Kenwood Ts 480 Users Manual 480_manual_E_040426b

TS-480 to the manual 318db68e-a42b-4fe6-b285-8a41a6421aa8

2015-01-23

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Preface
This in-depth manual for the TS-480 was written by the engineers who actually planned
and designed the product. It is our hope that this guide will serve to convey the joys of HF
and all the benefits of owning and using the TS-480 to whoever reads this guide – whether
you have already purchased a TS-480, an accomplished operator, thinking of buying a
transceiver, or just thinking of taking up Amateur Radio as a hobby. We believe the
TS-480 will appeal to everyone.

CONTENTS
Design Objectives ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 2
Development Objectives for the TS-480 Series・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 5
Circuitry ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 7
TX circuits ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 7
RX circuitry ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・13
Auxiliary Features ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・19
Features of the Built-in DSP ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 21
Tips・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・28
Structural Features ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・36
New Option: Voice Guide & Storage Unit (VGS-1) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 42
New Option: ARCP-480 (Freeware)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 45
New Option: ARHP-10 (Freeware) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 51

TS-480HX
TS-480SAT

200W output
(HF: 200W、50MHz: 100W)
100W output (HF: 100W、50MHz: 100W、
built-in automatic antenna tuner)

2

Design Objectives
Determination to create a unique transceiver
The concept of a compact HF transceiver first saw the light of day with Kenwood’s TS-50. From
then on, such equipment has become an essential part of the Amateur Radio world. Equipment
has now evolved with the appearance of multi-band models.
In developing this new HF transceiver, Kenwood has boldly chosen not to follow this path, because
we wanted to develop a transceiver unlike any other available. If we had developed a product
along the same lines as the others currently in the market, the customers would not have found it a
very attractive buy and few would choose it. This is why we wanted to develop a unique and
attractive Kenwood product, something that would effectively serve to create a new market.
It was with these thoughts that we embarked on our new project and began to mull over the details.
It was not to be an easy task. After all, every engineer involved in development wants to create
something special and innovative. We had to find a way to put it into practice.

Back to basics: “The appeal of HF lies in DX’ing.”
The search for “a completely new kind of transceiver” sounds like it might turn out to be a wild
goose chase, and in truth it is in the nature of things that such ideas rarely amount to much. But as
part of our brainstorming, we went back to basics. What first emerged as a key concept was this:
“The appeal of HF lies in DX’ing.” This is simple to say, but maybe more difficult to realize. From
here the discussion moved ahead rapidly once it was decided to develop a compact HF
transceiver.
According to conventional wisdom, a compact HF transceiver is by definition a mobile transceiver,
and a fixed, base station is physically large. But we refused to stick to these stereotypes as we
fleshed out the concept for a compact HF transceiver designed to make DX’ing really enjoyable.
Even if it were to be a mobile unit, as an HF transceiver we wanted to ensure it would offer the
operating ease and basic performance needed to enjoy DX’ing.
Consequently, it should also be able to serve as a fixed station.
The typical shack today has been equipped with a computer and there is not a great deal of
room available for a large transceiver. This PC-transceiver combination would become even
more common.
Operating both as a mobile and as a fixed station, this new model would target customers
dissatisfied with the compact transceivers currently on the market.
This was the concept that we started with.

3

Standalone control panel
For mobile operations, a separate control panel is ideal, but what if the transceiver is also to be
used as a base station? This was the problem we faced. With a large desktop rig, it is no easy
matter to shift things around to find the best position, so perhaps it would be a good idea to have a
separate control panel that could be moved easily. Also, a desktop unit has various kinds of cables
connected to it. What with the heat the main unit produces and the noise of the fan, etc., and
considering that it does not have to be on the desk in front of you, it would surely be better to
separate the control panel and place the main unit elsewhere.
With the appearance of computers in today’s shacks, it is certainly desirable to tidy up the desktop
as much as possible. We felt that we could contribute to this evolutionary process. By opting for a
completely separate panel, we could ensure that it would be large enough to offer sufficient
operating ease, since its dimensions would not be dictated by those of the compact main unit. This
was how we arrived at the idea of a standalone control panel that is slightly larger than the main
unit.

Focus on basic performance
The appeal of HF lies in DX’ing those places near and far. For this reason, we put a priority on
operating ease and basic performance. At this point the project team had already excluded any
idea of incorporating the V/UHF bands. Our approach was this: “Rather than spending
development money on the V/UHF bands, let’s spend money on HF performance.” “If someone
needs the V/UHF bands, then they can buy another product that is tailored for these bands.” This
meant we had confidence that our product would offer more than enough punch to perform well
even on grueling DX’peditions.

The 200W challenge
As explained, our initial starting point was a desire to create a transceiver like no other. But we
would not have succeeded in meeting this objective with just a standalone control panel and an
emphasis on basic performance. We needed something more if we were to make the product truly
special and stand out from the crowd.
The answer was to be found in the realization that DX operations depend on basic performance
and power. Real “power” in a transceiver is something that many people look for. So a radical
proposal was made: “Rather than making the output 100 watts, let’s go all out for 200 watts!” But in
fact the only transceivers on the market with 200W output were the expensive high-end models.
What we were developing was a compact transceiver.
We seemed to have run up against a wall: Did this mean that in terms of size and cost we would
inevitably end up creating a high-end transceiver? After long discussions, we made a
straightforward decision to challenge the status quo: If conventional wisdom dictated that a 200W
output was only available from a high-end transceiver, then we would change that dynamic.
At this point we could not see how this could be possible, but we stuck to our conviction that a
200W transceiver did not have to be expensive. We were determined to provide the customer with
a 200W transceiver at a reasonable price. As a result of our single-mindedness, we were
eventually able to achieve our goal, creating a product of about the same size as the TS-50 and, of
course, it had heavy-duty specs.

4

Adding appeal to fixed station operations
It is now increasingly common to see a PC sitting beside the transceiver in the shack, but we
wanted to expand the interaction between computers and transceivers. It was with this in mind that
Kenwood came up with the idea of an Internet remote-controlled transceiver. You may be away on
a business trip, but you want to operate, or you may want to use a large Yagi antenna out in the
suburbs from your downtown apartment. In these and many other ways, fixed station operations
are becoming more varied and more difficult. However, laws governing radio transmissions vary
from country to country. In Japan, we had just about resigned ourselves to the fact that this could
only be implemented as an RX feature when fortunately the law changed: starting January 13,
2004, both TX and RX operations became possible. This made all our development work
worthwhile for our market in Japan and worldwide.

Overview of the TS-480 Series
The product concept for the TS-480 Series, as outlined, can be summarized thus:
Not simply a compact HF mobile transceiver like the TS-50 and other transceivers on the
market, the TS-480 is a completely new type of powerful compact HF transceiver offering the
performance and features required for HF DX operations.
TX output of 200W (HF), an astounding figure; and up till now, only available from the
top-of-the-line models.
Transceiver remote control
In order to realize all three of these, we started the design process with the following planning
objectives:
1. Priority on basic performance that stresses the 1.8 ~ 50 MHz range;
2. Dynamic range on a par with the TS-950;
3. Uncompromising RX performance, AF DSP as standard;
4. A control panel design that ensures top-notch operating ease, so that desired functions
can be accessed instantly;
5. Support for a range of different operations as a mobile station and as a full-fledged base
station, allowing the user to enjoy HF DX as much as with a conventional fixed station;
6. A quantum leap in power output in a compact chassis, generating 200W even when
working off a DC 13.8V supply (in the USA there are no limitations on the power output of
mobile transceivers, so it is being described as a “power mobile”);
7. Internal automatic tuner for the 100W model to make it more versatile and expand the
range of possible applications; and
8. Remote control via the Internet.
As for the name of the new series, which was intended to reflect our planning objectives, we
decided on the 400’s in order to express continuity with the popular TS-450 workhorse transceiver.
This was because the new product was not simply a compact transceiver but would offer the sort
of performance and features Kenwood fans would expect of a 400-series model. A workhorse
transceiver that could prove its worth in a variety of places – in the shack, in a vehicle, in the field -this was the TS-480 Series being planned by Kenwood.

5

Development Objectives for the TS-480 Series
The following is an explanation of our development objectives, distinct from the planning
objectives.
If asked about the origins of the compact HF rig, people outside Japan would no doubt think of the
Atlas Series. Following the Atlas, a variety of different products appeared on the market, but it is
probably no exaggeration to say that Kenwood’s TS-50 was the first in the category of the 100W
(HF) compact all-mode transceiver. It is already more than a decade since the TS-50 was
launched. Since then, successive models have grown increasingly smaller while adding new
features and expanding band coverage to include V/UHF. Today, this category has matured to the
point of actually forming a definable market. What we developed in order to stir up and add fresh
stimulus to this market was the TS-480 Series.
• Why a compact 200W transceiver?
• Why a 100W model with a built-in antenna tuner?
• Why HF~50MHz coverage?
The answers to these questions can be found in our planning objectives. Let’s look at the technical
background.

The TS-480 concept began with development of the TS-570?
We first started looking in detail at the technical feasibility not of the 200W model but of the model
with the internal antenna tuner. Today, there is nothing special about a built-in AT, but for the
TS-570 we developed a relay-type AT. This replaced the previous motor-driven variable capacitor
type of AT. Naturally this technology was used elsewhere and by other manufacturers, but if
applied not to TX but to RX also, it is possible to use it for receiver front-end passive tuning. For
transmission purposes, it is smaller than the conventional type of AT of the time, especially with
regard to height, making it a good choice for building into a compact set.
In 1996, when on a visit to the US to promote the TS-570 a local salesman asked whether we
were next going to put an AT into the TS-50. Well, perhaps that was where the TS-480 got its start!

