Novatech 425A Manuale utente

NOVATECH INSTRUMENTS 1 Rev 1.01, 425A Manual

INSTRUCTION MANUAL

Precision 350 MHz Synthesizer

Model 425A

Table of Contents

Section Page Contents

1.0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 . . . . . . . . . . . . . . . . . . . . . . . . . Description

2.0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 . . . . . . . . . . . . . . . . . . . . . . . Specifications

3.0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 . . . . . . . . . . . . . . . . . Hardware Installation

4.0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 . . . . . . . . . . . . . . . . . . . . . . . . . . .Operation

5.0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 . . . . . . . . . . . . . . . . . . Theory of Operation

6.0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 . . . . . . . . . . . . . . . . . . . . Performance Test

7.0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 . . . . . . . . . . . . . . . . . . . . . . . . . .Calibration

--. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 . . . . . . . . . . . . . . . . . . . . . . . . . . . Warranty

--. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 . . . . . . . . . . . . . . . . . . . . . Option E, Errata

NOVATECH INSTRUMENTS 2 Rev 1.01, 425A Manual

1.0 DESCRIPTION

1.1 The Model 425A is a 48-bit Direct Digital Syn-

thesized (DDS) Signal Generator in a small shielded

table top case with an asynchronous serial control

port (RS232). The 425A provides sine wave, LVDS

and LVCMOS output signals, which can be set from

250 kHz to 350 MHz in steps of 10 Hz per LSB

when using the internal VCTCXO clock

1.2 Relative phase is adjustable over the same inter-

face with 14-bits of resolution. Amplitude can be

fine trimmed over a 10-bit range from approxi-

mately 0.14 to 0.50 V

rms

into 50 .

1.3 The LVCMOS output is optimized for frequen-

cies up to 125 MHz and, when used with its pro-

grammable divider, provides square wave clock

signals down to lower than 2 Hz.

1.4 The 425A can also be used with an External

Clock or Reference input. The external source can

either be a 10.0 MHz reference, which is phase-

locked internally, or a direct input of 250 to 1000

MHz. When used with the same external clock

source, multiple 425A remain phase synchronous.

2.0 SPECIFICATIONS

2.1 OUTPUTS

TYPES: Sine, LVDS and LVCMOS simultaneously.

IMPEDANCE: 50 (100  differential for LVDS)

RANGE: 250 kHz to 350 MHz with 10 Hz resolu-

tion (internal clock).

SINE AMPLITUDE: full scale approximately +7 dBm

(0.50 Vrms) into 50  load. Settable from 0.14 to

0.50 V

rms

by the “V0” command. (14-bit DAC). ±3dB

referenced to amplitude at 100 MHz.

2.2 LVCMOS AMPLITUDE

<0.5 V, V

>2.0 V into a series-terminated

load.

r,f

<2.5 ns. Duty Factor: 40-60% (divider off). 50 

Programmable 16-bit divider with a selectable /2

prescaler allows LVCMOS frequencies below 2 Hz.

(LVCMOS optimized for frequencies <= 125 MHz)

2.3 LVDS AMPLITUDE

Meets EIA-644A specifications when terminated

into a 100  differential load (driver:

SN65LVDS100, or equivalent)

2.4 CONTROL

Output frequency (48-bits), phase (14-bits), CMOS

divider, and amplitude scaling (10-bits) are con-

trolled by a serial port. Settings can be saved in

EEPROM.

2.5 ACCURACY AND STABILITY

Accuracy: < ±1.5ppm at 10-40

C. Stable to an

additional ±2ppm per year, 18-28

2.6 EXTERNAL CLOCK/REFERENCE IN

Direct external clock frequency range of 250 to

1000 MHz or locked to a 10.0 MHz (±0.01%) refer-

ence. The 425A specifications depend upon the

quality of this signal.

Input Level (50 :

10 MHz Reference: 0.75-1.25 Vrms Sine or LVC-

MOS Square Wave.

External Clock: -3 to +6 dBm sine wave.

2.7 SPECTRAL PURITY

(Typical, 50 load, int.

clock)

Phase Noise:<-140 dBc, 10 kHz offset, 10 MHz out.

