HP 3586 schematic

5 (1)

A PRACTICAL GUIDE FOR USING THE HP3586A/B/C SELECTIVE

LEVEL METER©

(Version 2.0), September 2004

By Bill Feldmann, N6PY

TABLE OF CONTENTS

CHAPTER			PAGE
1	Introduction		3
2	Description of the HP3586		4
3	Signal Connections		7
4	Front Panel Description and Initial Setup		8
5	Setting and Measuring Frequency		11
6	Power Level Measurements Using the Selective Mode		13
7	Voltage Level Measurements Using the Selective Mode		15
8	Measuring Carrier Signal Strength		16
9	Tuning SSB Signals Using the Selective Mode		17
10	Tuning SSB Signals Using the Noise/Demodulation Mode		19
11	Measuring Audio Noise Using the Wideband Mode		20
12	Measuring Impulse Noise		21
13	Measuring Harmonic Audio Harmonic Distortion		22
14	Passive and Active Network Analysis		24
15	Measuring a Transmitter’s Spurious Emissions		26
16	Selection of Measurement Modes and Other Considerations		28
Appendix A		Understanding the Decibel Level Measuring System	31
Appendix B		HP3586 Error Codes	34
Appendix C		Schematics of Useful HP3586 Accessories	35

1. INTRODUCTION

This documents is intended for those having a HP3586 without the operator’s manual or are having trouble understanding the operator’s manual and want to learn how to use this versatile instrument. It should also be of use to those considering purchasing one of these instruments. This document is not intended as a complete operating manual but should help you understand what it does and how to use it. This document is written in a tutorial manner with many simple examples of typical measurements. If you want a copy of the HP operator’s or service manuals, I highly recommend obtaining copies from Manuals Plus at 801-936- 7000 where I obtained a professional quality copy of the operator’s manual at a reasonable price.

The HP 3586 family of Selective Level Meters was designed for the measurement of low power or voltage levels on telephone lines carrying multiplexed single side band radio frequency signals along with lower frequency audio signals. It’s designed to test and troubleshoot parameters commonly found on these lines. This instrument is a very sensitive, selective and accurately calibrated receiver that’s also capable of outputting a very low distortion signal of 0dbm at exactly the frequency it’s tuned to.

A while back I obtained a HP3586B that had been surplused from GTE from a couple of friends. They had found a number of these for a reasonable price at a surplus electronic warehouse, they obtained all they could and refurbished them, and then passed them on at their cost. Most had bad or leaking internal batteries, which they removed. They also installed the more common BNC female input connectors in place of the less common telephone connectors. Like all of these instruments on the surplus market mine came without operating or service documentation. But I figured out how to use it to measure frequency, use as an outboard VFO to drive my BC-610 AM transmitter, and as a receiver to search the radio bands for interesting signals. I felt this was a very large and heavy, 60lb, instrument to do what some cheap Radio Shack rice boxes could do and would take less room on my workbench. Also its internal receiver seemed to have rather poor audio quality. However, after obtaining and studying a copy of the operator’s manual and becoming more familiar with my HP3586B, a light went on in my head. I realized it’s a very versatile and useful instrument and I wasn’t even using 10% of its capability.

Please, first read this document sequentially to best learn about your HP3586 since each chapter will build on the experience you gain in previous chapters. We’ll start off describing the instrument so you’ll know how it works, what it can measure, then learn how to control and set it up by discussing it’s front panel along with its inputs and outputs, and finally learn how to use it for conducting useful measurements using hands on type examples.

Feel free pass on copies of this document to others that may find it useful. I’ll publish revised versions as I learn more about my HP3586 and discover new applications. I recommend you print out this document and the schematics in Appendix C, place it in a binder and add any additional notes you may wish just after the Appendix. Please don’t revise the document, just send me any suggested changes or additions at n6py@arrl.net and I’ll include them in future versions. Otherwise there will be different versions in circulation with no revision control causing mass confusion for those attempting to use it. I’m also releasing it in the Adobe PDF format to discourage uncontrolled changes and for easy Internet downloading so I don’t have to get into the book printing and binding business. I copyrighted this document to further control it and keep it’s use free of charge by using the © symbol on the document’s title.