Achieving 200W output in a compact transceiver
In achieving our goal of 200W there was one major constraint – namely, we could not raise the
voltage of the power supply. The TS-480 Series was to be sold not only in Japan but internationally.
If we had been looking only at our domestic market, things would have been different since the
output of mobile transceivers here is limited to 50W, but conditions are different abroad, especially
in the US. In the US, since there are no limitations on the output of either mobile or fixed stations,
mobile transceivers in the several hundred watt class are not unusual. A common pattern for
operations is not to hook up a 100W unit to a linear amp and mount a 200W fixed transceiver in a
car. Moreover, the most common type of vehicle is a pickup with a 12V battery, so people expect to
obtain a 200W output with a regular 13.8V power supply.
If one thinks of the way people operate such transceivers here in Japan, a question arises: Why
add that much power if it cannot be used as a mobile rig? The TS-480 has been designed with a
priority on operating ease. One reason for this is that we saw the TS-480 being used as a fixed
station in Japan, where 200W mobile operations are not permitted. Most 200W HF transceivers
are high-end and their price reflects this. But in the workhorse class, most models offer only 100W
output. So we can say that our new product can fulfill the wishes of those who have received an
advanced permit and thus want a 200W rig – as long as it is not expensive.
6

Focusing on HF
Raising power output and adding an antenna tuner are both moves in the right direction, but
limiting the transceiver to the HF bands when the mainstream nowadays is HF~V/UHF would
seem to be going against the tide of the times. Yet opting for the multi-band route inevitably leads
to larger dimensions and higher prices. In this genre, price is an important factor, so by limiting the
TS-480 to HF, we developed what is in fact a compact transceiver that stands apart from the
competition. The TS-480 is designed to ensure not only excellent TX performance but also
superior RX performance.

7

Circuitry
●

TX circuits

200W final section
Explained here is the circuitry for the 200W final section, the crown jewel of the TS-480 Series.
This circuit is responsible for developing 200W output with a DC 13.8V power supply. Of course,
various approaches are possible. The typical one would be to use a high voltage (28V or more)
with the FETs in a push-pull arrangement. However, we did not adopt this approach since a
DC-DC combination that raises the voltage to 28V exclusively for this purpose was considered
inappropriate for a compact rig. The final section of a regular transceiver delivers 100W from 13.8V,
so the normal approach would be to use this as the basis for a 200W design. Hence, we
considered the pros and cons of using 4 final devices, each with 50W output, to produce a total of
200W.
I will not go into details here, but following our calculations and tests we discovered that simply
hooking up the devices in parallel would not be a practical solution because of issues related to the
output transformer. The solution we finally adopted was to have a pair of 100W final sections with a
standard push-pull arrangement, combining these to obtain an output of 200W. Since this is the
most popular method, we should perhaps have adopted it from the start, but having no past
experience with a transceiver producing 200W from a 13.8V supply, we looked at the design
issues from various angles including performance, quality, size, cost, and manufacturability.
When one simply says “combine”, there are in fact different ways to do this. For example, you can
take a pair of 100W final circuits and connect in series the secondary circuit of the output
transformer in phase to double the output, thus producing 200W. When we actually experimented
with this, we found that it worked okay. Frequency characteristics were good. However, using this
method means that one cannot provide isolation between the amplifiers. So what we finally
adopted was the old standby in situations like this – namely, a wideband hybrid combiner.
The circuit for this combiner is straightforward: if you reverse the input and output it will actually
work as a splitter. For the TS-480HX, we put together a 200W output final circuit by using this type
of combiner on the input/output of a pair of 100W final amplifiers. For the 50MHz band, we have
limited the output to 100W because of the heat that we knew would be generated from loss.
A hybrid combiner only works on the condition that the two signals are identical in amplitude and
phase. Since our final section was to operate in the HF~50MHz bands, it would qualify as
wideband in terms of frequency but there would be some concern for the balance frequency
characteristics. However, this sort of power combiner has been used before for general
applications, so in that sense it is an approach that can be adopted with some confidence.
When it came to the actual design (mounting), an ideal, symmetrical layout of the components was
not possible; however, care was taken to preserve the balance, for example by employing
isometric wiring for patterns in which there are many high-frequency currents flowing.
The device used was the 2SC2782 bipolar transistor. Since this has a collector loss of 220W, there
would a total loss of 880W in a 200W set equipped with four of them; this represents more than
enough leeway for operations.
Continuous transmission performance with such a compact design is explained in the section on
the TS-480 structure.

8

Fig. 1 illustrates TX IM characteristics with 200W output at 14MHz, while the second graph (Fig. 2)
charts high-frequency spurious emissions.
Fig. 1: TX IMD (output 200W)

Fig. 2: TX Spurious emissions

9

SPS (separate power sources) [TS-480HX only]
SPS is shorthand for “operating at 200W using two 100W 13.8V power sources.” To generate a
200W output from 13.8V requires a maximum (total) current of 41A. As previously explained, the
TS-480HX employs a pair of 100W final amps. What the SPS design does is to supply these
amps from two separate power supplies, as shown in Fig. 3 below.
The use of two power supplies may appear inconvenient, but in actual fact this arrangement is
quite practical. Many customers already possess a 100W class power supply, so when they
acquire this 200W transceiver they do not have to make an additional purchase of a new 200W
class power supply. It is possible for them to make use of the 100W unit in their possession.
The PS-53 power supply is specified for the TS-480; however, as long as it can produce 20.5A or
more continuously at 13.8V, other power supplies can be used. Also, it is possible to operate this
transceiver using a single power supply that can produce at least 41A continuously; note, however,
that two power cables would still be needed.
Fig. 3: SPS schematic diagram

DC1 connector

Drive amp
Final amp 1

Other circuits

Final amp 2

Chassis

DC2 connector

10

DC power
supply 1
(13.8V, ≥20.5A)

DC power
supply 2
(13.8V, ≥20.5A)

Failsafe device (some TS-480HX versions only)
The use of two power supplies and two final amps in parallel is something that has not been tried
before, and naturally there may be some anxiety on the part of the user regarding what would
happen if just one of the power supplies suddenly failed. Such a situation would be handled safely,
since the TS-480 series is equipped with several failsafe devices.
Should a difference of 1V or more be detected between the two power supplies: “RX ONLY”
appears in the display and transmission operations are inhibited.
Should the voltage of one power supply drop to zero: if the failed supply is DC1 (Fig. 3), the
transceiver is powered down; if DC2 fails, “RX ONLY” appears in the display and only RX
operations are possible.
Should a final amp malfunction: if, for example, the output of one of the final amps fell, resulting
in an imbalance, “PA-ERROR” appears in the display and transmission operations are
terminated.
In addition, there is the usual complement of failsafe devices, including output control triggered by
high temperature, high voltage detection, and SWR output control. These failsafe devices will
provide temporary protection for the internal circuitry; however, should such a situation arise you
should not continue using the transceiver, but rather deal with the problem in accordance with the
troubleshooting guidelines.

100W final section
Like the 200W final section, the 100W final section uses 2SC2782 transistors. The drive and
peripheral circuits are virtually identical to those in the 200W model, enabling 100W output for the
HF~50MHz bands.
For the Japanese market, there are 50W and 10W (50MHz: 20W) models, allowing buyers to
choose whichever best suits them – that is, their license and their intended use (mobile or fixed).
It should be pointed out that it is possible to increase the output of these models: the 50W model to
100W, and the 10W model to 50W or 100W. A TS-480 owner who acquires a more advanced
license and wants to make use of this capability should go to the nearest service center. Note that
it is not possible to upgrade to 200W output.
Also, 50W mobile transceiver warranty certification is available for both 200W and 100W models
used as fixed stations.
Ever since the TS-570, Kenwood has adopted a method of converting transceivers to higher
output specifications that does not require a kit. Conversion cannot be performed by the individual
user, but because this method does not depend on finding stock of the appropriate kit it is proving
popular.

Antenna tuner (TS-480SAT)
The 100W model is equipped with the relay-driven antenna tuner that was developed for the
TS-570. Since there is no variable capacitor, gears or other rotating parts, this antenna tuner is
very responsive and trouble-free. Thanks also to the several preset memories supplied for each
band, you can instantly call up settings when moving up or down a band.
You can see the 200W and 100W final sections in Figs. 4 and 5, respectively.

11

Fig. 4: 200W final section

Fig. 5: 100W final section with antenna tuner

12

FM circuit
There were two approaches used for the FM circuit of the conventional all-mode transceiver. Either
there was a dedicated modulation circuit using a 10.695MHz crystal, or the modulation was
performed by the VCO on the 2nd OSC. The latter was not an option for the TS-480, and since the
whole transceiver had to be compact, we did not adopt the former approach. How then is FM
handled by the TS-480?
What we have employed for the TS-480 is something that is rarely seen these days in ham radios:
the reactance modulation approach, which does not have the modulation applied directly to the
oscillating circuit. This type of circuit was widely used in the days when a crystal was used to
change channels in FM car transceivers, but it dropped from sight when PLL became the norm. It
is not a new circuit, but it has excellent characteristics. In the TS-480, this reactance modulation
circuit is connected to the output of the DDS, which serves as the source for the PLL reference
frequency, so effectively it is modulating the 1st OSC.
This approach offers several advantages:
Since frequency modulation is not conducted in the TX signal circuitry, even if the TX RF signal
is passed through a roofing filter, it will not suffer from any delay distortion caused by the filter;
Since there is no need for an oscillator to perform modulation, “one-shot“ frequency
management is permitted when transmitting on FM with the same precision as SSB;
This approach saves on space and cost.
Fig. 6: FM modulation block diagram

13

●

RX circuitry

Front end
As explained in the section on development objectives, what distinguishes the TS-480 Series are
incomparable features and performance that result from our focus on HF. Of special note are the
dynamic range characteristics in the HF bands, demonstrating the fact that, despite the compact
dimensions of this transceiver, there has been no design compromise.
One of the circuits that is important in determining dynamic range is the first mixer. Now there are
some compact transceivers covering HF~V/UHF that are designed to cover all frequency bands
with a single mixer. Since HF~50MHz is the “home turf” for the TS-480 Series, it has an advantage
as in regards to the operating conditions for the mixer. Since developing the TS-950, Kenwood has
exclusively employed J-FET quad mixers, and the TS-480 is no exception. Fig.7 illustrates the
mixer circuit.
Fig. 7: RX 1st mixer