Spurious: <-70 dBc below 10 MHz

<-60 dBc below 50 MHz

<-55 dBc below 150 MHz

<-45 dBc below 350 MHz

Harmonic: <-65 dBc below 1 MHz

<-60 dBc below 10 MHz

<-55 dBc below 25 MHz

<-45 dBc below 50 MHz

<-40 dBc below 150 MHz

<-25 dBc below 350 MHz

2.8 POWER REQUIREMENTS

+4.75 to +5.25 V @ <750 mA. 2.5 mm center-

positive connector on rear panel. AC line (country

dependent) adapter provided.

2.9 SIZE

39 mm H, 107 mm W, 172 mm L, not including con-

nectors.

2.10 CONNECTORS

BNCs for SINE Out, LVCMOS Out, LVDS out, REF

IN. 2.5 mm center positive barrel connector for

Power. DE9 for serial control.

NOVATECH INSTRUMENTS 3 Rev 1.01, 425A Manual

3.0 HARDWARE INSTALLATION

3.1 Power Connection. Figure 1, shows the rear

panel of the 425A. The required power of +5 Volts

DC is applied through a 2.5mm center positive bar-

rel connector.

3.2 The quality of your power supply may affect the

performance of the 425A. The supply should be free

of ripple and noise (typically <50 mV). Even though

extensive filtering is used on the 425A board, a quiet

and well regulated power supply will ensure opti-

mum performance. If power supplies, other than the

Novatech Instruments provided one, are used, please

verify that your system noise requirement is met.

3.3 Internal Clock. If you plan to use the 425A

internal clock, which is the default mode, no setup

action is required. The on-board VCTCXO is multi-

plied in a phase-locked loop (PLL) to generate the

internal master clock for the DDS ASIC.

3.4 External Clock. There are two customer-sup-

plied clock modes. One (external reference select,

“C r”) uses an internal PLL to multiply an external

10.0 MHz reference to provide a 940.0 MHz master

clock. The other mode (external clock select, “C

e”) allows a 250 to 1000 MHz direct input. In this

mode, the PLL is disabled and the customer clock is

directly used as the master clock.

3.5 If you are providing an external clock or exter-

nal reference, apply your signal to the REF IN BNC

connector on the rear panel. Carefully observe the

amplitude requirements for each mode. Note that

phase noise and stability of the 425A are dependent

upon your supplied clock. Send the appropriate

clock select command to enable your input. This

automatically configures the internal clock circuitry

to generate the correct master clock.

3.6 Unless your external clock is an exact binary

multiple, non-fractional frequency steps will not be

possible, and your frequency settings will need to be

scaled. See Section 4.0, Operation, for scaling infor-

mation.

NOTE:

Consult Novatech Instruments if you require locking

to an external 10.00 MHz standard without round-

off.

3.7 Serial Port Interface Installation. The 425A is

controlled by using an asynchronous serial port

(RS232). Direct connections can be made from most

PCs using a 9-pin monitor extension (male to

female) cable or by using a USB to RS232 (DE9)

adapter. The rear panel connector is a 9-pin female.

3.8 If you are using a different computer, terminal

or other control source, please note that the data TO

the 425A is on pin 3; the data FROM the 425A is

on pin 2 and the COMMON return is on pin 5. Set

your host to 19.2 kBaud, 8 bits, 1 stop bit, no

parity and no hardware flow control.

3.9 Signal Outputs. There are three signal outputs

on the 425A: one channel each of Sine, differential

LVDS and LVCMOS. The outputs are provided on

front panel BNC receptacle connectors. Simply con-

nect your application cables to appropriate output.

The LVDS output requires 100  differential termi-

nation at the destination (internal driver:

SN65LVDS100 or equivalent). All the outputs are at

the same frequency, unless the divider (D0 and PR)

commands have been issued. The LVCMOS output

frequency depends upon the divider and prescaler

settings.

3.10 See Figures 3 and 4 for typical termination of

the LVDS and LVCMOS signals.

NOTE:

The LVCMOS signal is disable by default. Use the

“A e” command to enable it.

