HP ADNB-3082 High-performance optical mouse sensor Datasheet

Agilent ADNS-3080
High-performance
Optical Mouse Sensor
Data Sheet
Features
• High speed motion detection – up
to 40 ips and 15g
Description
The ADNS-3080 is a high
performance addition to Agilent’s
popular ADNS family of optical
mouse sensors.
The ADNS-3080 is based on a
new, faster architecture with
improved navigation. The sensor
is capable of sensing high speed
mouse motion - up to 40 inches
per second and acceleration up
to 15g – for increased user
precision and smoothness.
The ADNS-3080 along with the
ADNS-2120 (or ADNS-2120-001)
lens, ADNS-2220 (or ADNS2220-001) assembly clip and
HLMP-ED80-XX000 form a
complete, compact optical mouse
tracking system. There are no
moving parts, which means high
reliability and less maintenance
for the end user. In addition,
precision optical alignment is not
required, facilitating high volume
assembly.
The sensor is programmed via
registers through a four-wire
serial port. It is packaged in a
20-pin staggered dual inline
package (DIP).
Theory of Operation
The ADNS-3080 is based on
Optical Navigation Technology,
which measures changes in
position by optically acquiring
sequential surface images
(frames) and mathematically
determining the direction and
magnitude of movement.
It contains an Image
Acquisition System (IAS), a
Digital Signal Processor (DSP),
and a four-wire serial port.
The IAS acquires microscopic
surface images via the lens
and illumination system. These
images are processed by the
DSP to determine the direction
and distance of motion. The
DSP calculates the ∆x and ∆y
relative displacement values.
An external microcontroller
reads the ∆x and ∆y
information from the sensor
serial port. The
microcontroller then translates
the data into PS2 or USB
signals before sending them to
the host PC or game console.
• New architecture for greatly
improved optical navigation
technology
• Programmable frame rate over
6400 frames per second
• SmartSpeed self-adjusting frame
rate for optimum performance
• Serial port burst mode for fast
data transfer
• 400 or 1600 cpi selectable
resolution
• Single 3.3 volt power supply
• Four-wire serial port along with
Chip Select, Power Down, and
Reset pins
Applications
• Mice for game consoles and
computer games
• Mice for desktop PC’s,
Workstations, and portable PC’s
• Trackballs
• Integrated input devices
Pinout
Pin
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
2
Name
NCS
MISO
SCLK
MOSI
LED_CTRL
RESET
NPD
OSC_OUT
GUARD
OSC_IN
NC
OPTP
REFC
REFB
VDD3
GND
VDD3
NC
GND
NC
Description
Chip select (active low input)
Serial data output (Master In/Slave Out)
Serial clock input
Serial data input (Master Out/Slave In)
LED control output
Reset input
Power down (active low input)
Oscillator output
Oscillator gnd for PCB guard (optional)
Oscillator input
No connect
Connect to VDD3
Reference capacitor
Reference capacitor
Supply voltage
Ground
Supply voltage
No connect
Ground
No connect
TOP VIEW
NCS
1
MISO
2
SCLK
3
MOSI
4
LED_CTRL
5
RESET
6
NPD
7
OSC_OUT
8
GUARD
9
OSC_IN
10
A3080
XYYWWZ
20
NC
19
GND
18
NC
17
VDD3
16
GND
15
VDD3
14
REFB
13
REFC
12
OPTP
11
NC
PINOUT
Figure 1. Package outline drawing (top view)
Figure 2. Package outline drawing
CAUTION: It is advised that normal static precautions be taken in handling and assembly of
this component to prevent damage and/or degradation which may be induced by ESD.
3
Overview of Optical Mouse Sensor Assembly
2D Assembly Drawing of ADNS-3080
Shown with ADNS-2120,
ADNS-2220 and HLMP ED80XX000.
down. There is an aperture
stop and features on the
package that align to the lens.
Agilent Technologies provides
an IGES file drawing
describing the base plate
molding features for lens and
PCB alignment.
The ADNS-2120 lens provides
optics for the imaging of the
surface as well as illumination
of the surface at the optimum
angle. Features on the lens
align it to the sensor, base
plate, and clip with the LED.
The lens also has a large
round flange to provide a long
creepage path for any ESD
events that occur at the
opening of the base plate.
The components interlock as
they are mounted onto defined
features on the base plate.
The ADNS-3080 sensor is
designed for mounting on a
through hole PCB, looking
Figure 3. Recommended PCB mechanical cutouts and spacing
4
The ADNS-2220-001 clip holds
the LED in relation to the
lens. The LED must be
inserted into the clip and the
LED’s leads formed prior to
loading on the PCB. The clip
interlocks the sensor to the
lens, and through the lens to
the alignment features on the
base plate.
The HLMP-ED80-XX000 LED
is recommended for
illumination. If used with the
bin table, sufficient
illumination can be guaranteed.
Figure 4. 2D Assembly drawing of ADNS-3080 (top and side view)
NOTE: These new Agilent optical mouse sensors, lenses and clips have different physical
configurations that require a different PCB mounting method to optimize the navigation
performance.
Refer Application Notes AN 5035 for further information.
5
PCB Assembly Considerations
HLMP-ED80-XX000 (LED)
ADNS-2220 (Clip)
ADNS-3080 (Sensor)
Customer supplied PCB
ADNS-2120 (Lens)
Customer supplied base
plate with recommended
alignment features per
IGES drawing.
Figure 5. Exploded view drawing
3. Insert the LED/clip assembly
into PCB.
4. Wave Solder the entire
assembly in a no-wash
solder process utilizing
solder fixture. The solder
fixture is needed to protect
the sensor during the solder
process. It also sets the
correct sensor-to -PCB
distance as the lead
shoulders do not normally
rest on the PCB surface.
The fixture should be
designed to expose the
sensor leads to solder while
shielding the optical
aperture from direct solder
contact.
5. Place the lens onto the base
plate.
6. Remove the protective
kapton tape from optical
aperture of the sensor. Care
must be taken to keep
contaminants from entering
6
7. Insert PCB assembly over
the lens onto the base plate
aligning post to retain PCB
assembly. The sensor
aperture ring should selfalign to the lens.
8. The optical position
reference for the PCB is set
by the base plate and lens.
Note that the PCB motion
due to button presses must
be minimized to maintain
optical alignment.
9. Install mouse top case.
There MUST be a feature in
the top case to press down
OSC_IN
NCS
RESONATOR
OSCILLATOR
SCLK
MOSI
MISO
LED_CTRL
CTRL
RESET
OSC_OUT
IMAGE
PROCESSOR
VOLTAGE REGULATOR
AND POWER CONTROL
2. Insert the LED into the
assembly clip and bend the
leads 90 degrees.
the aperture. During mouse
assembly process, it is
recommended that the PCB
is held vertically when
kapton tapes are being
removed.
Serial Port
1. Insert the sensor and all
other electrical components
into PCB.
Figure 6. Block diagram of ADNS-3080 optical mouse sensor
REFB
REFC
REFERENCE
VOLTAGE
FILTER NODE
OPTP
NPD
VDD3
GND
3.3 V POWER
Design considerations for improving
ESD Performance
The flange on the lens has
been designed to increase the
creepage and clearance
distance for electrostatic
discharge. The table below
shows typical values assuming
base plate construction per the
Agilent supplied IGES file and
ADNS-2120 lens flange.
Typical Distance
Creepage
Clearance
Millimeters
16.0
2.1
and therefore, cyanoacrylate
based adhesives or other
adhesives that may damage the
lens should NOT be used.