This document is dedicated to all those amateur radio operators that enjoy working on electronic circuits, measure the performance of radios, repairing their radios, measuring audio through HF radio signals, or restoring amateur or military radios that are keeping the hobby of amateur radio alive, well and interesting. So read on and I hope you enjoy learning about the wonderful world of the HP3586.

2.DESCRIPTION OF THE HP3586

2.1General – For those not familiar with selective level meters they can best be visualized as a receiver having very high selectivity with a detector system capable of accurately measuring low power signal levels from +20dbm down to –100dbm and frequency over a wide range from 200Hz to 32MHz and. It also will output a signal of 0dbm, one miliwatt, at exactly the same frequency that the instrument is tuned to, which is usually the center frequency of the selected receiver band pass filter. It’s also a SSB receiver to aid in tuning the signal to be measured. Because of these features a selective level meter is extremely valuable for measuring and the analysis of audio up through RF signals, it’s a whole lab of instruments in one package. Because of this it can be used to measure the performance of electronic radio and RF circuits, measure the strength and frequency of radio signals along with driving other electronic devices using it’s one miliwatt low distortion output signal as a low power signal generator.

The HP3586 family of selective level meters was designed to measures signal levels and frequency in selected portions of its total frequency spectrum on multiplex telephone transmission lines. These frequency slices can be operator set by selection of filters from 20 Hz up to 3100 Hz in bandwidth that are front panel selectable. All versions will have 20 and 400 Hz filters. The A and B versions have one additional 1740 or 2000 Hz filter depending on model. Those with 003 option will have a 3100Hz filter and a noise weighting WTD filter that can be switched in series with the 3100Hz filter to reduce low and high audio frequency noise. The C version only has the 3100Hz filter without a WTD noise filter and no filter options.

There are three versions of this family of instruments. The A and B versions have modes and features making it easier to measure SSB channels on phone lines. The C version is more basic and doesn’t have the SSB channel features of the A and B versions. However all three will work equally well for most of the RF and audio measurement described in this document.

In its measuring modes except wideband the instrument will display and output a 0 dbm signal to a rear panel connector at the center frequency its filter from an internal tracking oscillator. This signal’s frequency can be set using the front panel keyboard or tuning knob. It also has a counter system that can be commanded to read and display the frequency of the strongest steady signal within its filter’s pass band. It can then be commanded to store this frequency in its frequency register changing its center frequency to the register’s frequency and outputting this new frequency to its rear panel Fo connector. This feature is very useful for measuring the frequency of a carrier and then synchronizing the frequency of another device to that frequency. The instrument also contains a SSB detector system that is used to receive and tune SSB signals or other signals into the instruments pass band.

In the following chapters I’ll describe how to setup your HP3586 to do useful measurements of frequency, power, voltage, network analysis, distortion analysis, and use it on the air as an accurate signal strength meter along with using it as a VFO to control an AM transmitter. In the interest of keeping things simple, instrument features and modes that I feel are not useful for RF or audio measurements will not be discussed in this document.

2.2 Instrument Capabilities - Since the HP3586 measures the total power of all signals in its filter’s pass band, its always best to use the narrowest possible filter when measuring narrow band signals to reduce noise errors. Power measurements are usually displayed in db’s referenced to one miliwatt, dbm units, but can also be referenced to a pico watt, which I haven’t found useful. It can also measure the voltage of a signal in db’s referenced to .775 volts on all versions and 1 volt on the C version. These units may seem cumbersome since most of us prefer dealing with linear measurements in watts and volts, but it’s better suited for measuring over very large ranges and is a standard method for those working with telecommunications systems. If you are not familiar with this system of measurement or a little hazy on understanding it, please take a look at Appendix A for a better understanding. You can easily convert to watts or volts from the HP3586 panel readings by using the following formulas and a hand held calculator:

Power dbm = 10 log (Power in watts/.001)	or Power watts = .001 [ anti log ( power dbm/10) ]
Voltage dbv = 20 log (Voltage volts/Vr) or	Voltage volts = Vr [anti log (Voltage volts/20)]

Vr = .775 volts for the A and B models: Vr = 1 volts or .775 volts can be selected on the C model.

