NASA Facts

National Aeronautics and Space Administration

Jet Propulsion Laboratory

California Institute of Technology

Pasadena, CA 91109

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Mars Polar Lander/Deep Space 2 First Signal

What if we don’t hear from Mars Polar Lander at 12:39 p.m. PST on
Friday, December 3, when it is scheduled to radio Earth following
its landing?

That window is only the first of several communications
opportunities over the weekend when we might possibly hear from
the lander for the first time. Any one of several factors could
delay first contact without preventing the lander from
establishing communication and carrying out a full mission. These
factors generally fall into two categories: telecommunications
issues, or a spacecraft “safing” event.

So if you don’t hear from the lander right away, what happens

First, it should be kept in mind that the 12:39 p.m. PST time is
an estimate of when the lander’s signal would first reach Earth.
Under the best of circumstances, it may take a few minutes to lock
onto the signal and establish contact.

If we do not have the signal within a few minutes of the start
time, teams will begin checking ground systems at Deep Space
Network stations and elsewhere to make sure that the problem is
not on the Earth end. We would then continue listening until the
lander’s first transmission would be scheduled to end, at
approximately 1:25 p.m. PST.

What happens then?

The next time we would listen for the lander would be during a
40-minute window beginning at 2:04 p.m. PST landing day. Polar
Lander would transmit at this time if it entered a safe mode
immediately upon touchdown.

What is a “safing” event, and how could it happen?

All planetary spacecraft are loaded with “fault protection”
software designed to safeguard the craft in the event of various
kinds of unusual events. When certain events take place, this
software puts the spacecraft into a so-called “safe” mode that
protects it and places it in standby, awaiting intervention by
ground controllers. Fault protection software is usually disabled
during critical flight events such as landings, orbit insertions
and some flybys in order to prevent a minor glitch from
interfering the event.

In the case of Polar Lander, the fault protection software is
disabled about 18 hours before landing so that it does not
interfere with the critical events of entry, descent and landing.
It is then reenabled about 10 minutes after landing during the
period when the lander is unfolding its solar panels and preparing
to transmit to Earth. If an event triggers the fault protection
software immediately when it is reenabled after the lander touches
down, the spacecraft will be put into a “safe” mode. In this mode,
it shuts down activities and goes into its low-power “sleep” mode.
It would then automatically start transmitting to Earth at about
2:04 p.m. PST.

What if a safing event took place as the lander was closing in on
its approach to Mars? Would you have enough time to recover the
spacecraft so that it could land properly?

The fault protection software is disabled 18 hours before landing
to make sure that there is enough time to reconfigure the
spacecraft. If a safing event took place at any time up to this
disabling point, there should be ample time to reset the lander
for entry, descent and landing.

So if you do not hear from the lander during this 2:04 p.m.
window, what happens then?

Our next step would be to investigate the possibility that the
lander’s dish antenna is not pointed close enough to Earth to
establish contact. To get a good communication session and hear
telemetry, or data, from the lander, the antenna must be pointed
within about 5 degrees of Earth. If the antenna is pointed more
than about 15 degrees away from Earth, we would not hear a carrier
signal at all.

At about 6:27 p.m. PST on landing day, we would send commands to
the lander to carry out a procedure designed to help it find
Earth. In this procedure, the lander transmits while it moves its
dish antenna from one point to another, gradually covering the
entire horizon. Sending these commands would be completed by 7:27
p.m. PST. The lander would then carry out the procedure attempting
to transmit to Earth while it moves its antenna from 8:08 to 10:40
p.m. PST.

If this procedure doesn’t result in a signal, what is your next

There is a window on Saturday evening, December 4, during which
the lander would transmit if it experienced a slightly different
safing event. You will recall from the above that the lander would
transmit on Friday afternoon if it entered safe mode immediately
upon touchdown. If it went into safe mode sometime after touchdown
but before its first transmission session began, it would shut
itself down and wait until Saturday evening to transmit to Earth.
This signal would be expected during a window between 8:30 and
10:45 p.m. Saturday, December 4.

Another possibility is that, even though we haven’t heard from it
for some reason, the lander could be carrying out its normal
post-landing activities. If this were the case, it would be
scheduled to transmit data to Earth during a window from 8:50 to
10:50 p.m. Saturday, December 4. Although it is difficult to say
why we would not have already heard from the lander if it were
otherwise operating relatively normally, we would listen during
this window just to make sure that we didn’t miss a possible

Would you send more commands to the lander?