For improved ESD
performance, the lens flange
can be sealed (i.e. glued) to
the base plate. Note that the
lens material is polycarbonate
Clip
LED
Sensor
PCB
Lens/Light Pipe
Base Plate
Surface
Figure 7. Cross section of PCB assembly
7
LP2950ACZ-3.3
3 Vin
Vo 1
GND
2
+
Vcc
SHLD
D+
D-
11
Vreg
17 P1.7
18
P1.5
3
Vcc
Scroll Wheel
Encoder
ALPS
EC10E
7
P0.7* 21
3
P0.6 22
2
P0.5* 23
4
P0.4* 24
1
P0.2 3
10 KΩ
6
P0.3 4
10 KΩ
7
QA 1
QB 2
P1.0
P1.2
P1.1
LED_CTRL
MISO
MOSI
REFC
5
13
+
NCS
REFB
RESET
NPD
OSC_IN
20KΩ
OSC_OUT
L
14
M
Buttons
20
R
11 18
OPTP
2.2
uF
10
9
24 MHz
8
Ceramic Resonator
Murata
CSALS 24 M 0X 53 -B 0
TDK FCR 24. 0 M 2G
6
VSS 9
XTALOUT
13
20KΩ
5
187Ω
1/8 W
SURFACE
GUARD
P1.4
HLMP-ED80
BS170
SCLK
NC
GND
Vpp
CYPRESS
CY7C63743A-PC
1.3 KΩ
15
NC
15
D-
ADNS
2120
Lens
V DD V DD Internal
Image
16 GND
Sensor
19
GND
4.7uF
NC
16
D+
17
+
Vcc
10
Vcc
0.1uF
14
Vcc
0.1uF
0.1uF
4.7uF
ADNS-3080
0.1
uF
12
Vo 3.3V
20
XTALIN
12
6 MHz
(Optional)
20kΩ
Notes:
- All capacitors close to chip
- 24MHz and 6MHz oscillators close to chip
- * Outputs configured as open drain
20kΩ
Figure 8. Schematic Diagram for USB, PS/2 mouse application with ADNS-3080
Notes
• Caps for pins 15 and 17 MUST have trace lengths LESS than 5 mm to nearest ground pin.
• Pins 15 and 17 caps MUST use pin 16 GND.
• Pin 9, if used, should not be connected to PCB GND to reduce potential RF emissions.
• The 0.1 uF caps must be ceramic.
• Caps should have less than 5 nH of self inductance.
• Caps should have less than 0.2 Ω ESR.
• NC pins should not be connected to any traces.
• Surface mount parts are recommended.
• Care must be taken when interfacing a 5V microcontroller to the ADNS-3080. Serial port inputs on the sensor should
be connected to open-drain outputs from the microcontroller or use an active drive level shifter. NPD and RESET
should be connected to 5V microcontroller outputs through a resistor divider or other level shifting technique.
• VDD3 and GND should have low impedance connections to the power supply.
• Capacitors connected to pin 15 and 17 should be connected to pin 16 and then to pin 19.
8
Enabling the SROM
Regulatory Requirements
For best tracking
performance,SROM is required
to be loaded into ADNS-3080.
This architecture enables
immediate adoption of new
features and improved
performance algorithms. The
external program is supplied
by Agilent as a file which may
be burned into a
programmable device. A
micro-controller with sufficient
memory may be used. On
power-up and reset, the
ADNS-3080 program is
downloaded into volatile
memory using the burst-mode
procedure described in the
Synchronous Serial Port
section. The program size is
1986 x 8 bits.
• Passes FCC B and
worldwide analogous
emission limits when
assembled into a mouse
with shielded cable and
following Agilent
recommendations.
• Passes IEC-1000-4-3
radiated susceptibility level
when assembled into a
mouse with shielded cable
and following Agilent
recommendations.
• Passes EN61000-4-4/IEC8014 EFT tests when assembled
into a mouse with shielded
cable and following Agilent
recommendations.
• UL flammability level UL94
V-0.
• Provides sufficient ESD
creepage/clearance distance
to avoid discharge up to
15kV when assembled into a
mouse according to usage
instructions above.
Sensor
Lens
2.40
0.094
Object Surface
Figure 9. Distance from lens reference plane to surface
9
Absolute Maximum Ratings
Parameter
Storage Temperature
Operating Temperature
Symbol Minimum Typical
TS
TA
-40
-15
Lead Solder Temp
Supply Voltage
VDD3
-0.5
ESD
Input Voltage
VIN
Output current
Iout
-0.5
Maximum Units
Notes
85
o
55
o
260
o
3.7
V
2
kV
All pins, human body model
MIL 883 Method 3015
VDD3+0.5
V
NPD, NCS, MOSI, SCLK, RESET, OSC_IN,
OSC_OUT, REFC.
20
mA
LED_CTRL, MISO
C
C
C
For 10 seconds,
1.6mm below seating plane.
Recommended Operating Conditions
Parameter
Symbol Minimum Typical
Maximum Units
Operating Temperature
TA
40
0
Power supply voltage
VDD3B
3.10
Power supply rise time
VRT
1
Supply noise (Sinusoidal)
VNB
Oscillator capable Frequency
fCLK
Serial Port Clock Frequency
3.30
3.60
Notes
°C
Volts
us
0 to 3.0V
30
80
mV p-p
10kHz- 300KHZ
300KHz-50MHz
25
MHz
Set by ceramic resonator
fSCLK
2
500
MHz
kHz
Active drive, 50% duty cycle
Open drain drive with pull-ups on,
50 pF load
Resonator Impedance
XRES
55
Ω
Distance from lens reference
plane to surface
Z
2.3
2.5
mm
Speed
S
0
Acceleration
A
Light level onto IC
IRRINC
Frame Rate
LED Drive Current
10
23
24
2.4
Results in ±0.2 mm DOF, See drawing
below
40
in/sec
@ 6469fps
15
g
@ 6469fps
20
24
100
120
6,000
7,200
6,000
7,200
mW/m2
λ
λ
λ
λ
FR
2000
6469
Frames/s See Frame_Period register section
ILED
10
mA
= 639
= 875
= 639
= 875
nm,
nm,
nm,
nm,
FR=1500 fps
FR=1500 fps
FR=6469 fps
FR=6469 fps
HLMP-ED80-XX000, bin N and brighter.
Maximum frame rate may not be
maintained on dark surfaces at the
minimum LED drive current
AC Electrical Specifications
Electrical Characteristics over recommended operating conditions. Typical values at 25 °C, VDD3=3.3V, fclk=24MHz.
Parameter
Symbol
VDD to RESET
tOP
Minimum Typical Maximum Units Notes
250
µs
From VDD = 3.0V to RESET sampled
Data delay after
RESET
tPU-RESET
35
ms
From RESET falling edge to valid motion data at 2000
fps and shutter bound 8290.
Input delay after reset TIN-RST
500
µs
From RESET falling edge to inputs active (NPD,
MOSI, NCS, SCLK)
Power Down
tPD
2.1
ms
From NPD falling edge to initiate the power down
cycle at 500fps (tpd = 1 frame period + 100ms )
Wake from NPD
tPUPD
75
ms
From NPD rising edge to valid motion data at 2000
fps and shutter bound 8290. Max assumes surface
change while NPD is low.
Data delay after NPD
tCOMPUTE
3.1
ms
From NPD rising edge to all registers contain data
from new images at 2000fps (see Figure 10) .
RESET pulse width
tPW-RESET
MISO rise time
tr-MISO
40
200
ns
MISO fall time
tf-MISO
40
µs
10
MISO delay after SCLK tDLY-MISO
CL = 50pF
200
ns
CL = 50pF
120
ns
From SCLK falling edge to MISO data valid, no load
conditions
MISO hold time
thold-MISO
250
ns
Data held until next falling SCLK edge
MOSI hold time
thold-MOSI
200
ns
Amount of time data is valid after SCLK rising edge
MOSI setup time
tsetup-MOSI
120
ns
From data valid to SCLK rising edge
SPI time between
write commands
tSWW
50
µs
From rising SCLK for last bit of the first data byte, to
rising SCLK for last bit of the second data byte.
