP is to handle all the low level signalling, which is defined by the device’s digital data interface, and to forward the received data to a more simple FIFO interface. Beside this functionality there are a few processing modules inside the data path of the core, which can be used for signal conditioning. All these processing modules are optional, the are enabled or disabled by setting the appropriate parameters. The following block diagram presents a generic AXI ADC IP cores data path.

Receive PHY

The most important part of the core is the Receive PHY module. This module contains all the IO primitive instantiations and all the control logic required to receive data from the device.

Currently the Receive PHY supports two different receive interface:

• Source synchronous (CMOS or LVDS) interface

• JESD204B/C Link Receive Peripheral [1]

All these interfaces are supported on both Altera (Intel) and Xilinx devices.

This module is perfect choice for those, who wants a HDL logic for the device interface, with a minimal resource footprint.

[1]

The receive module contains just the Transport Layer of the JESD204B interface. Lower layers are implemented by other cores.

ADC Channel

• Data format module

• DC Offset correction module

• IQ correction module

• PN Monitor

ADC Core

The ADC core is the top file of the IP core, the naming convention of this file is: axi_<device_name>.v. Here are instantiated all the internal module discussed above, and a wrapper module (up_axi), which converts the AXI interface into a more simplistic addressable, memory mapped interface, so called Microprocessor Interface or uP interface. This interface is used to interconnect the different memory mapped module pieces.

Interface

A generic AXI ADC core have at least three different interfaces:

• The physical data interface (LVDS or CMOS) or the JESD204B data interface from the link layer.

• Read FIFO interface of the receiver or sink module (e.g. DMA).

• AXI Slave Memory Mapped interface for register map access.

LVDS or CMOS RX interface

Pin	Type	Description
rx_clk_in_[p|n]	clock input	clock input
rx_data_in_[p|n]	input[resolution-1:0]	parallel data input
rx_frame_in_[p|n]	input	frame input signal (optional/device specific)
rx_or_in_[p|n]	input	over range input (optional/device specific)g

JESD RX interface

Pin	Type	Description
rx_clk	clock input	core clock
rx_sof	input[3:0]	start of frame signal
rx_data	input[DW-1:0]	data input; DW=32*MAX_LANE_NO
rx_ready	output	ready, core always ready (tied to HIGH)
rx_valid	input	data valid

Write FIFO interface

Pin	Type	Description
adc_clk	clock output	Interface’s clock signal
adc_enable_0	output	Enable signal for the first channel, asserted if channel is active
adc_valid_0	output	Data valid signal for the first channel, to validate data on the bus
adc_data_0	input[DW-1:0]	Data signal for the first channel
adc_enable_x	output	Enable signal for the channel x, asserted if channel is active
adc_valid_x	output	Data valid signal for the channel x, to validate data on the bus
adc_data_x	output[DW-1:0]	Data signal for the channel x
adc_dovf	input	Data overflow signal from the receiver or sink module (e.g DMA)
adc_dunf	input	Data underflow signal from the receiver or sink module (e.g DMA)

AXI Memory Map Slave

Pin	Type	Description
s_axi_*		Standard AXI Slave Memory Map interface for register map access

Register Map

The following block diagram presents the different register maps physical location in the core. These register maps are generic and can be found in each AXI ADC core.

The base and ADC common register map is implemented in the same verilog file. It contains registers which controls and monitors the overall core, like:

• Reset bits

• Attributes of the receiver interface module

• DRP (Dynamic Reconfiguration Port) access for different IO resources (Clock Management Units, PLLs, Gigabit Transceivers etc.)

• Status registers (PN Monitor status, frequency of the interface clock)

Note

The ADC Common register map is implemented in the library/common/up_adc_common.v verilog file. To find the instantiation of this module search for up_adc_common inside the IP’s directory.

The ADC Channel register map controls and monitors channel specific attributes. Each channel of the core has an individual channel register map. It contains all the registers, which are necessary to control and monitor the processing modules of the data path. For detailed description of the available processing modules see ADC Channel section.

Note

The ADC Channel register map is implemented in the library/common/up_adc_channel.v verilog file. To find the instantiation of this module search for up_adc_channel inside the IP’s directory.