Figure 1: Rear Panel

NOVATECH INSTRUMENTS 4 Rev 1.01, 425A Manual

Serial Command Function

F0 xxx.xxxxxxxxxxx Set Frequency of output in MHz to nearest 10 Hz. Decimal point

required.

P0 N Set relative Phase of output sinewave. N is an integer from 0 to 16383.

Phase is set to N*360

/16384 or N*2/16384 radians. This is useful

when multiple Model 425A are running from the same clock source.

E x Serial echo control. x=D for Echo Disable, x=E for Echo Enable. Dis-

able echo for maximum serial port speed.

C x Select clock source. x=E for External 250 MHz to 1000 MHz direct

input; x=R for 10.0 MHz Reference; x=I for Internal temperature com-

pensated reference. The quality of the external reference affects the

specifications of the 425A. The “F0” command requires scaling (see

manual) for clocks other than the internal oscillator.

RReset. This command resets the 425A. EEPROM data is preserved

and, if valid, is used upon restart. This is the same as cycling power.

CLR Clear. This command clears the EEPROM valid flag and restores all

factory default values.

A x x=E for LVCMOS Enable, x=D for LVCMOS Disable. Default setting

is “D.”

D0 N Set Divider value on LVCMOS output. N is an integer from 0 to

65535. The output frequency set by the “F0” command is divided by

N+1 before being sent to the LVCMOS driver.

PR x x=E for Enable Prescaler, x=D for Disable Prescaler. When enabled,

the frequency set by the “F0” command is divided by 2 before enter-

ing the LVCMOS divider specified by the “D0” command. This

allows a maximum divide integer of 131072.

SSaves current state into EEPROM and sets valid flag. The saved state

is used as the initial values upon next power up or reset. Use the

“CLR” command to return to default values.

QUE Return present frequency, phase and status. Returns a character string

of all internal settings.

M N Mode command. Mode ‘M 0’ is single tone. (Only Mode 0 is

implemented at software Rev 1.5.)

V0 N Set Voltage level of output. In default, the amplitude is set to the

maximum of approximately 0.5 V

rms

(+7 dBm) into 50  N can range

from 0 to 1023 (no decimal point allowed). Voltage level is scaled

(multiplied) by:

0.27 + 0.19*N/264

If N >1023, the command is ignored and the level remains at its

previous setting (approximately 0.14 V

rms

to 0.50 V

rms

I x Set the I/O update pulse method. If x=a, then an I/O update is issued

automatically at the end of each serial command (default). If x=m, then

a manual I/O update pulse is expected to be sent by a subsequent

‘I p’ command.

B aabb[cc[dd[ee[ff[gg[...]]]]]]] This Byte command allows each register in the DDS chip to be set.

Different registers require a various number of bytes to be written

depending upon the instruction word “aabb”. Note that it is possible

to set the DDS chip into a non-functional mode, requiring a power

cycle to recover. All values are in hexadecimal and no error checking,

other than correct format, is performed.

NOVATECH INSTRUMENTS 5 Rev 1.01, 425A Manual

4.0 Operation

4.1 Power on reset. After power is applied, the

425A takes approximately 300 ms to perform its ini-

tialization sequence. Any communication during

this time will be ignored or may cause erroneous

operation.

4.2 Specifications are met within 15 minutes of

power-up in stable environment.

4.3 After the 425A has been installed in the cus-

tomer application system, all that is required for

operation is to send the appropriate data.

4.4 Serial commands are shown on the previous

page. The commands consist of a one or two charac-

ter alpha-numeric mnemonic separated from the

operand by a space. Some commands do not have an

operand, so the space is not necessary.

4.5 To facilitate use with various systems, the com-

mands can be terminated by a line feed (LF), car-

riage return (CR) or any combination.

4.6 The user host hardware must properly format

the asynchronous serial port data. Incorrect format-

ting will result in erroneous or erratic operation. See

Table 1 for Serial Error Codes. Not all error codes

are used in all versions.

4.7 If you are using an external clock, the frequency

value sent to the 425A command must be scaled.