SPI time between
write and read
commands
tSWR
50
µs
From rising SCLK for last bit of the first data byte, to
rising SCLK for last bit of the second address byte.
SPI time between read tSRW
and subsequent
tSRR
commands
250
ns
From rising SCLK for last bit of the first data byte, to
falling SCLK for first bit of the second address byte.
SPI read address-data tSRAD
delay
50
µs
From rising SCLK for last bit of the address byte, to
falling SCLK for first bit of data being read. All
registers except Motion & Motion_Burst
SPI motion read
address-data delay
tSRAD-MOT
75
µs
From rising SCLK for last bit of the address byte, to
falling SCLK for first bit of data being read. Applies to
0x02 Motion, and 0x50 Motion_Burst, registers
NCS to SCLK active
tNCS-SCLK
120
ns
From NCS falling edge to first SCLK rising edge
SCLK to NCS inactive tSCLK-NCS
120
ns
From last SCLK falling edge to NCS rising edge, for
valid MISO data transfer
ns
From NCS rising edge to MISO high-Z state
NCS to MISO high-Z
tNCS-MISO
250
SROM download and tLOAD
frame capture byte-tobyte delay
10
µs
(see Figure 23 and 24)
NCS to burst mode
exit
tBEXIT
4
µs
Time NCS must be held high to exit burst mode
Transient Supply
Current
IDDT
mA
Max supply current during a VDD3 ramp from 0 to 3.6V
11
85
DC Electrical Specifications
Electrical Characteristics over recommended operating conditions. Typical values at 25 °C, VDD3=3.3V, fclk=24MHz.
Parameter
Symbol Minimum Typical Maximum Units Notes
DC Supply Current
IDD_AVG
Power Down
Supply Current
IDDPD
Input Low Voltage
VIL
Input High Voltage
VIH
5
52
mA
DC average at 6469 fps. No DC load on LED_CTRL,
MISO.
90
µA
NPD=GND; SCLK, MOSI, NCS=GND or VDD3;
RESET=GND
0.8
0.7 * VDD3
V
SCLK, MOSI, NPD, NCS, RESET
V
SCLK, MOSI, NPD, NCS, RESET
Input hysteresis
VI_HYS
200
mV
SCLK, MOSI, NPD, NCS, RESET
Input current,
pull-up disabled
IIH_DPU
0
±10
µA
Vin=0.8*VDD3, SCLK, MOSI, NCS
Input current,
CMOS inputs
IIH
0
±10
µA
NPD, RESET, Vin=0.8*VDD3
300
600
µA
Vin=0.2V, SCLK, MOSI, NCS
0.5
V
Iout=2mA, LED_CTRL
V
Iout=-2mA, LED_CTRL
V
Iout=2mA, MISO
V
Iout=-2mA, MISO
pF
OSC_IN, OSC_OUT
Output current, pulled- IOH_PU
up inputs
150
Output Low Voltage
LED_CTRL
VOL,LED
Output High voltage,
LED_CTRL
VOH_LED
Output Low Voltage,
MISO
VOL
Output High Voltage,
MISO
VOH
Input Capacitance
CIN
0.8*VDD3
0.5
0.8*VDD3
14-22
Detail of NPD rising edge timing
NPD
Reset
Count
Oscillator Start
250 us
340 us
Frame
1
Frame
2
Frame
3
Frame
4
Frame
5
LED CURRENT
(shutter mode)
SCLK
590 us
Optional SPI transactions
with old image data
tCOMPUTE = 590us + 5 Frame Periods
Figure 10. NPD Rising Edge Timing Detail
12
Motion bit set if
motion was detected.
First read dX = dY = 0
Typical Performance Characteristics
Mean Resolution vs. Z (White Paper)
2000
White Paper
1800
Manila
Resolution (counts/inch)
1600
Burl
1400
Z
1200
Black Walnut
DOF
1000
Black Copy
DOF
800
600
OPERATING REGION
400
200
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
1
2
-0.
3
-0.
4
-0.
5
-0.
6
-0.
7
-0.
-0.
-0.
8
0
Distance from Nominal Focus (mm)
Maximum Distance (Mouse Count)
Figure 11. Mean Resolution vs. Z (White Paper)
Typical Path Deviation
Largest Single Perpendicular Deviation From A Straight Line At 45 Degrees
Path length = 4 inches; Speed = 6 ips; Resolution = 1600 cpi
50
45
White Paper
40
Manila
35
Burl
30
Black Walnut
Black Copy
25
20
15
10
5
0
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
Distance From Lens Reference Plane To Navigation Surface (mm)
Relationship of mouse count to distance = m (mouse count) / n (cpi)
eg: Deviation of 7 mouse count = 7/1600 = 0.004375 inch ~ 0.004 inch
where m = 7, n = 1600
Figure 12. Average error vs. Distance (mm)
13
3.2
1
0.9
Relative responsivity
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0
500
400
600
700
wavelength (nm)
800
900
1000
Figure 13. Relative responsivity
Average Supply Current vs Frame Rate VDD=3.6V
120%
100%
Relative Current
100%
88%
80%
72%
60%
51%
55%
40%
20%
0%
0
2000
Figure 14. Idd vs. Frame Rate
14
4000
Frame Rate (Hz)
6000
8000
Synchronous Serial Port
The synchronous serial port is
used to set and read
parameters in the ADNS-3080,
and to read out the motion
information. The serial port is
also used to load SROM data
into the ADNS-3080.
The port is a four-wire, serial
port. The host microcontroller always initiates
communication; the ADNS3080 never initiates data
transfers. The serial port
cannot be activated while the
chip is in power down mode
(NPD low) or reset (RESET
high). SCLK, MOSI, and NCS
may be driven directly by a
3.3V output from a microcontroller, or they may be
placed in an open drain
configuration by enabling onchip pull-up current sources.
The open drain drive allows
the use of a 5V microcontroller without any level
shifting components. The port
15
Chip Select Operation
pins may be shared with other
SPI slave devices. When the
NCS pin is high, the inputs are
ignored and the output is tristated.
The lines which comprise the
SPI port are:
SCLK: Clock input. It is always
generated by the master (the
micro- controller).
MOSI: Input data (Master Out/
Slave In).
MISO: Output data (Master In/
Slave Out).
NCS: Chip select input (active
low).
NCS needs to be low to
activate the serial port;
otherwise, MISO will be high-Z,
and MOSI & SCLK will be
ignored. NCS can also be used
to reset the serial port in case
of an error.
The serial port is activated
after NCS goes low. If NCS is
raised during a transaction,
the entire transaction is
aborted and the serial port
will be reset. This is true for
all transactions including
SROM download. After a
transaction is aborted, the
normal address-to-data or
transaction-to-transaction
delay is still required before
beginning the next transaction.
To improve communication
reliability, all serial
transactions should be framed
by NCS. In other words, the
port should not remain
enabled during periods of nonuse because ESD and EFT/B
events could be interpreted as
serial communication and put
the chip into an unknown
state. In addition, NCS must
be raised after each burstmode transaction is complete
to terminate burst-mode. The
port is not available for
further use until burst-mode is
terminated.
Write Operation
Read Operation
Write operation, defined as
data going from the microcontroller to the ADNS-3080,
is always initiated by the
micro-controller and consists
of two bytes. The first byte
contains the address (seven
bits) and has a “1” as its MSB
to indicate data direction. The
second byte contains the data.
The ADNS-3080 reads MOSI on
rising edges of SCLK.
A read operation, defined as
data going from the ADNS3080 to the micro-controller, is
always initiated by the microcontroller and consists of two
bytes. The first byte contains
the address, is sent by the
micro-controller over MOSI,
and has a “0” as its MSB to
indicate data direction. The
second byte contains the data
and is driven by the ADNS3080 over MISO. The sensor
outputs MISO bits on falling
edges of SCLK and samples
MOSI bits on every rising edge
of SCLK.