14

How well does it actually perform? Fig. 8 is a graph illustrating the dynamic range characteristics
when changing the separation of two interfering signals. For the sake of reference, results for the
TS-480 are plotted against those obtained using other compact mobile transceivers (on the
market) under the same conditions.
Fig. 8: RX dynamic range

Looking at Fig. 8, results higher up the graph indicate wider dynamic range.
When the RX frequency is 14.100MHz, and for example there is simultaneous interference from
two signals at 14.150MHz and 14.200MHz, with the nonlinearity of the RX section, spurious
signals are generated at 14.100MHz and 14.250MHZ, enabling reception. Since the frequency
separation at this point is 14.200MHz -14.150MHz = 50kHz, the +50.0KHz point on the horizontal
axis of Fig. 8 corresponds to these conditions. Under these conditions, if there were interfering
signals that were faintly picked up by the other transceivers in this comparison, the strength of
those interfering signals would have to rise by 10~15dB for the TS-480 to begin suffering the same
effects.
When there is interference in close proximity to the RX frequency, there is no difference between
these models, with one notable exception. In this area we are approaching the bandwidth of the
roofing filter, so to put it another way, the fact that we can observe a difference between the
transceivers at the +50kHz point – where the interference is sufficiently eliminated by the roofing

15

filter – reflects a difference in the manufacturers’ approach to design from the antenna to the 1st
mixer.
It is not just the mixer that determines the characteristics of the front end: all of the components
between the antenna terminal and the mixer can have an impact.
Despite the compact design of the TS-480 Series, its RX BPF divides up the 500kHz~60MHz
range into 10 bandwidths. Since several coils are employed in this BPF circuit, small coils have to
be used in a compact transceiver. When discussing front end linearity, attention focuses on
semiconductors such as the PIN diode for switching bands, but in fact the coils used in this BPF
can be “nonlinear” parts, depending on operating conditions. Differences in their characteristics
become more noticeable the smaller they are. In the early stages of developing the TS-480, we
looked at the mutual modulation characteristics of a number of coils, picking only those that
demonstrated the best performance.
With this compact transceiver it was not possible to use a passive tuner equivalent to what is found
in top-end models, but our emphasis on HF performance was such that we selected components
whose advantage cannot even be appreciated from a circuit diagram.
Fig. 9 is a graph demonstrating RX sensitivity. Needless to say, for HF, especially in the low bands,
there is more importance attached to multi-signal characteristics than to sensitivity, but obtaining a
sufficient level of sensitivity can be vital during mobile operations when one cannot expect much in
the way of antenna gain.
As with previous models, sensitivity is set to switch at 21.5MHz with the pre-amp on. However,
there is a difference: previously the pre-amp itself was switched, but in the case of the TS-480 this
is managed by switching the pre-amp’s NFB gain.
Fig. 9: RX sensitivity

16

Jumpers for joy
As with the TS-2000, something special has been provided for both the BPF ATT in the BC band
and the regular ATT:
The BPF has been equipped with an ATT in order to cope with powerful local broadcasting
stations in the BC band. However, a jumper can be used to switch from NORM to DX, bypassing
this ATT and raising sensitivity by about 20dB.
The ATT accessible from the control panel defaults to 12dB, but by removing the CN4 jumper it
is possible to increase this to about 20dB.
Fig. 10: Jumper locations
RF unit (X44-3270-00) component surface (J72-0874-19)

ATT at BC band

17

Circuitry after the roofing filter
Except for FM, the TS-480 has a double super: 1st IF is 73.095MHz and the 2nd IF is 10.695MHz.
For FM, there is also a triple super as low as 455kHz. This is followed by analog detection and
signal processing performed by the AF DSP in a standard arrangement. The AF DSP is not
optional: it is equipped as standard. DSP features and characteristics are explained in the DSP
section.
Three newly developed optional filters are available for the 2nd IF. Previously, there was only one
10.695MHz optional filter: the YK-107C (500Hz). This filter was developed at the same time as the
TS-790, and since the focus was on its use for V/UHF, there may have been times when users felt
it was lacking when it came to HF operations. So when we were developing the TS-480, we
redesigned the 500Hz filter, greatly improving its shape factor. We also used the opportunity to
design new 270Hz and 1.8kHz (SSB narrow) filters.
Fig. 11 graphically illustrates the difference between these filters in the 500Hz band.

Fig. 11: Comparison of optional CW filters (500Hz)

18

Whereas the TS-570 provided only a single slot for installing an optional filter, the TS-480 has two
slots, meaning that two of the three filters can be installed at the same time. And the process of
installation itself is quite easy: there is no need to remove the main unit, since the option installation
unit has been designed to be separately removable.
The photograph in Fig. 12 shows the option installation unit. This can be used to install not only
these IF filters but also a high-stability TCXO SO-3 (±0.5ppm, -10~+50°C), which is optionally
available.
Fig. 12: Option installation unit

If you unclip the white connectors on either side and remove the screws
that hold the board in place, you can independently remove the unit for
installing the optional filters.
Since the type of filter is recognized automatically, it does not matter in
which order you install filters in the slots.

19

Auxiliary Features
In addition to the basic TX/RX circuitry already described, the TS-480 is equipped with a number of
auxiliary features of considerable practical benefit. What follows is an introduction to some of
these.
●

Full compatibility with digital modes (data modes)

PSK31 and RTTY operations can now be performed with ease using PC software. The TS-480
has been designed to make it easy to use such digital modes.
External audio input/output terminals, separate from the mic and speaker terminals, are provided.
For each of these the level can be adjusted in ten steps.
You can select special AF DSP filters for use with digital modes. Specially provided for PSK31
use is the choice of either a 1000Hz or 1500Hz beat frequency.
With the optional CW filters installed, you can choose between them even during SSB reception,
which we have had many requests for.
It is possible to switch the VOX function so that it will respond either to mic input or to an external
audio signal. No special standby wiring is needed for making digital use of this VOX function.
When transmitting voice with PTT, external input signals are muted. Conversely, when
transmitting using an external input, the mic input is muted; thanks to this feature, there is no
need to disconnect the mic during digital mode operations. (Note that if you put an external input
on standby using the mic PTT, it will not be modulated; sometimes users have queried as a
possible fault, but it is not.)
●

Features useful for 50MHz operations

You discover a DX CW signal during a USB band search! The TS-480 has a feature that is
perfect for such times: you can automatically switch to CW transmission by just keying the
transmitter (key down) with your CW key, keyer or CW computer program.
When scanning 50.110~50.150 with the SSB program scan, if you want to watch carefully at
10kHz intervals just use a slower scan speed. This is also possible with memory scan, but in that
case you cannot hear frequencies in between. This allows you to set the scan speed slower by
up to 5 points for selected frequencies.
The noise blanker, which has a reputation for being very effective in combating even weak noise,
is now even better: we have added the ability to adjust the threshold level.
●

Features useful for mobile operations

The TS-480 is equipped with a newly developed DNL (digital noise limiter). Although the principle
and operation of this DNL is quite different, the effect is somewhat like the old ANL (audio noise
limiter). Pulse noise is handled by a standard noise blanker, but if you find this is not working very
well as a result of a strong signal overlap or because of different types of noise, you should give
the DNL a try. In some cases, by processing audio signals with the DSP one can effectively
eliminate pulse noise. For details, see the DSP section.

20

TX tuning is a handy feature to have. It outputs a low-power continuous carrier for adjusting a
screw-drive or similar antenna. It allows you to transmit a continuous carrier that is independent
of the mode and power of your current operations. Simply assign a PF key to this function.
No paddle, but you want to give CW a try? No problem. With mic paddle mode, you can use the
up/down keys on your microphone as a simple paddle.
●

New 5MHz band

US versions are compatible with the new 5MHz band; this also goes for the antenna tuner.

21

Features of the Built-in DSP
●

DSP circuit
The digital signal processor equipped on the TS-480 is the 16-bit
fixed-point TMS320VC5402 from Texas Instruments, which
offers excellent value for the money. Running at 100MHz, it
provides double-precision arithmetic operations (equivalent to
32-bit processing), making it more than capable of serving as an
AF DSP. Thanks to this, the TS-480 offers many powerful
features of use in HF operations.

Ideal for mobile operations: DNL

NEW
When you hear the crackling of ignition and other types of pulse noise, it is possible to remove it
using the noise blanker (NB); however, this does not work in all cases. Depending on the type of
noise, or if there is a very strong signal close by, the pulse noise may remain and be demodulated.
This can result in an unpleasant sound being emitted from the speaker, thus reducing the clarity of
your target signal. In such cases, the DNL (digital noise limiter) can reduce pulse noise that has
been demodulated at the AF stage, effectively extracting your target audio signal.
Fig.13 is a block diagram illustrating in principle how the DNL operates.