4.8 The nominal Internal Clock has a value that pro-

duces a even step size of 10.0 Hz. Thus a scale fac-

tor is necessary to determine your exact output

frequency when using external clock sources. For

example, to obtain 10 MHz output when using a 10

MHz reference (940.0 MHz internal master clock),

your frequency setting would be:

setting

= F

desired

*0.998138215286 MHz

setting

= 9.98138215286

send: F0 9.98138215286

4.9 When used with an external clock of 250 MHz

to 1000 MHz (“C e” command), your setting will

be given by:

setting

= F

desired

*938.249922368853/(F

clk

) MHz

where F

clk

is your external clock in MHz.

NOTE:

You must account for your external clock frequency

accuracy and calculation round-off when using an

external clock. Most calculators have less than 48-

bits of resolution.

The noise and accuracy specifications are directly

affected by the quality of the external source. Unless

care is exercised, your specifications may be

degraded. Please verify your system requirements

with the chosen clock mode.

4.10 For example, if you were using an OC-12

clock of 622.08 MHz, and desire a 10 MHz output,

your calculation will be:

setting

= F

desired

*938.249922368853/(F

clk

) MHz

= 10.0*938.249922368853/622.08

= 15.08246402985

Send: F0 15.08246402985

4.11 Since the internal frequency resolution of the

425A is 48-bits, the typical fractional frequency

error (f/f) for output frequencies in the MHz range

will be on the order of 1x10

-12

, even when exact val-

ues are not possible due the round-off from the

external clock scaling. For the example, the 10.00

MHz error will be approximately 2 Hz when using

an external 10 MHz clock, resulting in 2x10

-13

f/f.

Table 1: Serial Error Codes

Error Code Meaning

OK Good command received (not sent for

R, CLR and QUE)

?0 Unrecognized Command

?1 Bad Frequency

?2 Bad AM Command

?3 Input line too long

?4 Bad Phase

?5 Bad Time

?6 Bad Mode

?7 Bad Amp

?8 Bad Constant

?f Bad Byte

NOVATECH INSTRUMENTS 6 Rev 1.01, 425A Manual

For many applications, this magnitude of the devia-

tion will be insignificant.

NOTE:

The frequency command is limited to a maximum

value of approximately 469.1 MHz, 50% of internal

clock. The filter -3dB cut-off is set to 375 MHz.

Distortion and roll-off will increase beyond 350

MHz, but the outputs may still be usable in your

application.

4.12 The relative phase of the output is settable to

14-bits of resolution. The relative phase shifts by:

Phase

out

= (P

setting

)*360

/16384

setting

= 0 to 16383.

4.13 The amplitude of the sine output can be

adjusted using the “V0 N” command. The 50  ter-

minated output amplitude as a function of the V0

setting is given by:

Amplitude = 0.5*[0.27+0.19*N/264] V

rms

approximately 0.14 to 0.5 V

rms

4.14 The LVCMOS output has a divide-by-2 pres-

caler followed by programmable 16-bit divider,

which allows the sinewave frequency to be divided

by integers up to 131,072. Your application fre-

quency may be created by various combinations of

the F0, D0 and Pr commands. You should experi-

ment to find the best performance range for your

application.

4.15 For example, if you desired a clock signal of

1.00 kHz, you could obtain it by setting F0 to 10.00

MHz and using at D0 value of 9,999.

4.16 The duty cycle of the LVCMOS output is

dependent upon the divide ratio. Odd divider values

(even D0 command values) give output symmetry

furthest from 50%. For example, a divide of 3 (“DO

2”) will result in a 33% duty factor. Even values

produce symmetrical duty cycle outputs. The pres-

caler setting does not affect the duty factor, since it

is before the programmable divider.

4.17 When the LVCMOS output is enabled, the

divider is set immediately upon the end of com-

mand. It is unaffected by the “I” command set-

tings.

NOTE:

The relative phase of the LVCMOS output with

respect to the Sine output is dependent upon

frequency and divide ratio settings.

4.18 A Baud rate command is available if you wish

to set a Baud rate different than the default value.