SCLK
NOTE:
The 250 ns minimum high state of
SCLK is also the minimum MISO data
hold time of the ADNS-3080. Since
the falling edge of SCLK is actually the
start of the next read or write
command, the ADNS-3080 will hold
the state of data on MISO until the
falling edge of SCLK.
MOSI
tHold,MOSI
SCLK
tHOLD-MISO
tSetup, MOSI
tDLY-MISO
Figure 15. MOSI setup and hold time
D0
MISO
Figure 18. MISO delay and hold time
NCS
1
2
1
A
3
4
5
6
7
8
9
10
12
11
13
15
14
16
1
2
1
A
SCLK
MOSI
6
A
5
A
4
A
A
3
A
2
A
1
0
D
7
D
D
6
5
D
4
D
3
D
2
D
D
1
0
MISO
MOSI Driven by Micro-Controller
Figure 16. Write Operation
NCS
SCLK
Cycle #
1
2
3
4
5
6
7
A6
A5
A4
A3
A2
A1
8
9
10
D7
D6
11
12
13
14
D4
D3
D2
15
16
SCLK
MOSI
0
MISO
Figure 17. Read operation
16
A0
tSRAD delay
D5
D1
D0
6
Required timing between Read and Write Commands (tsxx)
There are minimum timing requirements between read and write commands on the serial port.
tSWW ≥ 50µs
SCLK
Address
Data
Address
Write Operation
Data
Write Operation
Figure 19. Timing between two write commands
If the rising edge of the SCLK for the last data bit of the second write command occurs before
the 50 microsecond required delay, then the first write command may not complete correctly.
tSWR ≥ 50µs
SCLK
Address
Data
Address
Write Operation
Next Read
Operation
Figure 20. Timing between write and read commands
If the rising edge of SCLK for the last address bit of the read command occurs before the 50
microsecond required delay, the write command may not complete correctly.
tSRW & tSRR > 250 ns
tSRAD ≥ 50 µs for non-motion read
tSRAD-MOT ≥ 75 µs for register 0x02
SCLK
Address
Data
Read Operation
Address
Next Read or
Write Operation
Figure 21. Timing between read and either write or subsequent read commands
The falling edge of SCLK for the first address bit of either the read or write command must be at
least 250 ns after the last SCLK rising edge of the last data bit of the previous read operation.
In addition, during a read operation SCLK should be delayed after the last address bit to ensure
that the ADNS-3080 has time to prepare the requested data.
17
Burst Mode Operation
Motion Read
Burst mode is a special serial
port operation mode which
may be used to reduce the
serial transaction time for
three predefined operations:
motion read and SROM
download and frame capture.
The speed improvement is
achieved by continuous data
clocking to or from multiple
registers without the need to
specify the register address,
and by not requiring the
normal delay period between
data bytes.
This mode is activated by
reading the Motion_Burst
register. The ADNS-3080 will
respond with the contents of
the Motion, Delta_X, Delta_Y,
SQUAL, Shutter_Upper,
Shutter_Lower and
Maximum_Pixel registers in
that order. After sending the
register address, the microcontroller must wait tSRAD-MOT
and then begin reading data.
All 56 data bits can be read
with no delay between bytes
by driving SCLK at the normal
rate. The data are latched
into the output buffer after the
last address bit is received.
After the burst transmission is
complete, the micro-controller
must raise the NCS line for at
least tBEXIT to terminate burst
mode. The serial port is not
available for use until it is
reset with NCS, even for a
second burst transmission.
tSRAD-MOT ≥ 75 µs
SCLK
Motion_Burst Register Address
Read First Byte
First Read Operation
Figure 22. Motion burst timing
18
Read Second Byte
Read Third Byte
SROM Download
This function is used to load
the Agilent-supplied firmware
file contents into the ADNS3080. The firmware file is an
ASCII text file with each 2character byte (hexadecimal
representation) on a single
line.
This mode is activated by the
following steps:
1. Perform hardware reset by
toggling the RESET pin
2. Write 0x44 to register 0x20
3. Write 0x07 to register 0x23
4. Write 0x88 to register 0x24
5. Wait at least 1 frame period
6. Write 0x18 to register 0x14
(SROM_Enable register)
7. Begin burst mode write of
data file to register 0x60
(SROM_Load register)
After the first data byte is
complete, the SROM or microcontroller must write
subsequent bytes by presenting
the data on the MOSI line and
driving SCLK at the normal
rate. A delay of at least tLOAD
must exist between data bytes
as shown. After the download
is complete, the microcontroller must raise the NCS
line for at least tBEXIT to
terminate burst mode. The
serial port is not available for
use until it is reset with NCS,
even for a second burst
transmission.
Agilent recommends reading
the SROM_ID register to verify
that the download was
successful. In addition, a
self-test may be executed,
which performs a CRC on the
SROM contents and reports the
results in a register. The test
is initiated by writing a
particular value to the
SROM_Enable register; the
result is placed in the
Data_Out register. See those
register descriptions for more
details.
Agilent provides the data file
for download; the file size is
1986 data bytes. The chip
will ignore any additional
bytes written to the
SROM_Load register after the
SROM file.
SROM file is now available for
download at Agilent’s website.
exit burst mode
tBEXIT ≥4µs
NCS
SROM_Enable reg write
3 reg writes, see text
MOSI
address
key data
SROM_Load reg write
address
byte 0
byte 1
byte 1985
address
enter burst
mode
≥1 frame
period
SCLK
tNCS-SCLK
>120ns
≥40µs
tLOAD
≥10µs
tLOAD
≥10µs
≥10µs
soonest to read SROM_ID
Figure 23. SROM download burst mode
19
≥100µs
Frame Capture
This is a fast way to download
a full array of pixel values
from a single frame. This
mode disables navigation and
overwrites any downloaded
firmware. A hardware reset is
required to restore navigation,
and the firmware must be
reloaded afterwards if
required.
To trigger the capture, write to
the Frame_Capture register.
The next available complete 1
2/3 frames (1536 values) will
be stored to memory. The data
are is retrieved by reading the
Pixel_Burst register once using
the normal read method, after
which the remaining bytes are
clocked out by driving SCLK at
the normal rate. The byte time
must be at least tLOAD. If the
Pixel_ Burst register is read
before the data is ready, it will
return all zeros.
To read a single frame, read a
total of 900 bytes. The next
636 bytes will be
approximately 2/3 of the next
frame. The first pixel of the
first frame (1st read) has bit 6
set to 1 as a start-of-frame
marker. The first pixel of the
second partial frame (901st
read) will also have bit 6 set
to 1. All other bytes have bit 6
set to zero. The MSB of all
bytes is set to 1. If the
Pixel_Burst register is read
past the end of the data (1537
reads and on) , the data
returned will be zeros.
After the download is
complete, the micro-controller
must raise the NCS line for at
least tBEXIT to terminate burst
mode. The read may be
aborted at any time by raising
NCS.
Alternatively, the frame data
can also be read one byte at a
time from the Frame_Capture
register. See the register
description for more
information.
exit burst mode
tBEXIT ≥4µs
NCS
pixel dump reg read
frame capture reg write
MOSI
address
data
frame capture reg
address
address
enter burst
mode
≥10µs
soonest to begin again
SCLK
tNCS-SCLK
>120ns
tCAPTURE
tSRAD ≥50µs
MISO
P0 bit 6 set to 1
tLOAD
tLOAD
≥10µs
≥10µs
P0
P1
all MSB = 1
P899
see note 2
Notes:
1. MSB = 1 for all bytes. Bit 6 = 0 for all bytes except pixel 0 of both frames which has bit 6 = 1 for use as a frame marker.