●

Fig. 13: Principle of DNL operation

BPF

Delay device

Calculation of
amplitude
variation

LPF

Removal
of DC
component

Delay device

22

Derivation of
attenuation
coefficient

First, the input signal is divided into its low- and high-frequency components. Ignition and other
pulse noise tends to be concentrated in the latter, from which amplitude variation is output. The
attenuation coefficient derived from this signal is multiplied by the input signal. As soon as pulse
noise occurs, the attenuation coefficient rises instantaneously, thus damping the amplitude
variation in the input signal. Because of this adaptive processing performed by the DNL and based
on the amplitude variation, the output signal has virtually none of the “digital feel” that is often the
mark of digital signal processing. It is perhaps only natural to associate this DNL with the old “noise
limiter” technology, but as explained it works on a completely different principle, performing the sort
of advanced processing that is only possible with DSP.
Because the TS-480 will be often used for mobile operations, DNL parameters have been tuned
so as to have maximum effect on ignition noise. However, even when used as a fixed station, it
can be very effective on irregular, unanticipated noise, so we recommend that you try making use
of it, in combination with the noise blanker as well.
Fig.14 demonstrates how ignition noise is reduced by the DNL.
Fig. 14: The effect of DNL on ignition noise

The DNL works in SSB, CW, FSK and AM modes, and it can be used in conjunction with other
interference reduction and noise elimination features.
●

Noise reduction

There are two methods available for noise reduction: NR1 and NR2. NR1 is a line enhancer that
employs adaptive filter technology. By shaping a filter that lets through signals with a certain
amount of periodicity, as with voice and CW, it can suppress noise that falls outside the passband.
NR2 employs what is known as SPAC (speech processing by auto correlation) technology. What
results from looping one cycle of the RX signal’s autocorrelation coefficient is then output as the
received audio. What this means is that only periodic signals found in the received audio emerge.
In principle this approach can result in a small amount of noise at the “seam” where the periodic
signal is looped together, but in practice it proves extremely effective at noise compression.
NR1 is a good choice for SSB and other audio signals, while NR2 is especially effective when
used with single frequencies, as with a CW signal.
Figs. 15~17 demonstrate the effect of applying NR1 and NR2. For comparison purposes, the
same weak sine signal was received, with the audio output monitored by an FFT analyzer.

23

Fig. 15: NR OFF

Fig. 16: NR1 ON

Fig. 17: NR2 ON

24

●

Beat cancel

Beat cancel (BC), as its name implies, is designed to cancel unpleasant beat interference. Like
NR1, it uses adaptive filter technology, tracking a beat and canceling it by shaping. It is very similar
to a band elimination filter. Even if there are multiple beats, BC can track and cancel them all.
However, since BC operates at the AF stage, should powerful beat interference be experienced
during DX operations, even though beat cancel works properly, by then the AGC has already
attenuated both the interference and the target signal. To combat this sort of beat, IF shift is used
to eliminate the interference.
Figs. 18 and 19 show how BC cancels beat signals, as monitored by an FFT analyzer. You can
see how the three beats present in the signal are removed with almost surgical precision.
Fig. 18: BC OFF

Fig. 19: BC ON

There are two methods available for beat cancellation: BC1 and BC2. These have been tuned so
that BC1 is effective against weak or continuous beat interference, while BC2 cancels intermittent
beat such as a CW Morse signal. (Note that since BC is designed to remove the beat, and does
not function in CW mode.)

25

● RX DSP filters

In SSB, AM and FM modes, you can independently set high- and low-cut frequencies for the AF
filters to suit operating conditions (slope tune).
Fig. 20 illustrates how slope tune works. When there are interfering signals in proximity to the
target signal, you can use a high-cut filter and a low-cut filter to remove the signals above and
below the target.
In SSB mode, installing the optional SSB narrow filter results in even better interference reduction.
In AM mode if you select NAR, RX is possible using this SSB IF filter.
Target signal

Interference

Interference

Target signal
Low-cut

Hi-cut

Interference

Interference

Fig. 20: Slope tune in action
Listed below are the cutoff frequencies (unit: Hz) that can be chosen; default values are shown in
bold.
SSB/FM
Low-cut
Hi-cut

0
50 100 200 300 400 500 600 700 800 900 1000
1000 1200 1400 1600 1800 2000 2200 2400 2600 2800 3000 3400 4000 5000

AM
Low-cut
Hi-cut

0 100 200 500
2500 3000 4000 5000

In CW and FSK modes, the AF filters function as a VBT, changing bandwidth without altering the
center frequency. In CW mode, the center frequency is coupled to the CW pitch, whereas in FSK
mode it is determined by the FSK tone and FSK shift frequencies.
Fig. 21 shows how it is possible during CW operations to extract a target signal from surrounding
interference by changing the AF filter bandwidth (WIDTH).

26

Target signal

Interference

Interference

Target signal

Interference

Interference

Fig. 21: Switching WIDTH
during CW operations
Listed below are the filter bandwidths (unit: Hz) that can be chosen; default values are shown in
bold.
CW
WIDTH

50

FSK
WIDTH

250 500 1000 1500

80

100 200 300 400 500 600 1000 2000

When the optional CW filters are installed, the TS-480 will automatically select the optimum IF filter
in accordance with the DSP filter bandwidth.
Also available are filters for PSK31 and RTTY data mode operations. From the menu, if you select
ON for the “Available data communications filters”, these data communications filters can be used
in SSB mode. You can choose from 3 center frequencies and 7 WIDTH settings.
Listed below are the filter types (unit: Hz) that can be chosen; default values are shown in bold.
For data
communications

Center
WIDTH

1000 1500 2210
50 100 250 500 1000 1500 2400

During PSK31 operations, the center frequency is set to either 1000Hz or 1500Hz.
Furthermore, since it is now possible to select an optional CW IF filter in SSB mode, it is possible
to narrow the bandwidth.
27

●

RX equalizer & TX equalizer

If you use the RX equalizer it is easy to adjust RX audio quality. Take your pick from flat (default),
high boost, Formant pass, bass boost, and conventional settings. As a new feature, the TS-480
actually offers two types of high boost and two types of bass boost.
TX audio quality can similarly be adjusted with the TX equalizer. It is easy to make any changes to
suit your taste: for example, mic characteristics can be corrected, and you can apply
compensation to match the characteristics of your own voice. For TX there are now two types of
high boost and two types of bass boost, so why not give them a try?

The graph in Fig. 22 plots overall
frequency characteristics from mic
input to antenna output, illustrating
the effect of some of these
equalizer settings.

Fig. 22: TX equalizer characteristics (example)
If you use the Audio Editor function (ARCP-480), available free for downloading, the options for
equalizing expand even more. In addition to a total of 35 types of equalizing samples, it offers tools
for freely adjusting such parameters as filter type, cutoff frequency and amount of attenuation. The
settings made with the ARCP-480 software can be applied by selecting U (user) from any of the
TS-480’s equalizer menus.
While it is true that neither the built-in equalizers nor the audio editor software provide the same
degree of freedom as the graphic equalizers found in audio entertainment equipment, they are
useful as a means for tailoring audio quality to suit.
●

CW auto tune

A useful feature for tuning in to another station is CW auto tune. There is more than one method
for zeroing in on a target frequency – such as matching RX beat with sidetone pitch, or getting the
pitch frequencies that can be heard when CW reverse is ON and OFF to be the same – but it is
very easy if you engage CW auto tune when you can hear the other station. It just takes the press
of a button to make the VFO automatically zero in on the target. Note, however, that there are
various limitations associated with this feature – for example, the tuning range is 300Hz on either
side of the pitch frequency, and it can be confused by interference – so you should learn how to
make good use of it.
28

Tips
As with other Kenwood HF transceivers, the TS-480 provides menu access to its many features.
By selecting and adjusting these features, you can customize the TS-480 so that it fits perfectly
into your way of operating a radio. Introduced here are tips on how to get the most out of the
various items listed in the menus.
●

TS-480 menus
Group

#

Function

Operator
interface

00

Brightness of display
backlighting
(5 levels, including OFF)

01

Key illumination ON/OFF

02

Auto mode

03

Tuning control adjustment
rate

04

Frequency step for the main
encoder in FM mode

05

Frequency rounding for the
MULTI control

06

Frequency step size for BC
band

Memory
channels

07

Temporarily change memory
frequency

Scan
functions

08

Program slow scan

09

Program slow scan setting

10

Program scan hold

11

Scan resume method

Tuning

Use
You can adjust brightness to suit the
ambient lighting level. Turning
backlighting off reduces power
consumption by about 30mA.
Turning illumination off reduces power
consumption by about 30mA.
Mode can be changed automatically
depending on frequency. This is more
convenient than setting VFO A to CW
and VFO B to USB.
By reducing the adjustment rate, you
can make it easier to tune.

29

You can change frequency with the
main encoder in the same way that
you can change channels.
With this switched OFF, if you
accidentally change frequency with the
MULTI control, you can return to the
original frequency.
When ON, frequency step size is
9kHz. When OFF, step size is
determined by the STEP value. The
factory setting for US models is OFF;
for other markets ON is the default.
Switch ON to operate a frequency in
memory without transferring it to a
VFO.
Useful for 50MHz scanning.
You can choose how much to slow the
scan.
You can pause the scan for 5 seconds,
a handy way to avoid missing a signal.
You can switch between time-operated
and carrier-operated scan resume to
suit your purpose.

Volume
adjustment

You can adjust this to suit your
preference.
For full break-in, it is easier to hear the
sidetone if you raise this volume.
You can check what has been
recorded.

12

Beep output level

13

Sidetone volume

14

VGS-1 message playback
volume

15

VGS-1 announcement
volume

16

VGS-1 announcement
speed

RX IF filters

17

Use CW IF filter for SSB
reception

This is useful for PSK31 operations.

DSP
equalizers

18

DSP RX equalizer

19

DSP TX equalizer

DSP TX
filters

20

DSP TX filter bandwidth

Fine-tuning
TX output

21

TX power output control

TX control

22

Time-out timer

Transverter

23

Frequency when using
transverter

24

Output power adjustment for
transverter

You can adjust frequency
characteristics during reception. Select
the position that best suits your
external speaker/headphones.
As with #18, this is not as versatile as a
dedicated graphic equalizer, but it is
useful for tailoring TX frequency
characteristics to match your mic and
voice.
As this is AF DSP, it is not as versatile
as IF DSP, but it can be used to
remove low frequencies during
transmit.
You can choose between a 5W step
and a 1W step. Useful for fine
adjustment of output when using a
linear amp.
This automatically terminates
transmission after a set time. Useful as
a failsafe for network (KNS)
operations.
You can change the frequency
displayed by the transceiver to the
operating frequency of the Transverter.
Unlike the TS-570, you can set any
frequency.
Transverter output is fixed at 5W for
the TS-570, but with the TS-480 you
can choose output freely (within the
transmitter’s capability).