For optimum accuracy the instrument takes measurements over a small part of it’s total –120dbm to +20dbm measuring range by using a range selectable detector circuit. The selectable ranges are, 100db and 10db and have resolutions of .1db and .01db respectively. The readings are accurate over the whole 10db range but are only accurate over the upper 80db of the 100db range. The location of a range within the instruments total measuring range is operator or automatically selected for best level measurement accuracy. This is done by using an IF amplifier circuit whose gain is accurately changed. The IF amp is located just before the detector and changes its gain to select the upper limit for the range of values the detector is measuring. Specifying an upper limit for a range using the entry command actually selects the gain of the IF amplifier. Automatic limit selection is done using a circuit similar to the AGC circuit in a radio receiver.

One important point to remember is that the upper limit for the 100db range can not be set below –45dbm because –80db below this setting starts to equal the instrument’s noise floor of around –120dbm. When the detector is set to the 10db range the upper limit can be set much lower to –120dbm. The SSB demodulator receives its signal from the IF strip in parallel with the level detector and will only be able to demodulate signals above –55dbm. When the instrument is in the 100db range the gain of the IF strip is too low to read radio signals below this level. Therefore, when using the SSB detector for audio tuning of received radio signals we should almost always have the instrument in the 10db range since these radio signals are usually below –55dbm. In chapter 4 we’ll show how to work around this problem when receiving SSB signals.

For those of us working on electronic circuits or taking radio signal measurements this instrument is a valuable tool that can be used to measure RF or audio noise, the frequency of a received carrier, find and measure spurious transmitter signals, provide a signal and detector system for circuit analysis, and as a VFO to control the carrier of a transmitter. It will work as a SSB receiver over its whole frequency range to tune on the air signals for measurement. It receives and accurately measures signals down to -100dbm, which is much lower than the noise on most ham bands.

One disadvantage when receiving SSB signals is that the HP3586 will not output the actual carrier frequency of a SSB signal to its rear panel Fo output when using the SSB detector. It only outputs the center frequency of the selected band pass. In this document I will describe how to work around this problem when controlling AM transmitters.

2.3 Instrument Accuracy - The instrument uses 100db or 10db changeable ranges for maximum accuracy as described above. The 100db range is only accurate over its upper 80db portion and has a resolution of .1db. In the automatic range limit control mode the 100db range will have its upper limit automatically changed to always stay within the accurate upper 80db part of this range. The narrower range of 10db has a resolution of .01db. The instrument’s level measuring frequency range is 200Hz to 32MHz with a frequency resolution of .1Hz and accuracy of + or - .000001 of it’s reading during the first year after calibration. The 004 optional crystal frequency reference was offered for greater frequency display accuracy, see Chapter 16, section 16.8 if your instrument doesn’t have this option.

The instrument is intended for accurate measurements only in the range of –100dbm up to +20dbm. Using the 50 or 75 ohm input from 200Hz to 32MHz and for signal levels between +20dbm and –80dbm, between –80db and –100db its accuracy is +/- .75dbm. From 200Hz to 200KHz and from +20dbm to – 80dbm its level accuracy drops to +/-.40dbm, and from –80dbm to –100dbm it’s +/-.95dbm. Below 100dbm it’s accuracy isn’t rated and level measurements below –100dbm should not be trusted even though the instrument will appear to read down to its noise floor of around –120dbm. By using

comparative measurement between different devices or conditions its accuracy can approach the 100db or 10db ranges precision of .1db or .01db, we’ll talk about that in Chapter 16.

To maintain accuracy the HP3586 does a 3 second duration automatic calibration, auto cal, when it’s first turned on, every two minutes during operation, if its frequency is changed more than 1MHz, and when a new measuring range width is selected. If any problems arise during calibration or during its operation the display will output error codes, which are described in Append B. For special reasons such as SSB audio tuning discussed in this document, the auto cal feature can be turned off at any time after its initial power up.

2.4 The 004 Option – When I purchased my HP3586B I assumed it didn’t have the 004 enhanced frequency accuracy option but I noticed a 004 installed sticker on its back panel. Also there was an oven output connector installed on its back panel but no jumper from this connector to the external reference connector just to its right. I then removed the instrument’s top cover by loosening a screw in the back of the cover and sliding the cover off. To my delight I found a wire from the oven connector to a module labeled A16 installed to the RH rear of the instrument’s motherboard, which was the 004 option module with the 10 MHz crystal standard in a oven.