Typical Register Map base addresses

Base (common to all cores) register map

DWORD	BYTE	Reg Name				Description
		BITS	Field Name	Type	Default Value	Description
0x0	0x0	VERSION				Version and Scratch Registers
		[31:0]	VERSION	RO	0x00000000	Version number. Unique to all cores.
0x1	0x4	ID				Version and Scratch Registers
		[31:0]	ID	RO	0x00000000	Instance identifier number.
0x2	0x8	SCRATCH				Version and Scratch Registers
		[31:0]	SCRATCH	RW	0x00000000	Scratch register.
0x3	0xc	CONFIG				Version and Scratch Registers
		[0:0]	IQCORRECTION_DISABLE	RO	0x0	If set, indicates that the IQ Correction module was not implemented. (as a result of a configuration of the IP instance)
		[1:1]	DCFILTER_DISABLE	RO	0x0	If set, indicates that the DC Filter module was not implemented. (as a result of a configuration of the IP instance)
		[2:2]	DATAFORMAT_DISABLE	RO	0x0	If set, indicates that the Data Format module was not implemented. (as a result of a configuration of the IP instance)
		[3:3]	USERPORTS_DISABLE	RO	0x0	If set, indicates that the logic related to the User Data Format (e.g. decimation) was not implemented. (as a result of a configuration of the IP instance)
		[4:4]	MODE_1R1T	RO	0x0	If set, indicates that the core was implemented in 1 channel mode. (e.g. refer to AD9361 data sheet)
		[5:5]	DELAY_CONTROL_DISABLE	RO	0x0	If set, indicates that the delay control is disabled for this IP. (as a result of a configuration of the IP instance)
		[6:6]	DDS_DISABLE	RO	0x0	If set, indicates that the DDS is disabled for this IP. (as a result of a configuration of the IP instance)
		[7:7]	CMOS_OR_LVDS_N	RO	0x0	CMOS or LVDS mode is used for the interface. (as a result of a configuration of the IP instance)
		[8:8]	PPS_RECEIVER_ENABLE	RO	0x0	If set, indicates the PPS receiver is enabled. (as a result of a configuration of the IP instance)
		[9:9]	SCALECORRECTION_ONLY	RO	0x0	If set, indicates that the IQ Correction module implements only scale correction. IQ correction must be enabled. (as a result of a configuration of the IP instance)
		[12:12]	EXT_SYNC	RO	0x0	If set the transport layer cores (ADC/DAC) have implemented the support for external synchronization signal.
		[13:13]	RD_RAW_DATA	RO	0x0	If set, the ADC has the capability to read raw data in register CHAN_RAW_DATA from adc_channel.
0x4	0x10	PPS_IRQ_MASK				PPS Interrupt mask
		[0:0]	PPS_IRQ_MASK	RW	0x1	Mask bit for the 1PPS receiver interrupt
0x7	0x1c	FPGA_INFO				FPGA device information library/scripts/adi_intel_device_info_enc.tcl (Intel encoded values) library/scripts/adi_xilinx_device_info_enc.tcl (Xilinx encoded values)
		[31:24]	FPGA_TECHNOLOGY	RO	0x00	Encoded value describing the technology/generation of the FPGA device (arria 10/7series)
		[23:16]	FPGA_FAMILY	RO	0x00	Encoded value describing the family variant of the FPGA device(e.g., SX, GX, GT or zynq, kintex, virtex)
		[15:8]	SPEED_GRADE	RO	0x00	Encoded value describing the FPGA’s speed-grade
		[7:0]	DEV_PACKAGE	RO	0x00	Encoded value describing the device package. The package might affect high-speed interfaces