The value set by this command is volatile and not

saved in EEPROM to prevent loss of communica-

tion. Upon power up, reset or clear, the 425A reverts

to 19.2 kBaud.

4.19 Kb command examples, with the value in

hexadecimal:

Kb 78 ;9.6 kBaud

Kb 3c ;19.2 kBaud

Kb 1e ;38.4 kBaud

Kb 14 ;57.6 kBaud

Kb 0a ;115.2 kBaud

4.20 Depending upon your system requirements,

you may wish to enable non-standard Baud rates.

The formula for the Kb setting is:

Baud Rate = 1152/N kBaud

where N is the decimal value of the Kb command

hexadecimal value. N=0 is not allowed.

NOTE:

You will need to verify non-standard baud rates in

your system. Consult Novatech Instruments

regarding permanent setting of 115.2 kB.

4.21 The “QUE” command returns a two-line hexa-

decimal string which represents the present instru-

ment state. The default return values are:

02BA7DEF3000 0000 03FF 000000

2100 15

The meanings are:

02BA7DEF3000: binary 48-bit frequency

(scaled by 3 from serial input value)

0000: binary phase (max: 3FFF)

03FF: binary amplitude setting (max: 03FF)

000000: binary divider value (max FFFF)

NOVATECH INSTRUMENTS 7 Rev 1.01, 425A Manual

(Leading byte: 01=prescaler on)

2100: internal control registers

15: software revision as x.y, (1.5)

5.0 Theory of Operation

5.1 Please refer to the simplified System Block Dia-

gram in Figure 2 for the following discussion.

5.2 At every cycle of the 425A master clock, the 48-

bit Direct Digital Synthesizer (DDS) integrated cir-

cuit increments the phase of an internal accumulator

by a value determined by the frequency setting

loaded into the on-chip registers. This digital phase

value is converted on-chip to a sinusoidal amplitude

level and delivered to an on-chip 14-bit digital-to-

analog converter. The analog signal from this con-

verter is filtered by a 7th-order elliptical low pass

reconstruction filter, amplified and sent to the SINE

output connector.

5.3 The amplified Sine signal is diverted to a high-

speed zero crossing detector to generate the LVDS

output signal. The output of the detector is fed back

into the DDS IC to supply the clock for the internal

programmable divider.

5.4 The frequency generated by the DDS IC is

determined by the binary 48-bit frequency word

loaded into the frequency register on the 425A. The

output frequency is given by:

out

= F

binary

*(100/3)*F

clock

Where: F

clock

= 28,147,497.6710656 Hz (int.)

binary

= Binary value in DDS IC.

binary

ranges from 0 to 2

-1)

This reduces to:

out

= F

binary

*3.3333Hz

for the internal (default) clock settings. The binary

setting is the customer’s input setting scaled by a

factor of three and converted to a binary value with

the LSB having a weight of 10 Hz.

5.5 Since the DDS IC is a sampled data system, the

output frequency is limited to a maximum of 1/2 the

system clock frequency (F

binary

<=2

-1). While it is

possible to generate an output near 50% of the clock,

the distortion may be unacceptable. Therefore, the

output is limited to approximately 40% (approxi-

mately 350 MHz) of the system clock and a 7th-

order elliptical output filter is implemented on

board.

6.0 PERFORMANCE TEST

6.1 Install the 425A as directed in Section 3. Con-

nect your host controller and operate the 425A per

Section 4. The test limits assume a stable environ-

ment of 18-28

NOTE:

Allow the 425A to warm up for at least 15 minutes

before performing any measurements. For best

results, the 425A should be verified in an

environment similar to its application.

6.2 See Table 2 for a list of recommended test

equipment to perform the following measurements.

6.3 Verify Frequency Accuracy. To verify the fre-

quency of the 425A, set the output sequentially to

each value in Table 3, with the clock source set to

internal (“C i”). Connect the recommended fre-

quency counter set to 50  termination and 0.1 Hz

resolution. Verify the limits show in Table 3. If you

do not use an external frequency standard for the

frequency counter, be sure to add the error of your

Table 2: Recommended Test Equipment

Item

Minimum

Specification Recommended

Oscilloscope 500MHz, 50Tektronix

TDS3052C

Frequency

Counter

350MHz HP53132A

Counter Time

Base

10MHz,

0.1ppm

Novatech

Instruments

Model 1450B

External Clock 250-1000

MHz

Customer

supplied

NOVATECH INSTRUMENTS 8 Rev 1.01, 425A Manual

counter to the tolerance. (LSD = Least Significant

Digit on counter).