2. Reading beyond pixel 899 will return the first pixel of the second partial frame.
3. tCAPTURE = 10µs + 3 frame periods.
4. This figure illustrates reading a single complete frame of 900 pixels. An additional 636 pixels from the next frame are available.
Figure 24. Frame capture burst mode timing
20
The pixel output order as related to the surface is shown below.
Cable
Top Xray View of Mouse
Positive Y
LB
RB
Positive X
1
10
A3080
20
11
expanded view of the
surface as viewed
through the lens
last output
899 898 897 896 895 894 893 892 891 890 889 888 887 886 885 884 883 882 881 880 879 878 877 876 875 874 873 872 871 870
869 868 867 866 865 864 863 862 861 860 859 858 857 856 855 854 853 852 851 850 849 848 847 846 845 844 843 842 841 840
•
•
839 838 •
etc.
•
•
•
61 60
59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38
37 36 35 34 33 32 31 30
29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
7
9
8
6
5
4
3
2
1
0
first output
Figure 25. Pixel address map (surface referenced)
Error detection and recovery
1. The ADNS-3080 and the
micro-controller might get
out of synchronization due
to ESD events, power supply
droops or micro-controller
firmware flaws. In such a
case, the micro-controller
should pulse NCS high for
at least 1 ms. The ADNS3080 will reset the serial
port (but not the control
registers) and will be
prepared for the beginning
of a new transmission after
the normal transaction
delay.
2. Invalid addresses: Writing
to an invalid address will
have no effect. Reading from
an invalid address will
return all zeros.
21
3. Termination of a
transmission by the microcontroller may sometimes be
required (for example, due
to a USB suspend interrupt
during a read operation).
To accomplish this the
micro-controller should raise
NCS. The ADNS-3080 will
not write to any register
and will reset the serial port
(but not the control
registers) and be prepared
for the beginning of future
transmissions after NCS goes
low. The normal delays
between reads or writes
(tSWW, tswr, tSRAD, tSRAD-mot)
are still required after
aborted transmissions.
4. The micro-controller can
verify success of write
operations by issuing a read
command to the same
address and comparing
written data to read data.
5. The micro-controller can
verify the synchronization of
the serial port by
periodically reading the
product ID and inverse
product ID registers.
6. The microcontroller can read
the SROM_ID register to
verify that the sensor is
running downloaded SROM
code. ESD or similar noise
events may cause the sensor
to revert to native ROM
execution. If this should
happen, pulse RESET and
reload the SROM
instructions.
Notes on Power-up and the serial
port
Reset Circuit
The ADNS-3080 does not
perform an internal power up
self-reset. The reset pin must
be raised and lowered to reset
the chip. This should be done
every time power is applied.
During power-up there will be
a period of time after the
power supply is high but
before any clocks are available.
The table below shows the
state of the various pins
during power-up and reset
when the RESET pin is driven
high by a micro-controller.
Power Down Circuit
The following table lists the
pin states during power down.
The chip is put into the power
down (PD) mode by lowering
the NPD input. When in PD
mode, the oscillator is stopped
but all register contents are
retained. To achieve the
lowest current state, all inputs
must be held externally within
200mV of a rail, either ground
or VDD3. The chip outputs are
driven low or hi-Z during PD
to prevent current
consumption by an external
load.
LED Drive Mode
The LED has 2 modes of
operation: DC and Shutter. In
DC mode it is on at all times
the chip is powered except
when in the power down mode
via the NPD pin. In shutter
mode the LED is on only
during the portion of the
frame that light is required.
The LED_MODE bit in the
Configuration_bits register sets
the LED mode.
22
State of Signal Pins After VDD is Valid
Pin
Before Reset
During Reset
SPI pullups
Undefined
Off
NCS
Hi-Z control
Hi-Z control
functional
functional
MISO
Driven or hi-Z
Driven or hi-Z
(per NCS)
(per NCS)
SCLK
Undefined
Ignored
MOSI
Undefined
Ignored
LED_CTRL
Undefined
Low
RESET
Functional
High
(externally driven)
NPD
Undefined
Ignored
State of Signal
Pin
SPI pullups
NCS
MISO
SCLK
MOSI
LED_CTRL
RESET
NPD
REFC
OSC_IN
OSC_OUT
Pins During Power Down
NPD low
off
hi-Z control functional
low or hi-Z (per NCS)
ignored
ignored
low
functional
low (driven externally)
VDD3
low
high
After Reset
On (default)
Functional
Low or hi-Z
(per NCS)
Functional
Functional
High
Functional
Functional
After wake from PD
pre-PD state
functional
pre-PD state or hi-Z
functional
functional
high
functional
functional
REFC
OSC_IN
OSC_OUT
Registers
The ADNS-3080 registers are accessible via the serial port. The registers are used to read motion
data and status as well as to set the device configuration.
Address
Register
Read/Write
SROM Default Value
0x00
Product_ID
R
0x17
0x01
Revision_ID
R
0xNN
0x02
Motion
R
0x00
0x03
Delta_X
R
0x00
0x04
Delta_Y
R
0x00
0x05
SQUAL
R
0x00
0x06
Pixel_Sum
R
0x00
0x07
Maximum_Pixel
R
0x00
0x08
Reserved
0x09
Reserved
0x0a
Configuration_bits
R/W
0x09
0x0b
Extended_Config
R/W
0x00
0x0c
Data_Out_Lower
R
Any
0x0d
Data_Out_Upper
R
Any
0x0e
Shutter_Lower
R
0x85
0x0f
Shutter_Upper
R
0x00
0x10
Frame_Period_Lower
R
Any
0x11
Frame_Period_Upper
R
Any
0x12
Motion_Clear
W
Any
0x13
Frame_Capture
R/W
0x00
0x14
SROM_Enable
W
0x00
0x15
Reserved
0x16
Reserved
0x17
Reserved
0x18
Reserved
0x19
Frame_Period_Max_Bound Lower
R/W
0xE0
0x1a
Frame_Period_Max_Bound_Upper
R/W
0x2E
0x1b
Frame_Period_Min_Bound_Lower
R/W
0x7E
0x1c
Frame_Period_Min_Bound_Upper
R/W
0x0E
0x1d
Shutter_Max_Bound_Lower
R/W
0x00
0x1e
Shutter_Max_Bound_Upper
R/W
0x20
0x1f
SROM_ID
R
0x00
0x20-0x3c
Reserved
R/W
0x00
0x3d
Observation
0x3e
Reserved
0x3f
Inverse Product ID
R
0xF8
0x40
Pixel_Burst
R
0x00
0x50
Motion_Burst
R
0x00
0x60
SROM_Load
W
Any
23
Product_ID
Address: 0x00
Access: Read
Reset Value: 0x17
Bit
7
6
5
4
3
2
1
0
Field
PID7
PID6
PID5
PID4
PID3
PID2
PID1
PID0
Data Type:
8-Bit unsigned integer
USAGE: This register contains a unique identification assigned to the ADNS-3080. The value in
this register does not change; it can be used to verify that the serial communications link is
functional.
Revision_ID
Address: 0x01
Access: Read
Reset Value: 0xNN
Bit
7
6
5
4
3
2
1
0
Field
RID7
RID6
RID5
RID4
RID3
RID2
RID1
RID0
Data Type: 8-Bit unsigned integer.
USAGE: This register contains the IC revision. It is subject to change when new IC versions are
released.
NOTE: The downloaded SROM firmware revision is a separate value and is available in the
SROM_ID register.
Motion
Address: 0x02
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
MOT
Reserved
Reserved
OVF
Reserved
Reserved
Reserved
RES
Data Type: Bit field.
USAGE: Register 0x02 allows the user to determine if motion has occurred since the last time it
was read. If so, then the user should read registers 0x03 and 0x04 to get the accumulated
motion. It also tells if the motion buffers have overflowed, and the current resolution setting.