When I connected a jumper between these two connectors the oven light on my front panel came on for about 10 minutes and then went off. After the oven light went out indicating the crystal oven was up to temperature, checked WWV on 10 MHz using the counter procedure in section 5.3 of chapter 5 and found my instrument was within .7 cycles of 10 MHz when using the counter on WWV’s 10 MHz carrier. Without the jumper installed between the connectors, it was off by over 9 cycles so activating the 004 option made a great difference in the frequency accuracy of my instrument.

If the oven connector is installed on the back panel of your instrument but isn’t connected to the EXT REF connector to its right, look inside your instrument and maybe you will be lucky and have this valuable option. If your instrument has the A16 module installed, you must connect a jumper cable with two BNC male connectors to activate the option.

2.5 Level Measuring Modes – The HP3586 family of instruments has the following modes for measuring signal levels:

SELECTIVE	See Chapters 4, 5, 6, 7 and 9
CARRIER	See Chapter 8
NOISE/DEMODULATION	See Chapter 10
WIDEBAND	See Chapter 11
IMPULSE	See Chapter 12
NETWORK ANALYSIS	See Chapter 14
TONE	Not Applicable
JITTER	Not Applicable

I have found the first six measurement modes useful for radio and audio measurements. The other modes are not normally useful because they are designed specifically for telephone measurements or require other not normally available specialized equipment.

All measurement modes discussed in this document apply to the A and B versions where the noise/demodulation, impulse and carrier modes are not available on the HP3586C general purpose version. However, I’ll show how to make noise/demodulation measurements with the selective mode using the C version.

3.SIGNAL CONNECTIONS

3.1General - In this section I’ll describe how to connect a HP3586 for measuring frequency and power level in the selective modes. In the following chapters I’ll also describe any differences for other measurement modes.

3.2Signal Input and Termination – Never put more than +27dbm or .5 watts total power into the input 50 or 75 ohm connector of a HP3586 when using the internal termination. Never put more than an AC + DC total of +42 volts into an unterminated connector.

To get a signal into a HP3586 you have the choice of many different input connectors and impedances. However the only input I’ve found useful is the 75 or 50 ohm unbalanced input. All other inputs, including the 600 ohm one, are not useful over the complete frequency range of the HP3586 and terminate in impedances usually used for telephone circuits but not for RF circuits. The 75 or 50 ohm input is usable over the instruments complete frequency range. Those with a HP3586C are fortunate that it has a 50 ohms input. A or B versions only have a 75 ohm input. Most of the surplus instruments have telephone type input connectors but many of us have converted ours to a more standard BNC connector for radio use. The A and B version make all their power calculations based on 75 ohms even if the input is unterminated or has an external 50 ohm termination resistor. However you can enter an offset to compensate for this difference, more on this in section 6.2 of Chapter 6.

When making on the air measurements to a 50 ohm unterminated antenna line, use the 50 ohm termination option on a C version or use a 50 ohm terminating resistor on the A and B versions and use the 10K 50pf unterminated 75 ohm input. When measuring antenna signals in parallel with a receiver having a terminated 50 ohm input, just simply hook a short 50 ohm feed line to the receiver’s antenna terminal in parallel with the receivers antenna input and use the unterminated input option on all models of the HP3586.

When making measurements on RF circuits you can terminate the input with 50 or 75 ohms termination, but on many circuits you may want to use the higher 10K 50pf unterminated input. Unfortunately this is not very high for some tuned circuits and the 50pf may detune the circuit causing measurement errors. HP did at one time offer accessory probes to isolate these circuits however they are not easy to obtain today so consider a link coupling if only measuring frequency. For accurate level measurements you may want to consider building a FET source follower or tube cathode follower one to one isolation amplifier to isolate these circuits from the instrument’s input. I’ve shown two suggested circuits for this in Appendix C.