ADC Common (axi_ad*) register map

DWORD	BYTE	Reg Name				Description
		BITS	Field Name	Type	Default Value	Description
0x10	0x40	RSTN				ADC Interface Control & Status
		[2:2]	CE_N	RW	0x0	Clock enable, default is enabled(0x0). An inverse version of the signal is exported out of the module to control clock enables
		[1:1]	MMCM_RSTN	RW	0x0	MMCM reset only (required for DRP access). Reset, default is IN-RESET (0x0), software must write 0x1 to bring up the core.
		[0:0]	RSTN	RW	0x0	Reset, default is IN-RESET (0x0), software must write 0x1 to bring up the core.
0x11	0x44	CNTRL				ADC Interface Control & Status
		[16:16]	SDR_DDR_N	RW	0x0	Interface type (1 represents SDR, 0 represents DDR)
		[15:15]	SYMB_OP	RW	0x0	Select symbol data format mode (0x1)
		[14:14]	SYMB_8_16B	RW	0x0	Select number of bits for symbol format mode (1 represents 8b, 0 represents 16b)
		[12:8]	NUM_LANES	RW	0x00	Number of active lanes (1 : CSSI 1-lane, LSSI 1-lane, 2 : LSSI 2-lane, 4 : CSSI 4-lane). For AD7768, AD7768-4 and AD777x number of active lanes : 1/2/4/8 where supported.
		[3:3]	SYNC	RW	0x0	Initialize synchronization between multiple ADCs
		[2:2]	R1_MODE	RW	0x0	Select number of RF channels 1 (0x1) or 2 (0x0).
		[1:1]	DDR_EDGESEL	RW	0x0	Select rising edge (0x0) or falling edge (0x1) for the first part of a sample (if applicable) followed by the successive edges for the remaining parts. This only controls how the sample is delineated from the incoming data post DDR registers.
		[0:0]	PIN_MODE	RW	0x0	Select interface pin mode to be clock multiplexed (0x1) or pin multiplexed (0x0). In clock multiplexed mode, samples are received on alternative clock edges. In pin multiplexed mode, samples are interleaved or grouped on the pins at the same clock edge.
0x12	0x48	CNTRL_2				ADC Interface Control & Status
		[1:1]	EXT_SYNC_ARM	RW	0x0	Setting this bit will arm the trigger mechanism sensitive to an external sync signal. Once the external sync signal goes high it synchronizes channels within a ADC, and across multiple instances. This bit has an effect only the EXT_SYNC synthesis parameter is set. This bit self clears.
		[2:2]	EXT_SYNC_DISARM	RW	0x0	Setting this bit will disarm the trigger mechanism sensitive to an external sync signal. This bit has an effect only the EXT_SYNC synthesis parameter is set. This bit self clears.
		[8:8]	MANUAL_SYNC_REQUEST	RW	0x0	Setting this bit will issue an external sync event if it is hooked up inside the fabric. This bit has an effect only the EXT_SYNC synthesis parameter is set. This bit self clears.
0x13	0x4c	CNTRL_3				ADC Interface Control & Status
		[8:8]	CRC_EN	RW	0x0	Setting this bit will enable the CRC generation.
		[7:0]	CUSTOM_CONTROL	RW	0x00	Select output format decode mode.(for ADAQ8092: bit 0 - enables digital output randomizer decode , bit 1 - enables alternate bit polarity decode).
0x15	0x54	CLK_FREQ				ADC Interface Control & Status
		[31:0]	CLK_FREQ	RO	0x00000000	Interface clock frequency. This is relative to the processor clock and in many cases is 100MHz. The number is represented as unsigned 16.16 format. Assuming a 100MHz processor clock the minimum is 1.523kHz and maximum is 6.554THz. The actual interface clock is CLK_FREQ * CLK_RATIO (see below). Note that the actual sampling clock may not be the same as the interface clock- software must consider device specific implementation parameters to calculate the final sampling clock.
0x16	0x58	CLK_RATIO				ADC Interface Control & Status
		[31:0]	CLK_RATIO	RO	0x00000000	Interface clock ratio - as a factor actual received clock. This is implementation specific and depends on any serial to parallel conversion and interface type (ddr/sdr/qdr).
0x17	0x5c	STATUS				ADC Interface Control & Status
		[4:4]	ADC_CTRL_STATUS	RO	0x0	If set, indicates that the device’​s register data is available on the data bus.
		[3:3]	PN_ERR	RO	0x0	If set, indicates pn error in one or more channels.
		[2:2]	PN_OOS	RO	0x0	If set, indicates pn oos in one or more channels.
		[1:1]	OVER_RANGE	RO	0x0	If set, indicates over range in one or more channels.
		[0:0]	STATUS	RO	0x0	Interface status, if set indicates no errors. If not set, there are errors, software may try resetting the cores.
0x18	0x60	DELAY_CNTRL				ADC Interface Control & Status(Deprecated from version 9)
		[17:17]	DELAY_SEL	RW	0x0	Delay select, a 0x0 to 0x1 transition in this register initiates a delay access controlled by the registers below.