Field Name
Description
MOT
Motion since last report or PD
0 = No motion
1 = Motion occurred, data ready for reading in Delta_X and Delta_Y registers
Reserved
Reserved
Reserved
Reserved
OVF
Motion overflow, Delta_Y and/or Delta_X buffer has overflowed since last report
0 = no overflow
1 = Overflow has occurred
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
RES
Resolution in counts per inch
0 = 400
1 = 1600
24
Notes for Motion:
1. Reading this register freezes the Delta_X and Delta_Y register values. Read this register before reading the Delta_X and Delta_Y registers. If
Delta_X and Delta_Y are not read before the motion register is read a second time, the data in Delta_X and Delta_Y will be lost.
2. Agilent RECOMMENDS that registers 0x02, 0x03 and 0x04 be read sequentially. See Motion burst mode also.
3. Internal buffers can accumulate more than eight bits of motion for X or Y. If either one of the internal buffers overflows, then absolute path data is
lost and the OVF bit is set. This bit is cleared once some motion has been read from the Delta_X and Delta_Y registers, and if the buffers are not at
full scale. Since more data is present in the buffers, the cycle of reading the Motion, Delta_X and Delta_Y registers should be repeated until the
motion bit (MOT) is cleared. Until MOT is cleared, either the Delta_X or Delta_Y registers will read either positive or negative full scale. If the
motion register has not been read for long time, at 400 cpi it may take up to 16 read cycles to clear the buffers, at 1600 cpi, up to 64 cycles.
Alternatively, writing to the Motion_Clear register (register 0x12) will clear all stored motion at once.
Delta_X
Address: 0x03
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
X7
X6
X5
X4
X3
X2
X1
X0
Data Type: Eight bit 2’s complement number.
USAGE: X movement is counts since last report. Absolute value is determined by resolution.
Reading clears the register.
Motion
-128
-127
-2
-1
0
+1
+2
+126
+127
80
81
FE
FF
00
01
02
7E
7F
Delta_X
Delta_Y
Address: 0x04
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
Y7
Y6
Y5
Y4
Y3
Y2
Y1
Y0
Data Type: Eight bit 2’s complement number.
USAGE: Y movement is counts since last report. Absolute value is determined by resolution.
Reading clears the register.
Motion
-128
-127
-2
-1
0
+1
+2
+126
+127
Delta_Y
80
81
FE
FF
00
01
02
7E
7F
25
SQUAL
Address: 0x05
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
SQ7
SQ6
SQ5
SQ4
SQ3
SQ2
SQ1
SQ0
Data Type: Upper 8 bits of a 10-bit unsigned integer.
USAGE: SQUAL (Surface Quality) is a measure of ¼ of the number of valid* features visible by
the sensor in the current frame. Use the following formula to find the total number of valid
features.
Number of features = SQUAL register value *4
The maximum SQUAL register value is 169. Since small changes in the current frame can result
in changes in SQUAL, variations in SQUAL when looking at a surface are expected. The graph
below shows 250 sequentially acquired SQUAL values, while a sensor was moved slowly over
white paper. SQUAL is nearly equal to zero, if there is no surface below the sensor. SQUAL is
typically maximized when the navigation surface is at the optimum distance from the imaging lens
(the nominal Z-height).
Squal Values (White Paper)
85
SQUAL Value
80
75
70
65
60
0
25
50
Figure 26. Squal values (white paper)
26
75
100
125
150
175
200
225
250
Mean SQUAL vs Z (White Paper)
90
Avg
Avg - 3sigma
Avg + 3sigma
80
70
SQUAL
60
50
40
30
20
10
0
-1.0
-0.8
-0.6
-0.4
-0.2
0.0
0.2
0.4
0.6
0.8
1.0
Delta from Nominal Focus (mm)
Figure 27. Mean squal vs. Z (white paper)
Pixel_Sum
Address: 0x06
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
AP7
AP6
AP5
AP4
AP3
AP2
AP1
AP0
Data Type: High 8 bits of an unsigned 16-bit integer.
USAGE: This register is used to find the average pixel value. It reports the upper byte of a 16bit counter which sums all 900 pixels in the current frame. It may be described as the full sum
divided by 256. To find the average pixel value, use the following formula:
Average Pixel = Register Value * 256 / 900 = Register Value/3.51
The maximum register value is 221 (63 * 900/256 truncated to an integer). The minimum is 0.
The pixel sum value can change on every frame.
Maximum_Pixel
Address: 0x07
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
0
0
MP5
MP4
MP3
MP2
MP1
MP0
Data Type: Six bit number.
USAGE: Maximum Pixel value in current frame. Minimum value = 0, maximum value = 63. The
maximum pixel value can vary with every frame.
Reserved
Address: 0x08
Reserved
Address: 0x09
27
Configuration_bits
Address: 0x0a
Access: Read/Write
Reset Value: 0x09
Bit
7
6
5
4
3
2
1
0
Field
0
LED_MODE
Sys Test
RES
Reserved
Reserved
Reserved
Reserved
Data Type: Bit field
USAGE: Register 0x0a allows the user to change the configuration of the sensor. Shown below are
the bits, their default values, and optional values.
Field Name
Description
BIT 7
Must always be zero
LED_MODE
LED Shutter Mode
0 = Shutter mode off (LED always on)
1 = Shutter mode on (LED only on when illumination is required)
Sys Test
System Tests
0 = no tests
1 = perform all system tests, output 16 bit CRC via Data_Out_Upper and Data_Out_Lower
registers.
NOTE: The test will fail if SROM is loaded. Perform a hardware reset before executing this test.
Reload SROM after the test is completed.
NOTE: Since part of the system test is a RAM test, the RAM and SRAM will be overwritten with
the default values when the test is done. If any configuration changes from the default are
needed for operation, make the changes AFTER the system test is run. The system test takes
200ms (@24MHz) to complete.
NOTE: Do not access the Synchronous Serial Port during system test.
RES
Resolution in counts per inch
0 = 400
1 = 1600
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
28
Extended_Config
Address: 0x0b
Access: Read/Write
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
Busy
Reserved
Reserved
Reserved
Reserved
Serial_NPU
NAGC
Fixed_FR
Data Type: Bit field
USAGE: Register 0x0b allows the user to change the configuration of the sensor. Shown below are
the bits, their default values, and optional values.
Field Name
Description
Busy
Read-only bit. Indicates if it is safe to write to one or more of the following registers:
Frame_Period_Max_Bound_Upper and Lower
Frame_Period_Min_Bound_Upper and Lower
Shutter_Max_Bound_Upper and Lower
After writing to the Frame_Period_Max_Bound_Upper register, at least two frames must pass
before writing again to any of the above registers. This bit may be used in lieu of a timer since
the actual frame rate may not be known when running in auto mode.
0 = writing to the registers is allowed
1 = do not write to the registers yet
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Serial_NPU
Disable serial port pull-up current sources
0 = no, current sources are on
1 = yes, current sources are off
NAGC
Disable AGC. Shutter will be set to the value in the Shutter_Max_Bound registers.
0 = no, AGC is active
1 = yes, AGC is disabled
Fixed_FR
Fixed frame rate (disable automatic frame rate control). When this bit is set, the frame rate will
be determined by the value in the Frame_Period_Max_Bound registers.
0 = automatic frame rate
1 = fixed frame rate
29
Data_Out_Lower
Address: 0x0c
Access: Read
Reset Value: Undefined
Bit
7
6
5
4
3
2
1
0
Field
DO7
DO6
DO5
DO4
DO3
DO2
DO1
DO0
Data_Out_Upper
Address: 0x0d
Access: Read
Reset Value: Undefined
Bit
7
6
5
4
3
2
1
0
Field
DO15
DO14
DO13
DO12
DO11
DO10
DO9
DO8
Data Type: Sixteen bit word.
