Fluke PM6690 Скачать руководство пользователя страница 29

Страница: 29 / 200

Crossover Switch

This stage uses relays to direct the signal to the two compara-
tors. The following combinations are possible:

•

IN A to COMP A and IN B to COMP B

•

IN A to both COMP A and COMP B

•

IN B to both COMP A and COMP B

Comparator

The comparator converts the analog signal to a binary logic
signal, with ECL levels (-0.9 V and –1.7 V). The trigger point
is set by a voltage from the trigger level circuitry.
Temperature-compensated circuitry generates the voltages
that control the hysteresis of the comparator. A trimmer
potentiometer adjusts the hysteresis window.

Trigger Level Generation

Two 12-bit DACs in a single IC generate the two trigger levels
for Channel A resp. Channel B. A 2.5 V DC reference IC sup-
plies the reference voltage to the DACs. The DACs are con-
trolled by the processor over the SPI bus. The

5 V dynamic

range at the BNC of the input amplifier is converted to ap-
proximately

2.1 V at the comparator. This range must be

covered by the DAC. The voltage step from the DAC is ap-
proximately 1.2 mV, corresponding to 2.9 mV per step at the
BNC.

Closed Case Calibration

(CCC) is used for adjusting

the trigger levels. A known reference level is applied to the
BNC and the processor finds out the appropriate setting of the
DAC to match the reference level.

Logic Level Conversion

The signals from the comparators must be converted from
ECL levels to LVPECL levels. There are three converter cir-
cuits. One for Channel A , one for Channel B and one for the
Set-Reset channel. The two main channels are fed to a Set-Re-
set flip-flop to make one-channel measurements with variable
hysteresis possible. There is also a converter for the signal

from an optional prescaler. It has PECL levels (+4.1 V and
+3.4 V) that are converted to LVTTL levels (+2.4 V and 0 V).

Oscillator Circuits

The processor has a 32768 Hz crystal. An internal PLL in the
processor uses the 32 kHz signal to make the internal proces-
sor clock, approximately 30 MHz. The USB IC has a 6 MHz
crystal to make an internal clock and the GPIB IC has a 40
MHz crystal to make an internal clock.

The measurement reference oscillator (timebase) for the
timer/counter is a 10 MHz crystal oscillator or an optional
oven-controlled crystal oscillator (OCXO). Only one of these
is mounted. The user can also select an external reference sig-
nal, connected to the

External Reference Input

BNC on the

rear panel.

The standard oscillator consists of an inverter and a crystal.
The processor controls the frequency of the oscillator with a
PWM signal. The PWM signal is filtered to a DC level that
controls the capacitance of a capacitance diode. The varying
capacitance changes the frequency of the oscillator. The stan-
dard oscillator is adjusted with

Closed Case Calibration

. Ap-

ply a 10 MHz reference signal to Input A. The processor will
find the correct PWM signal to make the internal reference
frequency equal to the external reference frequency.

The optional oven-controlled oscillator is a complete oscilla-
tor in a small hermetic metal box. An internal accurate DC
voltage is available for use as a reference for a 12-bit DAC.
The filtered output voltage from the DAC sets the frequency
of the oven oscillator. The processor controls the DAC via the
SPI bus. The same

Closed Case Calibration

as for the stan-

dard oscillator is used. The oven oscillator is kept warm if the
line power is connected to the timer/counter, even if it is
switched off (in standby mode).

Hardware Functional Description 4-7

AC/DC

COUPL

ATT

IMP

LIMITER

IMP

CONV

LP FILTER

BUFFER

CROSSOVER

SWITCH