		[16:16]	DELAY_RWN	RW	0x0	Delay read (0x1) or write (0x0), the delay is accessed directly (no increment or decrement) with an address corresponding to each pin, and data corresponding to the total delay.
		[15:8]	DELAY_ADDRESS	RW	0x00	Delay address, the range depends on the interface pins, data pins are usually at the lower range.
		[4:0]	DELAY_WDATA	RW	0x00	Delay write data, a value of 1 corresponds to (1/200)ns for most devices.
0x19	0x64	DELAY_STATUS				ADC Interface Control & Status(Deprecated from version 9)
		[9:9]	DELAY_LOCKED	RO	0x0	Indicates delay locked (0x1) state. If this bit is read 0x0, delay control has failed to calibrate the elements.
		[8:8]	DELAY_STATUS	RO	0x0	If set, indicates busy status (access pending). The read data may not be valid if this bit is set.
		[4:0]	DELAY_RDATA	RO	0x00	Delay read data, current delay value in the elements
0x1a	0x68	SYNC_STATUS				ADC Synchronization Status register
		[0:0]	ADC_SYNC	RO	0x0	ADC synchronization status. Will be set to 1 after the synchronization has been completed or while waiting for the synchronization signal in JESD204 systems.
0x1c	0x70	DRP_CNTRL				ADC Interface Control & Status
		[28:28]	DRP_RWN	RW	0x0	DRP read (0x1) or write (0x0) select (does not include GTX lanes). NOT-APPLICABLE if DRP_DISABLE is set (0x1).
		[27:16]	DRP_ADDRESS	RW	0x000	DRP address, designs that contain more than one DRP accessible primitives have selects based on the most significant bits (does not include GTX lanes). NOT-APPLICABLE if DRP_DISABLE is set (0x1).
		[15:0]	RESERVED	RO	0x0000	Reserved for backward compatibility.
0x1d	0x74	DRP_STATUS				ADC Interface Control & Status
		[17:17]	DRP_LOCKED	RO	0x0	If set indicates that the DRP has been locked.
		[16:16]	DRP_STATUS	RO	0x0	If set indicates busy (access pending). The read data may not be valid if this bit is set (does not include GTX lanes). NOT-APPLICABLE if DRP_DISABLE is set (0x1).
		[15:0]	RESERVED	RO	0x0000	Reserved for backward compatibility.
0x1e	0x78	DRP_WDATA				ADC DRP Write Data
		[15:0]	DRP_WDATA	RW	0x0000	DRP write data (does not include GTX lanes). NOT-APPLICABLE if DRP_DISABLE is set (0x1).
0x1f	0x7c	DRP_RDATA				ADC DRP Read Data
		[15:0]	DRP_RDATA	RO	0x0000	DRP read data (does not include GTX lanes).
0x20	0x80	ADC_CONFIG_WR				ADC Write Configuration ​Data
		[31:0]	ADC_CONFIG_WR	RW	0x00000000	Custom ​Write to the available registers.
0x21	0x84	ADC_CONFIG_RD				ADC Read Configuration ​Data
		[31:0]	ADC_CONFIG_RD	RO	0x00000000	Custom read of the available registers.
0x22	0x88	UI_STATUS				User Interface Status
		[2:2]	UI_OVF	RW1C	0x0	User Interface overflow. If set, indicates an overflow occurred during data transfer at the user interface (FIFO interface). Software must write a 0x1 to clear this register bit.
		[1:1]	UI_UNF	RW1C	0x0	User Interface underflow. If set, indicates an underflow occurred during data transfer at the user interface (FIFO interface). Software must write a 0x1 to clear this register bit.
		[0:0]	UI_RESERVED	RW1C	0x0	Reserved for backward compatibility.
0x23	0x8c	ADC_CONFIG_CTRL				ADC RD/WR configuration
		[31:0]	ADC_CONFIG_CTRL	RW	0x00000000	Control RD/WR requests to the device’​s register map: bit 1 - RD (‘b1) , WR (‘b0), bit 0 - enable WR/RD operation.
0x28	0xa0	USR_CNTRL_1				ADC Interface Control & Status
		[7:0]	USR_CHANMAX	RW	0x00	This indicates the maximum number of inputs for the channel data multiplexers. User may add different processing modules post data capture as another input to this common multiplexer. NOT-APPLICABLE if USERPORTS_DISABLE is set (0x1).
0x29	0xa4	ADC_START_CODE				ADC Synchronization start word
		[31:0]	ADC_START_CODE	RW	0x00000000	This sets the startcode that is used by the ADCs for synchronization NOT-APPLICABLE if START_CODE_DISABLE is set (0x1).
0x2e	0xb8	ADC_GPIO_IN				ADC GPIO inputs
		[31:0]	ADC_GPIO_IN	RO	0x00000000	This reads auxiliary GPI pins of the ADC core
0x2f	0xbc	ADC_GPIO_OUT				ADC GPIO outputs
		[31:0]	ADC_GPIO_OUT	RW	0x00000000	This controls auxiliary GPO pins of the ADC core NOT-APPLICABLE if GPIO_DISABLE is set (0x1).
0x30	0xc0	PPS_COUNTER				PPS Counter register
		[31:0]	PPS_COUNTER	RO	0x00000000	Counts the core clock cycles (can be a device clock or interface clock) between two 1PPS pulse.
0x31	0xc4	PPS_STATUS				PPS Status register
		[0:0]	PPS_STATUS	RO	0x0	If this bit is asserted there is no incomming 1PPS signal. Maybe the source is out of sync or it’s not active.