3.3 Tracking Oscillator’s Output Signal - This output signal can drive a transmitter or other device, connect a BNC male connector with a 75 ohm line from the driven device’s input to the Fo output connector located on the back panel. This outputs power is 0dbm or .27 volts RMS, which may not drive many older tube type transmitters. It will drive my Viking 2 on 160 through 40 meters but not above these bands and also is too low in power to drive my BC-610 through its crystal socket. I’ve constructed a small solid state broad band amplifier to drive the BC-610 and my Viking 2 that boosts the output to at least 10 volts RMS for more drive and better isolation, its schematic is shown in Appendix C. This amplifier is in a RF sealed box and mounted to the back panel of my HP3586. It’s powered by the transmitter and has its B+ cut off during receive to kill any back wave in my receiver.

Other output signals are available on the instrument’s back panel but are not useful to most of us doing Audio and RF measurements along with being for other specialized equipment, like HP computers and jitter measuring devices, so won’t be discussed in this document.

4.FRONT PANEL DESCRIPTION AND INITIAL SET UP

4.1General - Before turning on your HP3586 be sure it’s configured for the right input power, usually 115VAC. Also be sure the filter on its back panel is clean, if not remove it and clean with only soap and water. The filter should be cleaned after every 720 hours of operation.

In the following sections and chapter you’ll see capital letters in brackets like [AUTO]. These identify buttons used to control the instrument or enter data. The front panel of a HP3586 is broken into groups or sub panels, which we’ll refer to in this chapter to aid in locating individual displays and controls.

Additionally, on the front panel you will see some buttons with a second label below the button or two labels on the button like buttons near the keyboard, these are dual function buttons. Ones with two labels on the button will select the proper function automatically by the button that is previously pushed, like if you push [FREQ] the instrument knows MHz, KHz, or Hz apply instead of the other labels like –db or -db. The ones with labels below and above the button are shifted button. On the same panel you will see an unlabeled colored shift button with a light on it. When it’s light is on, the lower label of the dual-purpose adjacent buttons will apply. Also buttons with lights will have their function on when their light is on.

Plug you HP3586 into AC power and the STANDBY annunciator should light, next turn on your HP3586 by pressing [POWER]. It will first perform an auto calibration for about 5 seconds. If a ERR or CE with a number is displayed on the LH front panel read out there has been an error during calibration, refer to Appendix A for a listing of errors and suggested corrective action. The [AUTO CAL] button light should be on but you can turn off auto cal at any time by pressing this button, but for now leave it on. After the initial power up and auto cal the instrument should default to the low distortion-measuring mode with a range setting of 10db auto. During the following sections we will describe the front panel controls. Since the instrument will default to the selective low distortion level measuring mode when first it’s powered up you may not need to perform all the described button pushing commands but just confirm that the instrument is set up as described.

During the following sections of this chapter, have your HP3586 available in front of you to find the described controls and LED displays.

4.2Measurement/Entry Group - On the upper LH is the measurement/entry sub panel, which is used for displaying the power or voltage measurements and their units on a LED display. The measuring range and range full scale range value is set using it’s buttons. Set the range by pressing [10db] and the full scale range limit by pressing [AUTO] for the automatic mode. The analog meter reads the relative level of signals within the selected 100db or 10db range. With the 100db and auto settings this meter will work as a relative signal strength meter to aid in frequency tuning. Press [dbm] to have the display read in dbm units. A dbm annunciator should now light to indicate the units are shown in dbm. The [OFFSET] button is used to subtract values placed in an offset register that will be subtracted from level values computed by the instrument to correct or normalize displayed level values. We will discuss this feature later, for now leave it off. Other buttons we’ll discuss later during some of the examples.

4.3Frequency/Entry Group - On the upper RH side of the front panel is the frequency/entry sub panel. This panel will usually display the frequency that the instrument is tuned to. It will display during frequency entry frequencies being entered by the instrument’s keyboard in KHz or Hz. This frequency will be the center RF frequency of the selected band pass filter except when in the SSB channel measurement modes. On all models this panel can select a LSB or USB, side band channel for measurement using the two channel buttons with a funny symbol I can’t show with Word. The left button is for LSB while the one on the right is for USB. A counter button is provided to start the frequency measurement counter system. Only the A and B versions have the SSB entry frequency selection buttons. The carrier button should be on when in one of the SSB channel modes and tuning a SSB signal. This changes the display to read SSB carrier frequency instead of filter center RF frequency. Even when their lights are on, the tone

and carrier buttons are only active in the SSB channel modes. The tone button is only useful for phone line analysis and won’t be used or discussed in this document.