Switch this OFF if you do not need
announcements while working the
radio.
You can adjust this to suit your
preference.

30

Antenna
tuner

Linear amp

Message
playback

25

TX hold when internal AT
completes tuning

26

In-line AT while receiving

27

External AT control method

28

Linear amp control for HF
band

29

Linear amp control for
50MHz band

30

VGS-1 constant recording

31

Repeat playback of
voice/CW messages

32

Interval time for #31

After completion of tuning, there is still
approximately 10W of output, so this is
useful if you want to go on to tune the
linear amp.
The internal antenna tuner can also be
used during RX. Depending on
conditions, sensitivity can vary by
enough to see a change in the
S-meter. It can also reduce
low-frequency interference.
If you own an AT-300, you can connect
it to the TS-480; however, operation is
limited by the capabilities of the
AT-300.
You can control the linear amp
independently for the HF and 50MHz
bands. And if the amp is not
compatible with full break-in, you can
add in a delay for the TX attack.
With the VGS-1 Voice Guide and
storage unit installed, you can engage
constant record for the RX signal.
Maximum playback time is 30
seconds.
This is not just for contest CQ
machines; it can be used as a simple
beacon.
Interval time can be adjusted up to a
maximum of 60 seconds.

31

CW

FSK

FM

Without switching off the repeat
playback for messages, you can start
keying.
Select RX pitch frequency between
400Hz and 1000Hz. At the same time,
sidetone frequency changes with the
pitch frequency. This can be used to
zero in on a target signal by matching
the sidetone frequency with the RX
beat.
Change the dot/dash weight ratio. This
is usually set to AUTO.
You can change the AUTO setting for
#35.

33

Keying priority over playback

34

CW RX pitch / TX sidetone
frequency

35

CW keying weight ratio

36

Reverse CW keying auto
weight ratio

37

Bug key function

38

Swap dot & dash paddle
position

39

Auto CW TX in SSB mode

40

Define CW tune frequency

41

FSK shift

42

FSK keying polarity

43

FSK tone frequency

44

Mic gain for FM

You can adjust FM mic gain (3 levels)

Filter bandwidth for data
communications

This enables you to pick the
appropriate DSP filter for data
communications using the filter switch
on the control panel.
Adjust input and output levels
independently when the TS-480 is
connected to a SoundBlaster™ card or
other external device.

Data
45
communicat
ions
46

AF input level for data
connector

47

AF output level for data
connector

Manual TX can be enabled for dashes
only.
Swap the paddle position to suit either
right-handed or left-handed use.

32

Automatically switch mode to CW
transmission by simply operating the
paddle.
Useful if used in combination with #39,
as there is no need to operate the dial
to zero in on a target.
Standard FSK operating parameters
are covered by these menus.

PF keys

You can assign functions to the PF
keys on the control panel as detailed in
the separate table.
You can assign functions to the PF
keys on a multifunction mic as detailed
in the separate table.

48

Assign PF keys on the
control panel

49

Mic PF1 key

50

Mic PF2 key

51

Mic PF3 key

52

Mic PF4 key

Split
frequency
transfer

53

Split frequency transfer

54

Permit to write #54 to target
VFOs

TX inhibit

55

TX inhibit

PC data rate 56

COM port communication
speed

External
devices

57

DTS polarity

TX inhibit

58

Busy lockout

APO

59

APO (auto power off)
function

VOX source 60

Transfer modes/frequencies between
compatible transceivers. Useful when
one is being used as a slave receiver.
Inhibits TX, which is useful if the
transceiver is to be used for RX only as
it prevents unintentional transmissions.
Select 4800~115200bps.
In data communications this switches
the logic for transmission. You should
match polarity to the external device
you are using.
You can select BSY lockout to inhibit
transmission when busy.
Power can be switched off
automatically in the absence of any
operations.
Select either the mic or the data input
for VOX activation. Standby wiring may
not be required provided that the
method used is compatible with data
communications. (Be careful to ensure
correct TX delay.)

Select input for VOX

33

● Functions that can be assigned to PF keys

#

Assigned
function

Use

0~60

MENU #00~60

61

Voice1

62

Voice2

The selected menu item can be called up directly, making this
useful for menu functions that you often use.
In addition to the automatic Voice Guide, you can have
frequency and other displayed data read out when you press a
PF key.
S-meter reading is read out when you press a PF key.

63

RX monitor

64

RX DSP monitor

65

Main encoder
lock

66

SEND key

67

TX tuning

68

LSB/USB toggle

The squelch can be forced open for as long as the PF key is
depressed. Useful for monitoring when setting CTCSS, etc.
The TS-480 will receive using the widest passband available in
that mode for as long as the PF key is depressed. This is a
quick way to check on nearby interference.
You can lock the main encoder. This prevents unintentional
operation of the encoder when the transceiver is being used in
a vehicle.
There is no SEND key on the control panel, but this role can
be assigned to a PF key.
Irrespective of the current operating mode and power, this
function allows you to transmit a continuous carrier at a fixed
output. Useful for configuring external devices.
Toggle between LSB and USB when LSB (USB) is displayed.

69

CW/FSK toggle

Toggle between CW and FSK when CW (FSK) is displayed.

70

FM/AM toggle

Toggle between FM and AM when FM (AM) is displayed.

34

71

TF-SET

72

Q MR

73

Q MI

74

SPLIT

75

A/B

76

M/V

77

A=B

78

SCAN

79

M >V

80

M.IN

81

CW TUNE

82

CH1

83

CH2

84

CH3

85

FINE

86

CLR

87

MTR

88

MHz

89

ANT 1/2

90

NB

91

NR

92

BC

93

DNL

99

OFF

You can assign a function you often use to a PF key on the
mic. Also, a function defined by pressing the key for 1 second
can be called up instantly. For example, if you find yourself
frequently switching between antennas, you can save time if
you assign a panel PF key to ANT 1/2.

No function is assigned to the PF key.

35

●

Making menus easier to use

Menu switching
There are so many different menu selections and parameters to choose from that it is impossible
to remember them all. Consequently, the menu system can be a little inconvenient when you need
to change several settings at once.
To solve this problem, the TS-480 offers two sets of menus: A and B. Switching between these
can greatly simplify operations – for example, when switching from DX to local, from regular to
data communications, or from fixed station to mobile operations.

Quick menu
The TS-480 offers many menu functions. If you know which functions you use most of the time,
you can arrange for other functions to be hidden when selections are displayed.

36

Structural Features
●

Internal structure of the main unit

The internal structure of the main unit is straightforward: employing a die-cast aluminum chassis, it
is designed so that the circuit boards are attached from both above and below. From above one
can see the TX/RX unit, the filter unit and the relay unit; seen from below, there are the RF unit and
the final unit (or final/AT unit, in the case of the SAT model). There is also a separate display unit in
the standalone control panel.
Figs. 23~25 illustrate the arrangement of these units.

Filter unit

Relay unit
Final unit

RF unit

TX /RX unit
Fig.23: View from above (both models)

Fig.24: View from below (TS-480HX)

Final /AT unit

RF unit

Fig.25: View from below (TS-480SAT)

37

●

Cooling

In developing the TS-480HX, the most important issue when it came to structural design was how
to arrange for sufficient cooling.
In order for this transceiver to be capable of 200W output and yet have the same compact design
as the TS-50, we examined dozens of different cooling fans, various circuit board patterns, and a
variety of different cooling fan layouts. After conducting several hundred different types of heat
dissipation tests, we finally decided on the present structural design of the TS-480.
The principle features of this structure are as follows:
Improved cooling efficiency as a result of employing twin cooling fans;
Concentration of efficient cooling fins in one location since space limitations meant that a normal
fin arrangement was not possible.
Fig. 26 illustrates how the TS-480 is cooled. The air that is sucked in through the front panel and
the top and bottom of the case directly cools the surface of those internal components that are
generating heat, such as the final section. At the same time, it absorbs the heat that has dispersed
through the die-cast chassis before being expelled by the twin cooling fans at the rear.

Fig. 26: Cooling diagram
Blue: Die-cast aluminum chassis
Red: Heat flow from final transistors
Brown: Circuit boards
Gray: Air flow (from front panel on left)

As you can tell from this diagram, the cooling fans located at the rear must be powerful enough to
be able to suck in fresh air through the intakes on the front panel. In order to make the TS-480 as
compact as possible the mounting density of the internal components has been increased; for this
reason, we decided to install a pair of powerful cooling fans so as to ensure a strong flow of air and
the increased cooling efficiency that would result.

38

The TS-480HX is equipped with 4 final transistors (2 in the case of the SAT model), and the heat
produced by these disperses through the die-cast aluminum chassis. In order to efficiently transfer
this heat outside the transceiver, cooling fins are absolutely essential. We would like to provide as
many of these fins as possible, but in fact on more than one occasion we have found that, owing to
space limitations, we were not able to fit in the normal complement of cooling fins. In the case of
the TS-480, in order to make the transceiver compact we provided a single row of tall, highly
efficient cooling fins right above the final transistors. This compensated for the lack of cooling fins
dictated by the design restrictions.
Our decision to suspend the filter unit was made in order to fit in as many cooling fins as possible
by packing in the components.
Figs. 27~29 are photographs of the
TH-480HX die-cast aluminum chassis.
The final transistors are positioned on the
four raised areas (circled) that can be seen
in the middle of the chassis (underside).
On the opposite side to the final transistors,
running across the middle of the upper side
of the chassis, can be seen a row of
relatively tall, flat cooling fins.
Fig. 27: Upper side

Fig. 28: Underside

Fig. 29: Fin

The air that is sucked in from the front is divided into two flows, one through the top of the chassis
and the other through the bottom. The upper flow of air must pass through these high-efficiency
cooling fins, absorbing the heat from them before it is expelled to the outside.
These fins, which also serve as a partition between the TXRX unit and the filter unit, are set
diagonally so as to offer a degree of shielding.