USAGE: Data in these registers come from the system self test or the SROM CRC test.
can be read out 0x0d, or 0x0d first, then 0x0c.
Data_Out_Upper
Data_Out_Lower
System test results:
0x1B
0xBF
SROM CRC Test Result:
0xBE
0xEF
The data
System Test: This test is initiated via the Configuration_Bits register. It performs several tests to
verify that the hardware is functioning correctly. Perform a hardware reset just prior to running
the test. SROM contents and register settings will be lost.
SROM CRC Test: Performs a CRC on the SROM contents. The test is initiated by writing a
particular value to the SROM_Enable register.
Shutter_Lower
Address: 0x0e
Access: Read
Reset Value: 0x85
Bit
7
6
5
4
3
2
1
0
Field
S7
S6
S5
S4
S3
S2
S1
S0
Shutter_Upper
Address: 0x0f
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
S15
S14
S13
S12
S11
S10
S9
S8
Data Type: Sixteen bit unsigned integer.
USAGE: Units are clock cycles. Read Shutter_Upper first, then Shutter_Lower. They should be
read consecutively. The shutter is adjusted to keep the average and maximum pixel values within
normal operating ranges. The shutter value is checked and automatically adjusted to a new value
if needed on every frame when operating in default mode. When the shutter adjusts, it changes
by ± 1/16 of the current value. The shutter value can be set manually by setting the AGC mode
to Disable using the Extended_Config register and writing to the Shutter_Maximum_Bound
registers. Because the automatic frame rate feature is related to shutter value. It may also be
appropriate to enable the Fixed Frame Rate mode using the Extended_Config register.
Shown below is a graph of 250 sequentially acquired shutter values, while the sensor was moved
slowly over white paper.
30
Mean Shutter vs Z (White Paper)
120
Shutter value (counts)
100
80
60
40
Avg
20
Avg - 3sigma
Avg + 3sigma
0
-1.0
-0.8
-0.6
-0.4
-0.2
0.0
0.2
0.4
0.6
0.8
1.0
Distance from Nominal Focus (mm)
Figure 28. Mean shutter vs. Z (white paper)
The maximum value of the shutter is dependent upon the setting in the Shutter_Max_Bound_
Upper and Shutter_Max_Bound_Lower registers.
31
Frame_Period_Lower
Address: 0x10
Access: Read
Reset Value: Undefined
Bit
7
6
5
4
3
2
1
0
Field
FP7
FP6
FP5
FP4
FP3
FP2
FP1
FP0
Frame_Period_Upper
Address: 0x11
Access: Read
Reset Value: Undefined
Bit
7
6
5
4
3
2
1
0
Field
FP15
FP14
FP13
FP12
FP11
FP10
FP9
FP8
Data Type: Sixteen bit unsigned integer.
USAGE: Read these registers to determine the current frame period and to calculate the frame
rate. Units are clock cycles. The formula is
Frame Rate = Clock Frequency/Register value
To read from the registers, read Frame_Period_Upper first followed by Frame_Period Lower.
To set the frame rate manually, disable automatic frame rate mode via the Extended_Config
register and write the desired count value to the Frame_Period_Maximum_Bound registers.
The following table lists some Frame_Period values for popular frame rates with a 24MHz clock.
Counts
Frame_Period
Frames/second
Decimal
Hex
Upper
Lower
6469
3,710
OE7E
OE
7E
5000
4,800
12C0
12
C0
3000
8,000
1F40
1F
40
2000
12,000
2EE0
2E
E0
Motion_Clear
Address: 0x12
Access: Write
Reset Value: Undefined
Data Type: Any.
USAGE: Writing any value to this register will cause the Delta_X, Delta_Y, and internal motion
registers to be cleared. Use this as a fast way to reset the motion counters to zero without
resetting the entire chip.
32
Frame_Capture
Address: 0x13
Access: Read/Write
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
FC7
FC6
FC5
FC4
FC3
FC2
FC1
FC0
Data Type: Bit field
USAGE: Writing 0x83 to this register will cause the next available complete 1 2/3 frames of pixel
values to be stored to SROM RAM. Writing to this register is required before using the Frame
Capture burst mode to read the pixel values (see the Synchronous Serial Port section for more
details). Writing to this register will stop navigation and cause any firmware loaded in the SROM
to be overwritten. A hardware reset is required to restore navigation, and the firmware must be
reloaded using the SROM Download burst method.
This register can also be used to read the frame capture data. The same data available by reading
the Pixel_Burst register using burst mode is available by reading this register in the normal
fashion. The data pointer is automatically incremented after each read so all 1536 pixel values (1
and 2/3 frames) may be obtained by reading this register 1536 times in a row. Both methods
share the same pointer such that reading pixel values from this register will increment the pointer
causing subsequent reads from the Pixel_Burst register (without initiating a new frame dump) to
start at the current pointer location. This register will return all zeros if read before the frame
capture data is ready. See the Frame Capture description in the Synchronous Serial Port section
for more information.
This register will not retain the last value written. Reads will return zero or frame capture data.
SROM_Enable
Address: 0x14
Access: Write
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
SE7
SE6
SE5
SE4
SE3
SE2
SE1
SE0
Data Type: 8-bit number.
USAGE: Write to this register to start either SROM download or SROM CRC test.
Write 0x18 to this register before downloading SROM firmware to the SROM_Load register. The
download will not be successful unless this register contains the correct value.
Write 0xA1 to start the SROM CRC test. Wait 7ms plus one frame period , then read result from
the Data_Out_Lower and Data_Out_Upper registers. Navigation is halted and the SPI port should
not be used during this test.
Reserved
33
Address: 0x15 – 0x18
Frame_Period_Max_Bound_Lower
Address: 0x19
Access: Read/Write
Reset Value: 0xE0
Bit
7
6
5
4
3
2
1
0
Field
FBm7
FBm6
FBm5
FBm4
FBm3
FBm2
FBm1
FBm0
Frame_Period_Max_Bound_Upper
Address: 0x1A
Access: Read/Write
Reset Value: 0x2E
Bit
7
6
5
4
3
2
1
0
Field
FBm15
FBm14
FBm13
FBm12
FBm11
FBm10
FBm9
FBm8
Data Type: 16-bit unsigned integer.
USAGE: This value sets the maximum frame period (the MINIMUM frame rate) which may be
selected by the automatic frame rate control, or sets the actual frame period when operating in
manual mode. Units are clock cycles. The formula is
Frame Rate = Clock Frequency / Register value
To read from the registers, read Upper first followed by Lower. To write to the registers, write
Lower first, followed by Upper. To set the frame rate manually, disable automatic frame rate
mode via the Extended_Config register and write the desired count value to these registers.
Writing to the Frame_Period_Max_Bound_Upper and Lower registers also activates any new values
in the following registers:
• Frame_Period_Max_Bound_Upper and Lower
• Frame_Period_Min_Bound_Upper and Lower
• Shutter_Max_Bound_Upper and Lower
Any data written to these registers will be saved but will not take effect until the write to the
Frame_Period_Max_Bound_Upper and Lower is complete. After writing to this register, two
complete frame times are required to implement the new settings. Writing to any of the above
registers before the implementation is complete may put the chip into an undefined state
requiring a reset. The “Busy” bit in the Extended_Config register may be used in lieu of a timer
to determine when it is safe to write. See the Extended_Config register for more details.
The following table lists some Frame_Period values for popular frame rates (clock rate = 24MHz).
In addition, the three bound registers must also follow this rule when set to non-default values:
Frame_Period_Max_Bound ≥ Frame_Period_Min_Bound + Shutter_Max_Bound.