6.4 Sine Out Amplitude Verification. Set the fre-

quency of the 425A to 10 MHz. Connect the 425A

Sine Out to the oscilloscope set for 50  termina-

tion. Set the oscilloscope to measure to RMS voltage

using at least 16 averages. Verify a reading of 0.5

Vrms

0.1 Vrms.

6.5 Output Flatness Verification. Verify that the

outputs are flat with frequency by performing the

following test: Connect the 425A Sine Out to the

oscilloscope set for 50  termination. Use the same

setting up as the Sine Out Amplitude Verification.

Note the 100 MHz voltage reading.

6.6 Set the 425A to the values of Table 3. Verify

that the oscilloscope amplitude reading remains

within

3dB (a multiple of 1.414 to 0.707) of the

value noted in the previous paragraph.

6.7 External Clock Input Verification. Connect a

10.0 MHz external clock source via a short coaxial

cable to the REF IN BNC on the 425A rear panel.

Issue the “C r” command. Set the frequency to 10

MHz without scaling. Verify that your reference sig-

nal meets the requirements in the specifications.

Verify an output frequency reading of

10.0186525742 MHz. You will need to account for

the accuracy of your 10.00 MHz source and your

frequency counter.

6.8 If you are using a clock source of 250 MHz to

1000 MHz, you will have to calculate the proper

scaling per Section 4.

6.9 This concludes the verification test of the 425A.

7.0 CALIBRATION

7.1 The 425A has two user adjustable components:

Y2, frequency, and R37, output amplitude. Calibra-

tion should be performed only if the 425A fails the

performance test or if the unit has been repaired.

Routine adjustments are not recommended nor gen-

erally required. This procedure assumes that the

425A has failed the performance test or has been

repaired.

WARNING:

Calibration should be performed only by qualified

personnel. The on-board components are static

sensitive.

7.2 The adjustments shown are set to 1/2 the speci-

fication values.

NOTE:

Allow the 425A to warm up for at least 15 minutes

before performing any adjustments. For optimum

performance the 425A should be calibrated in an

environment similar to its installation.

7.3 Frequency Adjust, Y2. Set the output of the

425A to 10.000000 MHz. Connect your frequency

counter with its input set for 50  termination.

Adjust Y2 using a non-metallic adjustment tool for

10.000000 MHz, ±7.5 Hz.

7.4 Amplitude Adjust, R37. Connect the Sine out-

put to the oscilloscope set to measure RMS voltage,

with a minimum of 16 averages. Set the oscilloscope

for 50  input termination. Leave the 425A output

set to 10.00 MHz. Adjust R37 for 0.5 Vrms ±0.05

Vrms.

7.5 This completes the calibration of the Model

425A.

Table 3: Frequency Test Points

Frequency Tolerance

250 kHz

0.375 Hz

1 LSD

1 MHz

1.5 Hz

1 LSD

10 MHz

15 Hz

1 LSD

30 MHz

45 Hz

1 LSD

50 MHz

75 Hz

1 LSD

100 MHz

150 Hz

1 LSD

150 MHz

225 Hz

1 LSD

250 MHz

375 Hz

1 LSD

350 MHz

525 Hz

1 LSD

NOVATECH INSTRUMENTS 9 Rev 1.01, 425A Manual

POWER

LOGIC

48-Bit

DDS,

LP Filter AMP SINE

OUT

Buffer LVCMOS

OUT

POWER

FILTERS &

+5V

-5V

Master

Clock

EXT

CLK

CLK SEL

Figure 2.