39

Now let’s have a look at the rise in temperature of the different parts when the TS-480HX transmits
continuously (14MHz) for 30 minutes at 200W. To provide a comparison, plotted on the same
graph is test data compiled for a compact 100W model (designed so as not to power-down during
continuous transmission at 100W).
Fig. 30: Temperature rise around final transistors

Fig. 31: Temperature rise of die-cast aluminum chassis around GND terminal on rear

40

Fig. 32: Temperature rise measured at center of the upper case of the main unit

As you will appreciate from these results, despite the fact that the TS-480HX has an output of
200W, twice that of the comparison model, it boasts the same or even better cooling performance.
It is not only designed not to power-down (for temperature protection) during continuous, normal
transmission, but you can see that we have taken into full consideration the rise in temperature
that occurs during continuous transmission.
Despite the fact that the TS-480 Series is compact, it has the same heavy-duty specifications as
the previous, fixed station model. Nevertheless, electronic components, whether from Kenwood or
another manufacturer, are generally susceptible to heat: the higher the temperature, the shorter is
their working life. Therefore, in order that you can use the product for a long time, we recommend
that you adjust output to suit conditions.

41

●

Standalone control panel

In the compact size range, virtually all transceivers are designed so the control panel can be
removed and replaced. While this is convenient, owing to the small dimensions of the main unit,
the area of the front panel is necessarily limited. Consequently, in order to access the many
functions that are used in HF operations using only a limited number of switches, hierarchical
menus are unavoidable.
As explained in the section on development objectives, we started out with the premise that the
TS-480 would not be limited to mobile applications but that it would be able to serve as a
reasonably priced 200W fixed station. So rather than going for a simple appearance, we decided
on a standalone control panel in order to provide true operating ease.
By separating the control panel from the main unit, its size can be decided independently of the
cross-sectional area of the main unit. As a result, we were able to realize just about the same
operability as one would expect of a conventional base station. Naturally, at the same time we
adopted a large TN LCD, thus ensuring a responsive, easy-to-view display.
For the main encoder, we picked a magnetic encoder with 250-pulse resolution made by Copal
Electronics Corp., using software to quadruple resolution to 1000 pulses per revolution. Since this
encoder uses the same components used in virtually all of the models in Kenwood’s HF fixed
station lineup, even during mobile operations it should offer the same operability as during fixed
station operations. In addition, by ringing the main encoded dial with rubber we have further
improved operating ease, since it provides a good grip and is more pleasing to the touch.
In addition, installed inside this standalone panel is a 66mm-diameter speaker. Since the speaker
grill is on the rear of the panel, you might wonder whether it can deliver sufficient volume. However,
when you are actually using the standalone panel, you will find that the sound is reflected off your
desk, the dashboard of your car, or the windshield, that is indeed loud enough.
●

Design concept

The standalone panel of the TS-480 Series draws on the design of the TS-2000. While inheriting
the best aspects of the former model’s design, the new series represents an evolution in design
with added emphasis on the 3D look, sharpness, and the power that is associated with 200W
output. Also, the case of the main unit has been given a rounded form so as not to appear simply
as a box; its design creates the impression of aesthetic unity.
The TS-2000 was mainly designed for fixed station operations, so it has a silver-colored control
panel. The TS-480 is of course expected to be used more frequently for mobile operations so a
black color scheme was chosen. Black helps to minimize light reflection when used outside in
sunny conditions.
Of course the part of the transceiver that is most frequently touched is the main encoder dial. Each
one is carefully machined and processed. After spin finishing, it is treated with titanium-colored
alumite. The design of this main encoder dial is one of those features the TS-480 has inherited
from the acclaimed TS-2000.
Of course, we were not exclusively concerned with design aspects – for example, adopting backlit
rubber keys with a creamy-white base in order to improve visibility, and mounting the speaker in
the rear of the standalone panel. We believe that our design enhances visibility and operating ease
in both fixed and mobile operating environments.

42

New Option: Voice Guide & Storage Unit (VGS-1)
Developed at the same time as the TS-480, the VGS-1 can be
installed as an option. Combining in one unit the functions of the
voice synthesizer unit (VS-3) and the digital recording unit
(DRU-3A) previously offered by Kenwood, the VGS-1 goes
beyond both of these.
Let’s now take a close look at the functions that are available using
this unit.
NEW
Haven’t you ever wondered if your callsign was being used correctly by other stations while on a
DX’pedition? If you use this constant recording function, you can record and playback the last 30
seconds of received audio or transmitted audio (sidetone when operating in CW mode), allowing
you to check what was said afterwards. In addition, you can use this handy feature for other
purposes, such as recording memos.
It could not be easier to use. From the menus, you set constant recording to ON, and then all you
have to do is operate the CH3/REC key. If you press the CH3/REC key for more than one second,
the last 30 seconds of audio data is recorded in flash ROM. Then when you press the CH3/REC
key the audio data recorded in flash ROM is played back. The audio data in held in flash ROM
until it is overwritten by a fresh recording. Note that when recording to flash ROM, or when other
VGS-1 functions are in use, constant recording is temporarily paused.
●

Constant recording function

●

Message recording/playback function

If beforehand you record standard CQ messages such as your callsign in the voice message
memory, you can transmit them repeatedly at will, a feature that is extremely useful for
DX’peditions and contests.
The main features of this message/recording playback function are as follows:
There are three recording channels;
You can record up to 30 seconds in each channel (using all three channels this allows a
maximum of 90 seconds for message playback);
Used in conjunction with VOX, message playback can be used to switch between TX and RX;
Repeat playback is possible;
You can adjust the interval for repeat playback (0~60 sec.); and
You can adjust recording level.
With VOX on, repeat playback on, and the interval set appropriately, if you play back a
prerecorded message repeatedly, the TS-480 will automatically switch between transmitting the
message and waiting for a response. There is thus no need to sit in front of the mic and actually
repeat your message over and over again.
Even when you use a microphone with low sensitivity to record a message, the TS-480 is
designed to set the appropriate recording level. Normally, this recording level is automatically
linked to the mic gain setting, so if you wish to adjust recording level manually, you should adjust
mic gain while recording is in standby. In message recording mode, the ALC meter scale serves
as a recording level meter. As you speak into the microphone, adjust mic gain so that the recording
level just crosses into the MAX zone occasionally. Even when you record in this zone, the AGC is
designed to keep audio distortion to a minimum.
43

●

Voice Guide

Kenwood’s Voice Guide function is not the same as the basic versions fitted in some transceivers
merely to announce the frequency. Of course, we have included a frequency guide, but we were
convinced that a Voice Guide is an obvious and essential feature for the menus and function
settings that are so crucial for daily operation.
The TS-480 has inherited intact those Voice Guide features that have proved so popular in other
models. However, in addition we have enhanced the Voice Guide functions for the different
configuration modes, and by making it possible to vary the speed (5 levels) we have made sure
that this rig is even more user-friendly.
We have programmed the TS-480 Voice Guide so that it only announces what has been changed
in configuration mode, menus, etc. Thus items that are unchanged are not read out. Previously,
even if there had only been a change in the options, the Voice Guide would read out each item:
“menu”, menu number, option, and so forth. For the TS-480, however, we have changed the Voice
Guide algorithm so that it only announces the option, enabling swift confirmation without you being
forced to listen to unnecessary details being read out.
Normally, Voice1 is assigned to a PF key on the control panel to read out operating frequency,
channel number, the settings for each function, and so on. However, if you reassign a PF key
(using menu #48) to #62, by switching to Voice2 you can hear the S-meter level being read out.
Introduced here are a few of the benefits of the TS-480 Voice Guide. Some of these are automatic,
while others are accessed by the PF keys.
1. Reset
When the power is switched on, if you press the power switch together with either A/B or A=B, the
Voice Guide will automatically respond with the query “VFO/FULL RESET?”
2. Configuration mode for TX output, etc.
When the PWR switch is pressed, the Voice Guide will automatically respond with “TX PWR” plus
the option. If you change the option using the MULTI/CH encoder, just the new option will be
announced. With previous models if one pressed the PF key at this point, the frequency would be
read out, but the TS-480 announces the setting plus the option.
3. Frequency lock
Whenever the MENU button is pressed for more than 1 second, the Voice Guide will automatically
respond with “FREQUENCY LOCK ON” or “FREQUENCY LOCK OFF”, whichever is appropriate.
4. Menu settings
If the MENU button is pressed, the Voice Guide responds with “MENU” plus the menu number
and the option. If you change the option using the MULTI/CH encoder, the menu number and
option will be announced. If the i and j keys are pressed, just the option will be read out. For the
options actually announced for the various menu items, please refer to the menu list provided in
the instruction manual.
5. Split mode
If you press a PF key during split operations, the Voice Guide will read out VFO + S + A +
frequency. (Here “S” stands for split mode, while “A” means VFO A.)