Counts
Frame_Period
Frames/second
Decimal
Hex
Upper
Lower
6469
3,710
OE7E
OE
7E
5000
4,800
12C0
12
C0
3000
8,000
1F40
1F
40
2000
12,000
2EE0
2E
E0
Frame_Period_Min_Bound_Lower
Address: 0x1B
Access: Read/Write
Reset Value: 0xAC (before SROM download)
0x7E (after SROM download)
Bit
7
6
5
4
3
2
1
0
Field
FBm7
FBm6
FBm5
FBm4
FBm3
FBm2
FBm1
FBm0
Frame_Period_Min_Bound_Upper
Address: 0x1C
Access: Read/Write
Reset Value: 0x0D (before SROM download)
0x0E (after SROM download)
Bit
7
6
5
4
3
2
1
0
Field
FBm15
FBm14
FBm13
FBm12
FBm11
FBm10
FBm9
FBm8
Data Type: 16-bit unsigned integer.
USAGE: This value sets the minimum frame period (the MAXIMUM frame rate) that may be
selected by the automatic frame rate control. Units are clock cycles. The formula is
Frame Rate = Clock Rate / Register value
To read from the registers, read Upper first followed by Lower. To write to the registers, write
Lower first, followed by Upper, then execute a write to the Frame_Period_Max_Bound_Upper and
Lower registers. The minimum allowed write value is 0x7E0E; the maximum is 0xFFFF.
Reading this register will return the most recent value that was written to it. However, the value
will take effect only after a write to the Frame_Period_Max_Bound_Upper and Lower registers.
After writing to Frame_Period_Max_Bound_Upper, wait at least two frame times before writing to
Frame_Period_Min_Bound_Upper or Lower again. The “Busy” bit in the Extended_Config register
may be used in lieu of a timer to determine when it is safe to write. See the Extended_Config
register for more details.
In addition, the three bound registers must also follow this rule when set to non-default values:
Frame_Period_Max_Bound ≥ Frame_Period_Min_Bound + Shutter_Max_Bound.
Shutter_Max_Bound_Lower
Address: 0x1D
Access: Read/Write
Reset Value: 0x8C (before SROM download)
0x00 (after SROM download)
Bit
7
6
5
4
3
2
1
0
Field
SB7
SB6
SB5
SB4
SB3
SB2
SB1
SB0
Shutter_Max_Bound_Upper
Address: 0x1E
Access: Read/Write
Reset Value: 0x20
Bit
7
6
5
4
3
2
1
0
Field
SB15
SB14
SB13
SB12
SB11
SB10
SB9
SB8
Data Type: 16-bit unsigned integer.
USAGE: This value sets the maximum allowable shutter value when operating in automatic mode.
Units are clock cycles. Since the automatic frame rate function is based on shutter value, the
value in these registers can limit the range of the frame rate control. To read from the registers,
read Upper first followed by Lower. To write to the registers, write Lower first, followed by
Upper, then execute a write to the Frame_Period_Max_Bound_Upper and Lower registers. To set
the shutter manually, disable the AGC via the Extended_Config register and write the desired
value to these registers.
Reading this register will return the most recent value that was written to it. However, the value
will take effect only after a write to the Frame_Period_Max_Bound_Upper and Lower registers.
After writing to Frame_Period_Max_Bound_Upper, wait at least two frame times before writing to
Shutter_Max_Bound_Upper or Lower again. The “Busy” bit in the Extended_Config register may be
used in lieu of a timer to determine when it is safe to write. See the Extended_Config register
for more details.
In addition, the three bound registers must also follow this rule when set to non-default values:
Frame_Period_Max_Bound ≥ Frame_Period_Min_Bound + Shutter_Max_Bound.
SROM_ID
Address: 0x1F
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
SR7
SR6
SR5
SR4
SR3
SR2
SR1
SR0
Data Type:8-Bit unsigned integer.
USAGE: Contains the revision of the downloaded Shadow ROM firmware. If the firmware has been
successfully downloaded and the chip is operating out of SROM, this register will contain the
SROM firmware revision, otherwise it will contain 0x00.
Note: The IC hardware revision is available by reading the Revision_ID register (register 0x01).
Reserved
Address: 0x20 – 0x3C
Observation
Address: 0x3D
Access: Read/Write
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
OB7
Reserved
OB5
Reserved
Reserved
Reserved
OB1
OB0
Data Type: Bit field
USAGE: Each bit is set by some process or action at regular intervals, or when the event occurs.
The user must clear the register by writing 0x00, wait an appropriate delay, and read the register.
The active processes will have set their corresponding bit(s). This register may be used as part
of a recovery scheme to detect a problem caused by EFT/B or ESD.
Field Name
Description
OB7
If set, chip is running SROM code
Reserved
Reserved
OB5
NPD pulse was detected
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
OB1
Set once per frame
OB0
Set once per frame
Reserved
Address: 0x3E
Inverse_Product_ID
Address: 0x3F
Access: Read
Reset Value: 0xF8
Bit
7
6
5
4
3
2
1
0
Field
NPID7
NPID6
NPID5
NPID4
NPID3
NPID2
NPID1
NPID0
Data Type: Inverse 8-Bit unsigned integer
USAGE: This value is the inverse of the Product_ID, located at the inverse address. It can be
used to test the SPI port.
Pixel_Burst
Address: 0x40
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
PB7
PB6
PB5
PB4
PB3
PB2
PB1
PB0
Data Type: Eight bit unsigned integer
USAGE: The Pixel_Burst register is used for high-speed access to all the pixel values from one
and 2/3 complete frame. See the Synchronous Serial Port section for use details.
Motion_Burst
Address: 0x50
Access: Read
Reset Value: 0x00
Bit
7
6
5
4
3
2
1
0
Field
MB7
MB6
MB5
MB4
MB3
MB2
MB1
MB0
Data Type: Various, depending on data
USAGE: The Motion_Burst register is used for high-speed access to the Motion, Delta_X, and
Delta_Y, SQUAL, Shutter_Upper, and Shutter_Lower and Maximum_Pixel registers. See the
Synchronous Serial Port section for use details.
SROM_Load
Address: 0x 60
Access: Write
Rset Value: N/A
Data Type: Eight bit unsigned integer
USAGE: The SROM_Load register is used for high-speed programming of the ADNS-3080 from an
external SROM or microcontroller. See the Synchronous Serial Port section for use details.
Read Also
ADNS-3080 Product Overview
ADNK-3080 Sample Kit
Relevant Application Notes
Application Note AN 5035*
Application Note AN 5034*
Application Note AN 5036*
* The application notes content are applicable for ADNS-3080 as well.
Ordering Information
Specify part number as follows:
ADNS-3080 = Sensor IC in a 20 pin plastic optical package, 20 per tube.
ADNB-3081 = Sensor IC and ADNS-2120 round lens bundle kit, 1000 pc incremental
ADNB-3082 = Sensor IC and ADNS-2120-001 trim lens bundle kit, 1000 pc incremental
ADNS-2120 = Round Optical Mouse Lens
ADNS-2120-001 = Trim Optical Mouse Lens
ADNS-2220 = LED Assembly Clip (Clear)
ADNS-2220-001 LED Assembly Clip (Black)
HLMP-ED80-XX000 = LED
www.agilent.com/
semiconductors
For product information and a complete list
of distributors, please go to our web site.
For technical assistance call:
Americas/Canada: +1 (800) 235-0312
Europe: +49 (0) 6441 92460
China: 10800 650 0017
Hong Kong: (+65) 6756 2394
India, Australia, New Zealand: (+65) 6755 1939
Japan: (+81 3) 3335-8152(Domestic/International), or 0120-61-1280(Domestic Only)
Korea: (+65) 6755 1989
Singapore, Malaysia, Vietnam, Thailand,
Philippines, Indonesia: (+65) 6755 2044
Taiwan: (+65) 6755 1843
Data subject to change.
Copyright © 2005 Agilent Technologies, Inc.
Obsoletes 5989-1830EN
June 30, 2005
5989-3422EN
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