4.4Status Group - This small status sub panel on the top far right indicates if the instrument is receiving or sending data to a remote computer and weather it’s under local or remote control. If the remote annunciator is on, press [LOCAL]. For our use it should always be in local front panel control mode.

4.5Measurement Mode Group - On the lower LH side is the measurement mode sub panel that’s used for selection of how level a measurement will be made by the instrument. All versions have the selective mode buttons, but only the A and B versions have the specialized SSB channel modes for performing many SSB channel measurements. The only useful SSB modes I have found a use for are noise/demod, carrier, and impulse modes. With the shift key light off, press the selective [LO DIST] key to select the maximum dynamic measurement range for the instrument.

4.6Termination Group – Never put more than +27dbm or .5 watts total power into the input 50 ohm or 75 ohm connector of a HP3586 when using the internal termination. Never put more than +42 volts total AC + DC into an unterminated connector.

The termination sub panel is also located on the lower LH of the control panel. This panel is used to select the input termination for an input signal. The 50 or 75 ohm unbalanced input on the LH side of the panel is the only ones useful for radio work and used in the examples of this document. The others use nonstandard RF circuit impedances and are for telephone applications. See Chapter 3 for a complete description on how to connect to the unbalanced low impedance input.

For the measurements we’ll be doing in the following chapter, press the [100K 50pf] button on an A or B versions. On the C version press the [50 ohm] button and the unlabeled shift key to the right of the 75 ohm key to remove its 50 ohm load. If you’re not connected in parallel with a terminated load like a radio receiver, and need a termination such as when being directly connected to an antenna feed line, turn off the shift key’s light on the C version to provide a load. For unterminated 50 ohm loads using the A or B version you will need to provide an external 50 ohm termination. In Appendix C is a schematic for a termination box with a blocking capacitor that I use with my HP3586B.

4.7 Entry Group - On the lower center of the front panel is located the entry sub panel. This sub panel is used for entry of frequencies, data offsets, frequency tuning steps, full scale measurement values, and transferring frequency and offset values to their respective registers by using its keyboard buttons.

One very important key is the measurement continue key, [MEAS CONT]. During many data entries that use one of the LED displays this key’s red light will turn on or flash indicating the instrument’s measurement process has been interrupted. Anytime you see this button’s light and want to return to the measurement mode press this key to continue measuring. You can also press it to cancel a mistaken partially keyboard entry.

Another useful feature of the HP3586 is its ability to store its configuration settings for future use in making similar future measurements. To do this you can press [STORE] on the entry sub panel followed by any number from 1 to 9 on the keyboard. This will store the present configuration of the instrument in the memory location of the number pressed for future recall and to save setup time. To recall the configuration press [RECALL] followed by the register number to rapidly configure the instrument to a previously stored configuration. To return to the default power up configuration, press [RECALL] then enter 0. These configurations will be stored after the front panel power button is off and the instrument is in standby as long is AC power is connected to the instrument or its internal battery is charged. Unfortunately many surplus HP3586’s have dead batteries or their batteries removed and will loose their stored configurations when disconnected from AC power.

If you press [OFFSET] on this sub panel you’ll first see the offset in the measurement level offset register. If the number you want to enter is close to the present one in the data offset register, you can change the existing number up or down using the arrow keys, [↑] or [↓] and then press one of the db buttons and followed by [MEAS CONT].

4.8Frequency/Tune Group - On the lower right side of the front panel is the frequency/tune sub panel. This sub panel contains a knob, which is useful in fine-tuning the instrument’s frequency, especially to SSB signals. Different automatic tuning steps are selected for the selected filters using the [AUTO] button. Entry panel pre-programmed steps can be selected by pressing the frequency step button. The actual step size is entered on the entry sub panel for the [FREQ STEP] button. Pressing the off button can lock off the frequency tune function.

4.9Bandwidth Group - On the lower right is the bandwidth sub panel, which is used to select the instrument’s bandwidth that a power or voltage measurements are to be taken over. All models have 20Hz and 400Hz filters. The A and B versions will have one additional filter of 1740Hz, 2000Hz or 3100Hz. A and B versions may also have the optional WTD audio noise filter which is selected by a fourth button to be in series with the wide third filter. For now select the widest filter your HP3586 has.