Very probably so. Depending on exactly what we are seeing, we
might send commands instructing the lander to switch between its
main and backup radio or computer systems. There is a window
during which we might send commands from 6:35 to 8:05 p.m.
Saturday, December 4.


Lander Communications Windows

All times Pacific Standard Time
(PST = UTC – 8 hours)

12:39 – 1:25 p.m. Friday 12/3 Transmission if antenna is pointed at

2:04 – 2:44 p.m. Friday 12/3 Transmission if lander entered safe
mode at touchdown

6:27 – 7:27 p.m. Friday 12/3 Window to send commands to lander

8:08 – 10:40 p.m. Friday 12/3 Transmission if lander is executing
normal activities,
or using its dish antenna to find

6:35 – 8:05 p.m. Saturday 12/4 Window to send commands to lander

8:30 – 10:45 p.m. Saturday 12/4 Transmission if lander entered safe
mode just after touchdown

8:50 – 10:50 p.m. Saturday 12/4 Transmission if lander is executing
normal activities

10:50 – 11 a.m. Sunday 12/5 Transmission if antenna is pointed at



What about later opportunities?

One possible scenario is that the power amplifier on the
transmitter that the lander uses to communicate directly with
Earth — called its “X-band” transmitter — could not be working
right for some reason. This is one of few components on the
spacecraft that do not have an identical backup. If the lander
doesn’t hear any commands from Earth telling it not to do so, it
would automatically switch to another radio, called the UHF
transmitter, and would send data to the orbiting Mars Global
Surveyor spacecraft. Global Surveyor would relay these data in
turn to Earth.

If this happened, the lander would transmit to Global Surveyor
between 10:50 and 11 a.m. PST on Sunday, December 5. Global
Surveyor would relay the data to Earth immediately.

If you haven’t heard from the lander by the end of the weekend,
what would you do next?

At this point it is likely that we would continue sending commands
for several days instructing the lander to swap out various
hardware systems. There is also another milestone that we would
investigate. The lander has what is called a “command loss timer”
that counts how long it has been since the last time it received a
command from Earth. If it does not hear from Earth for six days,
this system “times out” and the spacecraft assumes it has a
hardware failure somewhere. It then begins swapping between main
and backup systems in its flight computer, radio, etc., and
attempts to contact Earth. This would take place early morning
Mars time on sol 6 (the evening of Thursday, December 9) if the
lander has received no commands from Earth after landing. Since we
would have been sending commands to the lander well before this,
the likelihood of receiving a signal at this time would not be
strong. However, for the sake of completeness we would listen for

How many systems on the spacecraft have identical backups?

Most systems such as the computer and radios are redundant. There
is only one power amplifier for the X-band transmitter and only
one dish antenna, but the lander can switch to the UHF transmitter
if the X-band system isn’t working. A few other parts of the
lander such as the robot arm do not have backups.

The lander will be out of touch with Earth for half an hour during
its entry, descent and landing. Even if the lander cannot send
data to Earth during its descent to Mars, why can’t it send a
carrier signal or “beacon” signals like Mars Pathfinder did?

The reason that the lander cannot send a signal to Earth during
descent is mostly dictated by the geometry of landing near Mars’
south pole. As the spacecraft descends through the atmosphere, an
ionization layer builds up around it that is very difficult to
transmit through. In addition, there was concern that attempting
to send a signal from the lander at this point might interfere
with onboard electronic systems. We decided to take all steps to
protect the lander as it descends, even though this means we will
be out of touch with it as it descends.

What about the Deep Space 2 microprobes? What if we don’t hear
from them right away on Friday evening, December 3?

It is possible that communications with the microprobes could be
delayed by factors such as the orientation of the probes following
impact or the temperature at the impact sites. If communication is
not established during the first relay pass by Mars Global
Surveyor on Friday evening, December 3, we will continue listening
for the probes every two hours as Global Surveyor passes over the
impact site throughout the weekend.

The microprobes wait to hear a command from Mars Global Surveyor
before they transmit. If the probes’ radio receivers are
compromised, it is possible that they may not receive this command
correctly. Just like Polar Lander, each of the microprobes has a
“command loss timer” that keeps track of the last time each probe
received a command from Earth via Global Surveyor. If they do not
hear from Global Surveyor within 29 and 32 hours of impact,
respectively, they will automatically begin transmitting to Global
Surveyor. If we do not hear from the probes on Friday evening, it
is very possible that we might hear from them late afternoon or
early evening Saturday, December 4.