LM9830VJD/NOPB National Semiconductor, LM9830VJD/NOPB Datasheet - Page 26

LM9830VJD/NOPB

Manufacturer Part Number

LM9830VJD/NOPB

Description

IC SCANNER COLOR DOC 100-TQFP

Manufacturer

National Semiconductor

Datasheet

1.LM9830VJDNOPB.pdf (45 pages)

Specifications of LM9830VJD/NOPB

Number Of Bits

Number Of Channels

Power (watts)

350mW

Voltage - Supply, Analog

Voltage - Supply, Digital

4.5 V ~ 5.5 V

Package / Case

100-TQFP, 100-VQFP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

*LM9830VJD
*LM9830VJD/NOPB
LM9830VJD

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Price

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Part Number:

LM9830VJD/NOPB

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the 2 bit DAC, shown in Figure 17.

3.2 MicroStep Mode

Microstepping is a technique of driving the stepper motor with a

staircase approximation of a sine wave, as shown in Figure 18.

This technique maximizes the torque of a given motor, resulting in

a higher maximum speed. In addition, it increases the resolution

of the stepper motor. If a stepper motor moves 3.6° per full step,

microstepping can create positions inside the 3.6°: 1.8°, 0.9°, or

0.45°, for example. This increases the maximum vertical resolu-

tion of the scanner. Microstepping also results in quieter motor

movement.

The amplitude of the microstepped sine wave is controlled by the

output of the stepper motor DAC (Figure 19). The current in the

stepper motor winding is measured as a voltage across the sense

resistor, and the transistor drive signals are pulse width modu-

lated (PWM) to force the average current through the winding

equal to V

PWM, and Register 57 controls the minimum time the driver is on

every period. Register 57 should be set as short as possible, the

driver only needs to be on long enough to mask any transient

Starting from

a dead stop

Scanning

Stopped

Scan Mode

DAC

Figure 18: Bipolar Microstepping Waveform

Figure 17: Full Step Current Control

SENSE

. Register 56 controls the frequency of the

0.5V for number of steps specified in

Kickstart Steps register (0-7). If

current - movement begins at 0.35V.

0.35V

0.125V for number of steps specified

in Hold Current Timeout register

(0 - 31), 0V after time out. If register

is 0 there is no hold current.

DAC Voltage

1 microstep

noise generated by the driver transistor turning on.

Figure 20 shows the LM9830’s DAC voltages. The peak current

through the stepper motor winding will be 0.5V/R

index is incremented every microstep (StepSize pixel periods).

3.3 Pause Behavior - Non-Reversing Mode

When the Full Steps to Reverse When Buffer is Full register is

0, the stepper motor simply stops moving when the Pause signal

is received, as shown in Figure 21. The line of data currently

being processed (section “a” in Figure 21) will continue to be pro-

cessed and stored in SRAM. Additional lines may be digitized and

stored as well, depending on the number programmed in the

Lines to Process After Pause Scan Signal register (Figure 22).

This value is different for different scanner designs and should be

empirically set to the value that minimizes the spacial distortion

created by the motor slowing down and stopping.

MicroStep

DAC A

DAC B

Figure 19: Stepper Motor Waveform - LM9830 Signals

Table Code

Pulse

Figure 20: Microstepping Current Control

-0

-1

-2

-3

-4

Figure 21: Stepper Motor Stopping

A (B)

Scanning

Pause

Signal

A (B)

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DAC Voltage

N/A

0.191V

0.353V

0.462V

0.500V

N/A

0.191V

0.353V

0.462V

0.500V

SENSE

. The table

LM9830VJD/NOPB National Semiconductor, LM9830VJD/NOPB Datasheet - Page 26

LM9830VJD/NOPB

Specifications of LM9830VJD/NOPB

Available stocks

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