4.10Audio Group - On the lower far right is the audio sub panel. This panel contains a small speaker and headphone jack along with a volume control knob for output of audio from the SSB detector. Since we won’t be using the audio output during our first measurements turn the volume knob full CCW to turn off the sound.

4.11Improving SSB Reception - This method that is not in the HP operator’s manual gets around the problem of these signals being very distorted in the instrument’s speaker due to the fact the automatic range level selection is acting as a AGC system for the SSB demodulator but because of its slow action there is heavy distortion on the onset of audio signals such as words. I first set the instrument in the 10db and auto range selection mode, press [10db] then [AUTO] on the frequency/entry sub panel if they aren’t on. Next press [AUTO] on the measurement/entry panel and tune the speaker’s audio for best possible audio. Then enter a frequency step of one Hz by pressing [FREQ STEP] on the entry panel and enter 1 followed by [Hz] and [MEAS CONT]. Now press [FREQ STEP] on the frequency/entry sub panel and again tune for best audio.

Now to improve the speaker audio by preventing over loading the SSB demodulator, lock the instrument into manual IF gain control by pressing [ENTRY] on the frequency/ entry sub panel. This will stop the IF amps AGC action and fix the gain of the IF strip to that of the last automatic setting. This should partially reduce distortion but to further reduce it, press [FULL SCALE] on the entry sub panel and use the [↑] key to move the range full scale setting shown on the level display up until the modulation peaks on the analog meter are near 1/3 scale and turn up the speaker’s volume if necessary. If you go too far and loose the audio, then press [↓] to increase the IF’s gain but I’ve found 1/3 scale on the analog meter gives best audio. You can experiment and find the best IF gain setting by entering smaller and larger limits using these keys just like you would using a manual RF or IF gain control knob on your receiver. If you get UL or OL on the level measurement display, don’t worry if your just tuning or listening to SSB, this only indicates level measurements are inaccurate. Also to not have your SSB signal interrupted during tuning or monitoring, turn off auto cal. However when doing level measurements, always have auto cal back on and press [AUTO] on the measurement/entry sub panel when your doing signal level measurements.

4.12 Back Panel Oscillator Output – On the HP3586’s back panel is located a female BNC connector labeled Fo that supplies an output of 0 dbm, 75 ohm from the internal tracking oscillator. Its frequency will always equal to the frequency of the selected filter’s center band pass frequency. This output is disabled in the wideband measuring mode.

5.SETTING AND MEASURING FREQUENCY

5.1General - Now we’re ready to have some fun doing examples of how to use your HP3586. This chapter we’ll show how to use the HP3586 as a VFO by adjusting its frequency and outputting this frequency for controlling an outboard device like an AM transmitter. We’ll also command the instrument to measure the frequency of a received AM carrier then lock its output to the carrier’s for zero beating to another transmitter’s carrier along with checking your HP3586’s frequency calibration. These examples can be used in all the selective measurement. For now stay in the low distortion selective mode.

5.2Setting Frequency - The easiest way to set the frequency of the instrument is to enter the desired frequency using the entry keyboard. On the entry keyboard first press [FREQ], enter a number for the desired frequency on the keyboard. Then press one of the dual function [Hz], [KHz] or [MHz] buttons for the units the frequency is in. The frequency display will now read the frequency you have just entered and a CENTER annunciator on the display will light indicating this is the frequency the center of its selected filter. It will also output this frequency to the back panel Fo connector at a 0dbm, 75 ohm level. Now the HP3586 can be used as an outboard VFO for controlling other devices through its Fo connector. In Appendix C is the schematic of an amplifier I use to drive my AM transmitters from this output.