Simplified System Block Diagram

425A

Serial CSystem Control

+1.8V

REGULATOR

AD9912

+5V

+3.3V

Buffer LVDS

OUT

100

Typical LVDS Driver, SN65LVDS100

Customer Supplied

LVDS+

LVDS-

50

Series Terminated LVCMOS

Customer Application

425A

50

Figure 3.

Figure 4.

NOVATECH INSTRUMENTS 10 Rev 1.01, 425A Manual

425A MANUAL ERRATA

OPTION /E, Remote Clock

Option E makes it possible to use multiple 425A and have the outputs from these 425A be phase

synchronous. Model 425A with Option E installed has the internal master 28MHz oscillator removed and

two rear mounted SMA connectors installed. One of the rear mounted SMA connectors, labeled CLK IN,

accepts a 28MHz clock signal from the 450A Clock Distribution Amplifier. The other rear mounted

SMA connector labeled IOUD is intended to enable a future feature. When option E is installed on a

425A, the user needs to connect the 28MHz internal clock signal from a Model 450A Clock Distribution

Amplifier to the 425A CLK IN SMA connector on the rear of the 425A and the 425A must be configured

for internal clock (C x command where x=I, see table on page 4).

CAUTION: The 425A rear SMA connectors are intended for use with low voltage signals. Do not apply

a voltage over 5.7Vpp AC on the CLK IN connector or you may damage the 425A.

WARRANTY

NOVATECH INSTRUMENTS warrants that all instruments it manufactures are free from defects in

material and workmanship and agrees to replace or repair any instrument found defective during a

period of one year from date of shipment to original purchaser.

This warranty is limited to replacing or repairing defective instruments that have been returned

by purchaser, at the purchaser's expense, to NOVATECH INSTRUMENTS and that have not

been subjected to misuse, neglect, improper installation, repair alteration or accident.

NOVATECH INSTRUMENTS shall have the sole right to final determination regarding the existence

and cause of a defect.

This warranty is in lieu of any other warranty, either expressed or implied, including but not

limited to any warranty of merchantability or fitness for a particular purpose. In no event shall seller

be liable for collateral or consequential damages. Some states do not allow limitations or

exclusion of consequential damages so this limitation may not apply to you.

All instruments manufactured by NOVATECH INSTRUMENTS should be inspected as soon

as they are received by the purchaser. If an instrument is damaged in shipment the

purchaser should immediately file a claim with the transportation company. Any instrument

returned to NOVATECH INSTRUMENTS should be shipped in its original shipping container or

other rigid container and supported with adequate shock absorbing material.

This warranty constitutes the full understanding between NOVATECH INSTRUMENTS and

the purchaser and no agreement extending or modifying it will be binding on

NOVATECH INSTRUMENTS unless made in writing and signed by an authorized official of

NOVATECH INSTRUMENTS.

NOVATECH INSTRUMENTS

United States of America

Voice: 206.301.8986

http://www.novatechsales.com

sales@novatechsales.com

Indice

Altri manuali Novatech Sintetizzatore

Novatech

Novatech 2910A Manuale utente

Manuali Sintetizzatore popolari di altre marche

Kawai

Kawai MP7 Manuale tecnico

Joranalogue

Joranalogue Contour 1 Manuale utente

Full Bucket Music

Full Bucket Music Mono/Fury Manuale utente

Kawai

Kawai PH50 Manuale utente

IK Multimedia

IK Multimedia UNO Synth PRO X Manuale utente

Behringer

Behringer DEEPMIND 12 Manuale utente

Roland

Roland Gaia SH-01 Manuale utente

Roland

Roland GR-30 Manuale utente

Gotharman

Gotharman Gotharman's anAmoNo-box Manuale utente

Yamaha

Yamaha DX21 Manuale utente

QuStream

QuStream HDFS-550 Manuale utente

Modal Electronics

Modal Electronics ARGON8 Manuale utente

Roland

Roland GS-500 Manuale utente

Octave

Octave Cat SRM Manuale utente

Dreadbox

Dreadbox Murmux Initiate Manuale utente

neutral labs

neutral labs ELMYRA 2 Manuale utente

Waldorf

Waldorf KYRA Manuale utente

Tubbutec

Tubbutec Juno-66 Manuale utente