JESD TPL (up_tpl_common) register map

DWORD	BYTE	Reg Name				Description
		BITS	Field Name	Type	Default Value	Description
0x80	0x200	TPL_CNTRL				JESD, TPL Control
		[3:0]	PROFILE_SEL	RW		Selects one of the available deframer/framers from the transport layer. Valid only if PROFILE_NUM > 1.
0x81	0x204	TPL_STATUS				JESD, TPL Status
		[3:0]	PROFILE_NUM	RO		Number of supported framer/deframer profiles.
0x90 + 0x2*n	0x240 + 0x8*n	TPL_DESCRIPTORn_1				JESD, TPL descriptor for profile n Where n is from 0 to 2.
		[31:24]	JESD_F	RO		Octets per Frame per Lane.
		[23:16]	JESD_S	RO		Samples per Converter per Frame.
		[15:8]	JESD_L	RO		Lane Count.
		[7:0]	JESD_M	RO		Converter Count.
0x91 + 0x2*n	0x244 + 0x8*n	TPL_DESCRIPTORn_2				JESD, TPL descriptor for profile n Where n is from 0 to 2.
		[7:0]	JESD_N	RO		Converter Resolution.
		[15:8]	JESD_NP	RO		Total Number of Bits per Sample.

ADC Channel (axi_ad*) register map

DWORD	BYTE	Reg Name				Description
		BITS	Field Name	Type	Default Value	Description
0x100 + 0x16*n	0x400 + 0x58*n	CHAN_CNTRLn				ADC Interface Control & Status Where n is from 0 to 15.
		[11:11]	ADC_LB_OWR	RW	0x0	If set, forces ADC_DATA_SEL to 1, enabling data loopback
		[10:10]	ADC_PN_SEL_OWR	RW	0x0	If set, forces ADC_PN_SEL to 0x9, device specific pn (e.g. ad9361) If both ADC_PN_TYPE_OWR and ADC_PN_SEL_OWR are set, they are ignored
		[9:9]	IQCOR_ENB	RW	0x0	if set, enables IQ correction or scale correction. NOT-APPLICABLE if IQCORRECTION_DISABLE is set (0x1).
		[8:8]	DCFILT_ENB	RW	0x0	if set, enables DC filter (to disable DC offset, set offset value to 0x0). NOT-APPLICABLE if DCFILTER_DISABLE is set (0x1).
		[6:6]	FORMAT_SIGNEXT	RW	0x0	if set, enables sign extension (applicable only in 2’s complement mode). The data is always sign extended to the nearest byte boundary. NOT-APPLICABLE if DATAFORMAT_DISABLE is set (0x1).
		[5:5]	FORMAT_TYPE	RW	0x0	Select offset binary (0x1) or 2’s complement (0x0) data type. This sets the incoming data type and is required by the post processing modules for any data conversion. NOT-APPLICABLE if DATAFORMAT_DISABLE is set (0x1).
		[4:4]	FORMAT_ENABLE	RW	0x0	Enable data format conversion (see register bits above). NOT-APPLICABLE if DATAFORMAT_DISABLE is set (0x1).
		[3:3]	RESERVED	RO	0x0	Reserved for backward compatibility.
		[2:2]	RESERVED	RO	0x0	Reserved for backward compatibility.
		[1:1]	ADC_PN_TYPE_OWR	RW	0x0	If set, forces ADC_PN_SEL to 0x1, modified pn23 If both ADC_PN_TYPE_OWR and ADC_PN_SEL_OWR are set, they are ignored
		[0:0]	ENABLE	RW	0x0	If set, enables channel. A 0x0 to 0x1 transition transfers all the control signals to the respective channel processing module. If a channel is part of a complex signal (I/Q), even channel is the master and the odd channel is the slave. Though a single control is used, both must be individually selected.