44

6. VFO mode, direct frequency entry
Let us say you are operating at 7.033MHz and in VFO mode you press the PF key, the Voice
Guide will announce “VFO”, “A” or “B”, and 7.033.00. If you use the key pad to input ENT, 2, 1, 1, 9,
5, ENT, you will hear each key announced – “Enter”, “2”, “1”, “point”, “1”, “9”, “5”, and finally “Enter”.
On confirming with the Enter key, you will hear a beep to indicate “T” and then the input frequency
will be read out. Note that in memory channel mode you can also specify channel number for
frequency entry.
7. Memory channel
Let us imagine that the last memory channel you used was 89. Selecting memory channel mode
from VFO mode will cause the Voice Guide to announce “Channel”, “89” and the stored frequency.
Selecting memory scroll mode from VFO mode will cause the Voice Guide to announce “Memory
in”, the channel number, “Blank” if the channel is unused or the stored frequency if it is in use. To
store a frequency in a memory channel, pick the desired channel and once again press QMI; you
will hear a beep to indicate “T” and the data will be written to the memory channel. It will return to
VFO mode when the write has been completed. With quick memory mode, you can call up a
stored frequency with QMR and the Voice Guide will announce “Quick Memory”, the channel
number and the stored frequency.
8. Variable Voice Guide speed
With Menu #16 you can adjust the speed (5 levels) of the Voice Guide to suit your preference. The
factory setting is level 1. Note that as the speed increases, the tone of the voice changes.
9. S-meter level
By assigning the Voice2 function to a PF key, you can hear the S-meter level being read out,
according to the table below. (After operating PF(VOICE2))
Meter level

Voice guide

Meter level

Voice guide

Meter level

Voice guide

0
1–3
4
5
6

S0
S1
S2
S3
S4

7
8
9
10
11

S5
S6
S7
S8
S9

12
13 – 14
15
16 – 17
18
19 – 20

10dB
20dB
30dB
40dB
50dB
60dB

Other features
This is not connected with the Voice Guide, but the TS-480 is also equipped with a feature that has
proved popular on previous models – namely, it issues a beep that serves as an SWR alert when
an error is detected in Morse mode with AT tune.
Also, the TS-480 offers a range of beep functions to facilitate operations. These include issuing an
“end stop beep” to mark an end stop for options, differential beeps to distinguish between ON and
OFF when toggling a key, or to distinguish between configuration mode and completion when
adjusting TX output, etc.
Note:
For those people who do not require the Voice Guide, it is possible to disable it by simply turning
the volume to OFF. Just proceed to menu #15 and select OFF.

45

New Option: ARCP-480 (Amateur Radio Control
Program for TS-480) Freeware
Kenwood’s ARCP software has
proven very popular. For the
TS-480 we have made some
significant improvements, releasing
it as “ARCP-480”.
KNS added
ARCP-480 is compatible with the
Kenwood Network Command
System, enabling control of the
TS-480 over a network and, using
H.323 (VoIP), making voice
transmission/reception
possible.
So that you can enjoy easy control
of the TS-480 from your computer,
both ARCP-480 and ARHP-10 programs (explained later) are available free and can be
downloaded from Kenwood’s website.
URL: http://www.kenwood.com/i/products/info/amateur.html
There is ARCP software for the TS-870 and TS-570, as well as for the TS-2000. As with
ARCP-2000 and the TS-2000, the new ARCP-480 program allows you to control virtually all of the
functions on the TS-480 transceiver. What follows is an explanation of the major differences
between ARCP-2000 and ARCP-480.
●

Main functions

1. Button layout & basic operation
Just as when one uses the tuning control on the TS-480 to change frequency,
how one changes frequency with ARCP-480 is very important. We have made
the ARCP-480 software easier to use by improving the way you use the
mouse to change frequency.
Click on the tuning control icon to enter tuning mode. To raise the frequency,
keep your finger on the left mouse button while turning the mouse to the right.
Similarly, to lower the frequency, keep your finger on the left button while
turning the mouse to the left. To return to normal operations exit tuning mode.
If you want to use a wheel mouse* to change frequency, you can of course work in tuning mode
but even when tuning mode has not been selected the wheel can be used to change frequency by
whatever increment has been set in Click Enc./Step.
(Step no.)
Note that if the TS-480 is currently in a configuration mode, these actions will effectively change
the settings. But in this case a message is displayed, so you can exit from configuration mode
before continuing.
*This feature is only compatible with a genuine Microsoft® IntelliMouse® and driver.

46

2. Changing memory and registered details
You can change any registration data from the
appropriate window. You use this window when
storing new data in memory. Display the
frequency you wish to register and press M.IN.
Then pick the channel (0-89) you want to write to
and press DISP: the memory window (right) will
open. This window now allows you to pick split
operations. If you wish to switch to split mode,
check the TX/End Frequency checkbox and you
can then enter the frequency for the TX station as split memory. By clicking on the box displaying
the frequency you can input the desired frequency, and you can also store it. As with ARCP-2000,
you can input memory names in this window.
3. CW keying
You can also use ARCP for keying. If you think you may have made a mistake while keying,
ARCP-480 allows you to click the Stop button to prevent the message from being sent, although
with previous versions of ARCP you could not do this. Also, you can enter special codes (with a
few exceptions) from the keyboard.
Since you can now enter BT and other
special codes from the keyboard, you do
not have to move your hands from the
home position during a QSO. Also, the
software now allows you to stretch the log
window, which is useful when it becomes
filled with messages. The window can be
closed even during transmission by just
pressing the ESC key.
ARCP-480 does not allow direct keying by
typing, but for it is a fully practical solution
for regular QSO.

Special code input
Special code

Key / Display

Special code

Key / Display

BT

“[“

AS

“<“

KN

“]”

AR

“_”

BK

“\”

HH

“#”

SK

“>“

SN

“%”

47

4. Reading and writing files
With ARCP-480 you can write memory channel and menu data to a file for later recall. This does
not apply in certain cases when using KNS.
●

Compatibility with KNS (Kenwood Network Command System)

KNS is the name for the system that enables remote control of the transceiver over a LAN or
WAN; ARCP-480 is equipped with the remote functions for this system. To use KNS, you need to
have at least 2 computers, the remote one having ARCP installed and the host computer having
ARHP installed.

The basic arrangement is to connect the TS-480 to a host computer, which is on a LAN, and to
install ARHP-10 on this computer. ARCP-480 is then installed on the remote computer.

TX audio & ARCP commands

RX audio & control commands

48

When the system is operating, RX audio and the commands that control ARCP are sent from the
host PC, along with the TX audio and commands controlling the transceiver.
Using this combination of ARCP-480 and ARHP-10, in order to be able to communicate by voice,
and to be able to hear the sidetone when keying, both the host PC and remote PC must be
running Windows® 2000 (SP3 or later) or Windows® XP (SP1 or later). For voice exchanges, the
remote PC must be connected to a microphone for TX audio input, and to a speaker for receiving
audio. These are both plugged into a sound card.
Accidental continuous TX
Inasmuch as KNS is a network-based method for performing remote control over a network, it is
possible that, through some malfunction, the TS-480 installed on the host end might go into
continuous transmission accidentally.
By setting the time-out timer on the TS-480, it is possible to ensure that, after the set time period
has passed, the transceiver will automatically switch back to RX mode. The timer count always
starts with the commencement of transmission, so even in the case of a prolonged but intentional
transmission, after the set period has passed it will switch back to RX; nevertheless, it is a good
way to prevent the transceiver from going into continuous TX mode.
In the event that, following the start of transmission, some network problem arises that prevents
you from executing the command for the transceiver to switch back to RX, the ARHP-10 software
itself is equipped with a function* that, after the passage of a fixed period of time, will switch the
transceiver back to RX mode. However, please make sure that you can obtain rapid access to the
host if a malfunction occurs.**
*This software cannot handle every problem that may occur.
**In Japan only. For details, refer to the laws governing radio transmissions.
Setting up KNS on the ARCP side
First check the LAN/WAN. Ensure that
everything is set up correctly, referring to the
second section on ARHP10, ARCP-480 Help,
and the instruction manuals for your network
devices.*
Before setting up the host side for KNS, you
should first check with the administrator of the
host computer and obtain all necessary
information. This includes the KNS host address,
the command port number, user name and
password, and guidance on how to connect the
audio cable.
Within the setup window, you should fill in the
necessary information in the KENWOOD
NETWORK COMMAND SYSTEM frame. If the
To: combo box is empty, this means that no KNS host has been selected. You should input the
host for the connection using the Setting and Add buttons.
In the KNS Connection Settings window, you should input the name of the other computer as the
connection name, together with its description. For the address, input the IP address of the other
computer. You must also input user name and password. If you are going to use voice

49

communications and the operating system on
either end is compatible, check the Voice box.
(It is possible to enter the description using
double-byte characters. For the address, it is
also possible to enter the domain name,
provided that it can be resolved by DNS.)
Once you have finished, return to the setup
window, select the other computer in the To:
combo box, and check the box labeled Use
Network Command System. In the TX Control
frame, check DTS if the audio cable is
connected to the data terminal of the
transceiver; check PTT if it is connected to the mic and EXT-SP terminals. When you are finished,
click on OK.
The next step is to make the connection by clicking on CON, as you would with any other ARCP
software. If a normal connection is established, the green indicator lights on the CON button.
When you are connected using the KNS system, certain functions are not available. For details,
refer to ARCP/ARHP Help.

* In order to remotely control a transceiver via a
WAN, you must apply for permission. For
details, refer to the instruction manual and the
materials available on our website. Once you have obtained permission, you can use KNS for
remote control, but please make sure you follow correct operational procedure. The above applies
to remote control operations within Japan.
To use KNS via a WAN, you must obtain global IP addresses for the computers running
ARCP and ARHP to enable external access. Note that that when you open a broadband router
port you do so at your own risk.

50

Using a broadband router
Many people using the Internet today use a broadband router (hereafter referred to simply as a
router), but in order to use KNS in a setup that has routers installed at both the host and remote
ends, you need to configure each end separately. With KNS, for transmission and reception using
the TCP protocol you need to open one port for commands and several ports for VoIP. If a router is
compatible with Microsoft® NetMeeting®, by setting it up correctly you should be able to make use
of H.323 (VoIP) voice transmission/reception. For using only ARCP control, you open port 50000
(default) for bidirectional communications using the TCP protocol. If you also want to use VoIP
audio communications, you would normally have to open the following ports:
Ports: 389, 522, 1503, 1720, 1731Protocol: TCP
Direction: bidirectional
Ports: dynamically assigned ports in the range 1024-65535
Protocol: TCP/UDP
Direction: bidirectional
Note that even if the router is compatible with Microsoft® NetMeeting®, you must open the port for
ARCP control for TCP in both directions. To conduct voice communications, in most instances
ports 1503 and 1720 are opened and, if needed, NAT (Network Address Translation) set up to
enable the two parties to converse via VoIP. If you are using a router that is not compatible with
Microsoft® NetMeeting®, you may not be able to conduct voice communications via VoIP, even
with the communications ports open and the correct NAT settings.
If you are using a router with a built-in xDSL modern, it may be possible to enable KNS with the
correct bridge settings.
Once you have opened all these ports, you must be careful about security. Also, if you configure a
bridge, you may require a client and another router externally to use PPPoE* authentication. When
using a PPPoE client, refer to the relevant instruction manual to ensure that everything is set up
correctly, and please remember that you use this feature so at your own risk. Note that a PPPoE
client is available as a standard feature of Windows® XP.
Before opening router ports and making changes to your PC settings and to your network, you
should first carefully read the instruction manuals for the hardware. And remember you do so at
your own risk. Should you make a mistake, you may cause the network to fail or make it
vulnerable to intruders.