To make small frequency adjustments you can use the frequency tune knob. But first you have to set up the resolution of this control. First go to the entry panel and press [FREQ STEP] and enter on the keyboard the step resolution you want, I usually use 10Hz or for fine tuning of carriers so let’s enter 10, then press the [Hz] button for the units of the step you selected followed by the [MEAS CONT] button to return the instruments to its measuring mode. Now go to the frequency tune knob and press the [FREQ STEP] button. As you turn the knob you will see the frequency display change in 10Hz increments. Since the instruments frequency register is being changed the tracking oscillator output at Fo is also changing with the displayed frequency. For faster tuning you can press the [AUTO] button, which selects frequency steps depending on what bandwidth filter you selected. Knob tuning is a handy feature I use for zero beating the instrument’s Fo output to a carrier being receiving on my 75A4 receiver. I turn on the exciter stage in my transmitter then using the HP3586’s frequency tune knob to adjust the HP3586’s frequency to zero beat with the received carrier while listening to my 75A4.

5.3 Automatically Determining a Station’s Frequency – Be sure the 75 or 50 ohm connector is connected in parallel with your receivers antenna input as described in the previous section. To use this feature the instrument must be receiving a steady signal that’s stronger than any other signals in its filter’s pass band.

To automatically tune the HP-3586 to exactly the frequency of a received carrier, tune the carrier into the pass band of the instrument’s selected filter. I usually use the instrument’s widest filter, which we already selected in the previous chapter when setting up the instrument. Turn up the volume knob on the audio panel on the lower RH side of the front panel to hear signals being received and be sure either USB or LSB is selected using the buttons below the frequency display. Press the [AUTO] button for the frequency input knob and tune it into the filter’s pass band. Tune the tone for zero beat on one side of the filter’s band pass and you should be able to confirm the carrier is the one you want to tune to by listening to the audio from the carrier’s side band. Be sure you’re in the 10db measurement range and auto full scale for a good speaker output.

After confirming the stations identity, tune the carrier back into the band pass indicated by a strong carrier tone and press [COUNTER] under the frequency display to turn on the frequency counter. The display frequency will now automatically lock onto the received carrier’s frequency. Next press [CNTR→FREQ] on the keyboard entry panel to store the counter frequency in the frequency register then [COUNTER] to turn off the counter followed by [MEAS CONT] and return the display and instrument’s frequency to the new contents of the frequency register. The instrument’s frequency is now the carrier’s measured frequency and in the speaker you should now hear the received carrier’s tone at around half the frequency of the filters band pass frequency indicating the carrier is now exactly in the center of the filter’s pass band.

If there is other strong signals in the filter’s band pass and the instrument has trouble locking on to the received carrier, select a narrower filter and repeat the above procedure.

Unfortunately the HP3586 can’t be easily used as a receiver when controlling a transmitter, see section 16.11 of Chapter 16 for a possible method. It only has a SSB product detector and only displays the center RF frequency that its filter is tuned to, so after locking onto a carrier, you will have to turn the volume control knob full CCW to kill the carrier’s tone in the speaker. Then use your outboard receiver to copy the other station.

5.4 Checking Your Instrument’s Frequency Calibration – HP recommends that the instrument be calibrated each year. Unfortunately most of us don’t have access to a calibration lab and can’t afford to pay a lab to do this for us. But we can check its frequency calibration using one of the frequency standard WWV stations. Select a wide filter to make it easy to tune in one of the WWV stations, press [3100Hz] or the button for your widest filter. With the same setup as the previous section tune your instrument to one of the following frequencies, 2.500MHz, 5.000MHz, or 10.000MHz. Be sure to have an antenna connected to your instrument’s unplaced input.

Turn up the audio volume on the audio sub panel to find a frequency where WWV is well above the noise. You should hear a strong tone from its carrier in the filter’s pass band. You can also confirm you are tuned to WWV by tuning the tone for zero beat using the frequency tuning knob and listen for the announcer to identify the station as WWV in its AM side band. Be careful since WWV will send tones at times that you could lock onto by mistake, it’s better to tune when their tone is off. Now retune the carrier to the filters center and switch to your 400Hz filter being sure the WWV carrier is within the filters pass band.

Now press [COUNTER] on the frequency/entry sub panel and read what your HP3586 says the WWV carrier frequency is. The difference from exactly one of the above frequencies you first tuned to is the frequency error in your HP3586 since WWV stations have their frequency held to within a small fraction of a cycle. See section 16.8 of Chapter 16 for a suggested way of keeping your HP3586’s frequency accurately calibrated. Also see section 2.4 of Chapter 2 to see if you have the 004 frequency standard option and if it’s activated.

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