0x101 + 0x16*n	0x404 + 0x58*n	CHAN_STATUSn				ADC Interface Control & Status Where n is from 0 to 15.
		[12:12]	CRC_ERR	RW1C	0x0	CRC errors. If set, indicates CRC error. Software must first clear this bit before initiating a transfer and monitor afterwards.
		[11:4]	STATUS_HEADER	RO	0x00	The status header sent by the ADC.(compatible with AD7768/AD7768-4/AD777x).
		[2:2]	PN_ERR	RW1C	0x0	PN errors. If set, indicates spurious mismatches in sync state. This bit is cleared if OOS is set and is only indicates errors when OOS is cleared.
		[1:1]	PN_OOS	RW1C	0x0	PN Out Of Sync. If set, indicates an OOS status. OOS is set, if 64 consecutive patterns mismatch from the expected pattern. It is cleared, when 16 consecutive patterns match the expected pattern.
		[0:0]	OVER_RANGE	RW1C	0x0	If set, indicates over range. Note that over range is independent of the data path, it indicates an over range over a data transfer period. Software must first clear this bit before initiating a transfer and monitor afterwards.
0x102 + 0x16*n	0x408 + 0x58*n	CHAN_RAW_DATAn				ADC Raw Data Reading Where n is from 0 to 15.
		[31:0]	ADC_READ_DATA	RO	0x00000000	Raw data read from the ADC.
0x104 + 0x16*n	0x410 + 0x58*n	CHAN_CNTRLn_1				ADC Interface Control & Status Where n is from 0 to 15.
		[31:16]	DCFILT_OFFSET	RW	0x0000	DC removal (if equipped) offset. This is a 2’s complement number added to the incoming data to remove a known DC offset. NOT-APPLICABLE if DCFILTER_DISABLE is set (0x1).
		[15:0]	DCFILT_COEFF	RW	0x0000	DC removal filter (if equipped) coefficient. The format is 1.1.14 (sign, integer and fractional bits). NOT-APPLICABLE if DCFILTER_DISABLE is set (0x1).
0x105 + 0x16*n	0x414 + 0x58*n	CHAN_CNTRLn_2				ADC Interface Control & Status Where n is from 0 to 15.
		[31:16]	IQCOR_COEFF_1	RW	0x0000	IQ correction (if equipped) coefficient. If scale & offset is implemented, this is the scale value and the format is 1.1.14 (sign, integer and fractional bits). If matrix multiplication is used, this is the channel I coefficient and the format is 1.1.14 (sign, integer and fractional bits). If SCALECORRECTION_ONLY is set, this implements the scale value correction for the current channel with the format 1.1.14 (sign, integer and fractional bits). NOT-APPLICABLE if IQCORRECTION_DISABLE is set (0x1).
		[15:0]	IQCOR_COEFF_2	RW	0x0000	IQ correction (if equipped) coefficient. If scale & offset is implemented, this is the offset value and the format is 2’s complement. If matrix multiplication is used, this is the channel Q coefficient and the format is 1.1.14 (sign, integer and fractional bits). NOT-APPLICABLE if IQCORRECTION_DISABLE is set (0x1).
0x106 + 0x16*n	0x418 + 0x58*n	CHAN_CNTRLn_3				ADC Interface Control & Status Where n is from 0 to 15.