51

New Option: ARHP-10
(Amateur Radio Host Program) Freeware
ARHP-10 is the host application for
use with the Kenwood Network
Command
System.
As
was
explained in the section on
ARCP-480, if ARHP-10 is installed
on the host computer it can serve as
the host in a KNS connection.
1. Make an audio/voice cable &
connect the TS-480 to your PC
To conduct voice communications
you require a PC with the Windows®
2000 operating system or a later Windows OS, but in addition you need to connect the transceiver
to the PC with an audio cable.
Kenwood does not supply a cable for this purpose so
you must make up one by yourself. When doing this,
please refer to the wiring diagram on the right.
Illustrated here is the wiring diagram for a cable that uses
the DATA connector. It is also possible to make up a
cable that uses the MIC terminal; to make such a cable,
you will need a RJ-45 crimp tool to attach the connector.
For the MIC terminal wiring diagram, please refer to the
instruction manual.
If using the MIC terminal, you will need a cable in order to
hear the audio received by the TS-480; this connects the
transceiver’s EXT-SP terminal to the input terminal on
the PC sound card.
2. Checking LAN settings
In order to operate KNS, you must first check the correct
settings (operating system, home LAN devices).
In regards to a LAN, by ensuring that each device is set up correctly, communications should be
possible; however, if the connection is made via a WAN, one can suppose that as a result of
various network problems, commands and/or voice may not get through properly. Even in such
cases, you may find that the problem can be solved by changing the network device settings.
Depending on the service offered by your Internet provider, you may find that you cannot obtain a
global IP address or that commands and/or voice are not getting through.
Also, if you are using a router to access the Internet, in addition to opening the command port for
sending and receiving with TCP, if the router is compatible with Microsoft® NetMeeting®, by
making the appropriate “port open” setting it should be possible to conduct voice communications
when KNS is active. Be sure to read carefully the instruction manual before changing the settings
on any network device. You do so at your own risk.

52

3. Adjust PC volume
Whether hosting via a WAN or within a LAN, it is recommended that you test your setup at least
once using a KNS environment arranged with host and remote on the same LAN. This should
allow you to adjust volume to the appropriate level. To adjust terminal level, display the recording
control, confirm that MIC input is selected, and adjust the level. For speaker output level
adjustment, adjust WAVE.
4. User setup
Open the setup window and set the
COM port to be used for commands,
whether or not to use voice
communications, session time, and
whether or not to keep a log. By clicking
on Add, you can then input the name
and password of the user to connect.
The host administrator then informs the
remote PC user of the above user name
and password, as well as other relevant
information such as how to make up an
audio cable (for use with either the DATA
terminal or MIC/EXP-SP). The remote
PC user can then connect to this host
using the information provided.
Note that a red X mark within the user
frame indicates that this user is
temporarily barred from connecting to the
host.
After the setup is completed, you can return to the main window and click on CON; the button will
then appear yellow. This completes the setup: the host is now ready for the remote PC user to
make a connection.
Once the audio cable has been made up, connect the various cables to your PC as illustrated
below.
In addition, connect your PC to the TS-480 with an RS-232 cable.

53

54

●

Troubleshooting

Listed below are typical problems that you might encounter.
Network & Operations
Problem
Solution
Is it possible to use an analog We recommend a broadband connection. Otherwise, if
you have a narrowband connection of about 50kbps, it
dial-up connection?
might work, though this will depend on network traffic
conditions. You must also expect to encounter some noise
and to lose audio contact intermittently.
Yes, it is compatible provided that your ISP provides a
I have broadband but is it
global IP address, VoIP ports, and a command port.
compatible?
Can I use my router with
KNS?

With a high-speed modem
connected directly to my PC
running Windows® XP, KNS
does not work.
I am using a high-speed
modem connected directly to
my PC, but the modem is
inside the router.

We do not guarantee that KNS will work through a router.
Nevertheless, if your router offers DMZ or “virtual
computer” features, you may be able to set it up by
yourself to enable KNS to work properly.
You will have to make the required adjustments, referring
to the instruction manuals for the devices you are currently
using, at your own risk. Generally speaking, you can use
any modem that is compatible with Microsoft®
NetMeeting®. If your operating system is XP, switch off the
ICF (personal firewall) provided by Windows®.
If the ICF (personal firewall) of Windows® XP is switched
on, you should switch it off; however, be aware that this
can represent a security risk.
Switch to a modem that is not inside a router.
Open the ports required for KNS: a command port and
H.323 control ports (if the router is compatible with
Microsoft® NetMeeting®).
If you must use a router with built-in modem, try setting
up a bridge. In this case, however, some ISPs will not
issue an IP address. To solve this, you can either set up
another router (compatible with Microsoft®
NetMeeting®) externally, or have an IP address issued
using a PPPoE* client.
(A PPPoE* client is available as a standard feature of
Windows® XP.)
Be aware that you do all of this at your own risk.

55

I cannot get KNS to work
over the Internet connection
that is provided as a
collective service to my
apartment block.

It is possible that one of more of the ports required by KNS
is blocked. Talk to your network administrator to see if the
requisite ports can be opened.

Can I use a software-based
firewall?

KNS will probably work with your firewall, provided that it is
set up for the ports required by ARCP and ARHP to be
open.
Set the TOT to whatever duration you require. However,
since this simply times your transmission, once the time is
up, it will return the transceiver to RX even if you are in the
middle of transmission.
There is a delay with KNS. If you are using a WAN, this
delay increases, so it is not suitable for the various types of
digital communications or other operations that demand a
quick response. It is also not recommended if audio quality
is a priority.
Owing to the delays inherent in a network, this system is
not compatible with full break-in. For this same reason, it is
also not recommended for operations that require strict
TX/RX timing (contests or pileups). Also, break-in time
should be set longer than usual.

I want to time-out TX after a
set time.
Is KNS compatible with
digital communications
(PSK31, SSTV, etc.)?
Is KNS compatible with full
break-in or quick break-in
times?

56

Sound
Problem
The sound does not get
through (host PC).

The sound does not get
through (remote PC).

Solution
First check that the audio cable is connected properly.
Check what audio input method (MIC/EXP-SP or
DATA) has been selected for the transceiver.
• If the DATA terminal is used:
Use menus #46 & #47 to check that I/O levels are
correct.
• If MIC/EXT-SP is used:
Check that AF level and mic gain are correct.
• Check your computer:
Check that the computer can produce sound; update
drivers as necessary.
Connect the transceiver’s RX audio to the input of your
computer and bring up the recording control window.
Check that the input terminal you are using is active and
that it is set to an appropriate level. Bring up the
playback control window; make sure that it is not muted
and that it is set to an appropriate level. Check that you
can hear something from the speakers connected to
your computer. After you have completed these checks,
mute the PC output.
Check that you are using a compatible operating
system.
Check that Voice is checked in the ARHP-10 setup
window.
If using a WAN, check that KNS will work locally over
your LAN.
If using a WAN, check your communications hardware
and ISP settings. (If you are using a router, try removing
it temporarily to see if that makes a difference.)
Check that KNS VOICE is illuminated in the ARCP-480
display. If it is not, recheck your operating system for
compatibility and also your network settings (including your
ISP service).
First check that the host audio is connected properly.
Check what audio input method (MIC/EXP-SP or
DATA) has been selected for the transceiver on the host
side.
• If the DATA terminal is used:
Use menus #46 & #47 to check that I/O levels are
correct. (Normally, there would be no need for the
remote PC user to think about this.)
• If MIC/EXT-SP is used:
Check that AF level and mic gain are correct.
• Check your computer:
57

Check that the computer can produce sound; update
drivers as necessary.
Connect a microphone to the computer and bring up
the recording control window. Check that the input
terminal you are using is active and that it is set to an
appropriate level. Bring up the playback control window;
make sure that it is not muted and that it is set to an
appropriate level. Check that you can hear something
from the speakers connected to your computer.
Check that you are using a compatible operating
system.
Check that Voice is checked in the ARHP-10 setup
window on the host computer.
Check that KNS VOICE is illuminated in the ARCP-480
display. If it is not, recheck the host computer operating
system for compatibility and also the network settings
(including the ISP service for the host computer).
If using a WAN, check that KNS will work locally over
your LAN.
If using a WAN, check your communications hardware
and ISP settings. (If you are using a router, try removing
it temporarily to see if that makes a difference.)
Check that Voice is checked in the ARCP setup
window.
Check the modulation line. Check that the host PC
audio cable connection method in the TX Control frame
of the Setup window is the same.
TX/RX audio breaks up, is
distorted or faint.

Bring up the playback and recording control windows
on both host and remote computers and try adjusting
the levels.
If the RX audio seems faint, and if the Line-in terminal is
being used for input on the host computer, try switching
to the Mic-in terminal.
If modulation seems faint during TX, and if the Line-out
terminal is being used for output on the host computer,
try switching to the Speaker-out terminal.

58

TS-480 In-Depth Manual
Published in April 2004 by Kenwood Corporation
Communications Equipment Division
Unauthorized reproduction is forbidden.
Copyright © 2004 KENWOOD CORPORATION



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