		[19:16]	ADC_PN_SEL	RW	0x0	Selects the PN monitor sequence type (available only if ADC supports it). 0x0: pn9a (device specific, modified pn9) 0x1: pn23a (device specific, modified pn23) 0x4: pn7 (standard O.150) 0x5: pn15 (standard O.150) 0x6: pn23 (standard O.150) 0x7: pn31 (standard O.150) 0x9: pnX (device specific, e.g. ad9361) 0x0A: Nibble ramp (Device specific e.g. adrv9001) 0x0B: 16 bit ramp (Device specific e.g. adrv9001)
		[3:0]	ADC_DATA_SEL	RW	0x0	Selects the data source to DMA. 0x0: input data (ADC) 0x1: loopback data (DAC)
0x108 + 0x16*n	0x420 + 0x58*n	CHAN_USR_CNTRLn_1				ADC Interface Control & Status Where n is from 0 to 15.
		[25:25]	USR_DATATYPE_BE	RO	0x0	The user data type format- if set, indicates big endian (default is little endian). NOT-APPLICABLE if USERPORTS_DISABLE is set (0x1).
		[24:24]	USR_DATATYPE_SIGNED	RO	0x0	The user data type format- if set, indicates signed (2’s complement) data (default is unsigned). NOT-APPLICABLE if USERPORTS_DISABLE is set (0x1).
		[23:16]	USR_DATATYPE_SHIFT	RO	0x00	The user data type format- the amount of right shift for actual samples within the total number of bits. NOT-APPLICABLE if USERPORTS_DISABLE is set (0x1).
		[15:8]	USR_DATATYPE_TOTAL_BITS	RO	0x00	The user data type format- number of total bits used for a sample. The total number of bits must be an integer multiple of 8 (byte aligned). NOT-APPLICABLE if USERPORTS_DISABLE is set (0x1).
		[7:0]	USR_DATATYPE_BITS	RO	0x00	The user data type format- number of bits in a sample. This indicates the actual sample data bits. NOT-APPLICABLE if USERPORTS_DISABLE is set (0x1).
0x109 + 0x16*n	0x424 + 0x58*n	CHAN_USR_CNTRLn_2				ADC Interface Control & Status Where n is from 0 to 15.
		[31:16]	USR_DECIMATION_M	RW	0x0000	This holds the user decimation M value of the channel that is currently being selected on the multiplexer above. The total decimation factor is of the form M/N. NOT-APPLICABLE if USERPORTS_DISABLE is set (0x1).
		[15:0]	USR_DECIMATION_N	RW	0x0000	This holds the user decimation N value of the channel that is currently being selected on the multiplexer above. The total decimation factor is of the form M/N. NOT-APPLICABLE if USERPORTS_DISABLE is set (0x1).
0x10a + 0x16*n	0x428 + 0x58*n	CHAN_CNTRLn_4				ADC Interface Control & Status Where n is from 0 to 15.
		[31:3]	RESERVED	RO	0x00000000	Reserved for backward compatibility.
		[2:0]	SOFTSPAN	RW	0x7	Softspan configuration register.

IO Delay Control (axi_ad*) register map

DWORD	BYTE	Reg Name				Description
		BITS	Field Name	Type	Default Value	Description
0x0 + 0x1*n	0x0 + 0x4*n	DELAY_CONTROL_n				Delay Control & Status Where n is from 0 to 15.
		[4:0]	DELAY_CONTROL_IO_n	RW	0x00	Tap value for input/output delay primitive of the n’th interface line. If the delay controller is not locked (indicate issues with delay_clk), the read-back value of this register will be 0xFFFFFFFF. Otherwise will be the last set up value.

References

• AXI_AD9361 IP Description