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Claims  |
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I claim:
1. A universally applicable, automatic, vehicular toll paying system
comprised of,
a pre-paid cash balance registration means that electronically extracts
stored data from and inserts a newly computed pre-paid cash balance into
the memories associated with a vehicle borne transponder-data-processor,
and then transfers all said registration data to an independent
bookkeeping system,
a vehicle borne microwave transponder-data processor that permanently
stores, in its read-only-memory, a vehicle-owner code, a payment agent
code and a vehicle class code; receives vehicle entry location data, by
microwave transmission, for temporary storage in one of its read-write
memories, and upon subsequent coded interrogation, transmits all said
identification and entry location data, receiving back a toll amount from
a pre-paid balance that is stored in a second read-write memory, said
balance being visually displayed; and upon completion of the subtraction,
transmitting a code that indicates if the balance is negative or not,
a toll booth transponder-computer which periodically transmits, by
microwave, an interrogation code and receives back from a passing vehicle
transponder, following the interrogation, stored data from which said
transponder-computer calculates a toll and transmits said toll amount back
to said vehicle transponder, receiving back either a pass or reject code,
or no response, said response activating appropriate vehicle pass or
reject apparatus and the results of said transaction are transferred to an
independent bookkeeping system, and
a toll system entry location microwave transmitter, that periodically
transmits a fixed code followed by that entry location's identification
code.
2. A universally applicable, automatic toll paying method is comprised of
the steps of,
electronically inserting the amount of cash pre-paid to a collection agent,
into the memory of a vehicle borne microwave transponder-data processor by
means of an individual entry code, said code being derived from said
vehicle transponder's permanently stored identification codes,
receiving and temporarily storing appropriately coded vehicle entry
location data that is transmitted from a roadside data entry transmitter
to a passing vehicle's transponder upon its entry to a toll facility, said
data being later used for a toll computation, and
transmitting permanently stored vehicle-owner and vehicle class
identification codes, a collection agent code and temporarily stored entry
location data, if applicable, from said vehicle transponder, after
interrogation from a microwave transponder-computer located at an
automatic toll collection booth, said transponder-computer upon receipt of
said data calculates a toll and transmits said toll amount to said vehicle
transponder where the toll is fed into a subtraction register, subtracted
from the stored pre-paid cash balance, said balance being displayed to
vehicle occupants, and if new balance is not negative, sends a transaction
acceptance or rejection code to said toll booth transponder to actuate
appropriate vehicle pass or obstruct apparatus, and finally enters said
toll charge and vehicle identification codes into an independent
bookkeeping system for purpose of billing the collection agent and serving
other record keeping functions.
3. A universally applicable, automatic toll paying system that is comprised
of,
a cash balance increase registration means that connects with a vehicle
borne microwave transponder-data processor to extract an owner-vehicle
identification code, a payment agency identification code and the current
stored balance; adds the cash payment to the current stored balance
gaining entry to said transponder for said procedure using a code
determined from said identification codes by cryptographic procedures
programmed into said register's computer; and reads out said vehicle-owner
identification codes, the cash paid and the new balance into an
independent bookkeeping system,
a vehicle borne, microwave transponder-data processor which stores vehicle
entry location codes received from roadside data entry transmitters and
upon interrogation from a toll collecting transponder, reads out and
erases said entry location codes and reads out the permanently stored
owner-vehicle identification codes and payment agent code, and then
receives, by return microwave transmission, a computed toll amount which
is read into a subtraction register, subtracts toll from said stored
current pre-paid balance, the old balance being erased and said new
balance is read into the memory and visually displayed, and transaction
acceptance or rejection code is transmitted, telling whether subtraction
results is a negative balance or not, and
a toll booth microwave transponder-computer that interrogates passing
vehicles by coded, narrow beamed microwave transmissions requesting stored
data from passing vehicle transponders, and upon receipt of said stored
data, calculates the toll, transmits toll amount by coded microwave
transmission, and subsequently receives a transaction approval or
rejection code which activates appropriate vehicle pass or reject
mechanism and also transfers said toll, vehicle owner identification code
and payment agent code into an independent bookkeeping system.
4. Same as claimed in claim 3, but where the vehicle transponder includes a
tone generator that is activated when a negative or zero pre-paid balance
appears in the cash balance memory following its interrogation.
5. Same as claimed in claim 3, but optionally including an independent
means to check vehicle class or size at toll payment booth so as to verify
vehicle identification class data stored in vehicle transponder's read
only memory, and also to include a means to inhibit vehicle passage if
check is not positive.
6. Same as claimed in claim 3, but including a half duplex, amplitude
modulated, data and clock transmission method in which clock information
is sent as short pulses preceding each data bit and data bits consist of
trapezoidal pulses for "ones" and no-pulses for "zeros", said composite
signal is separated after reception by a differentiating circuit, an
integrating circuit and diode thresholders in both circuits, said
separation resulting in one output lead containing data and another output
lead containing clock information.
7. A universally applicable, automatic toll paying apparatus comprised of,
a vehicle mounted microwave transponder-data processor, which includes a
wide beam microwave antenna; a microwave detector and very low power
transmitter; a permanent read only memory; a temporary read-write memory;
a shift register for performing subtraction; a read-write memory and
associated electronic display for retaining current cash balance;
transaction sequence control circuitry; and a decoder that responds to an
individually derived crypto code, which controls balance increasing
transactions,
a toll booth microwave transponder-computer which includes a relatively
narrow beam microwave antenna; a moderate power microwave transmitter and
super heterodyne receiver; a computer, for computing a toll from received
information; a vehicle pass means for responding to a received transaction
approval code; a means for transferring toll and vehicle and collection
agent codes from computer into an independent bookkeeping system, and
a microwave transmitter, located at entry locations to a toll facility
where tolls are computed based on where vehicle entered and exited the
facility, periodically transmits a vehicle transponder entry code followed
by a code that identifies the entry location,
a cash balance increase registration means that includes a means for
electrically and electromagnetically connecting said registration means to
said vehicle borne transponder; a microwave receiver-transmitter; a
computer for determining the correct individual entry code from the
vehicle mounted transponder's permanently stored identification codes; a
summing register, which receives the current stored balance from said
vehicle transponder's memory adds the cash payment and inserts new balance
with said entry code; and a means for transferring paid cash amount,
current cash balance and vehicle identification codes into an independent
bookkeeping system for cash and credit transfers.
8. Same as claimed in claim 7, in which the vehicle transponder includes a
latched battery power switch that applies d.c. power to all circuits,
except the transponder, the pre-paid balance memory and the display, which
always receive power, and said switch, normally opened, is latched closed
when microwave energy is detected, said latch being removed and switch
opened upon receipt of end-of-transaction-signal, after which said switch
is inhibited from being closed again for several minutes by a continuously
powered timing circuit.
9. Same as claimed in claim 7 in which the vehicle's microwave transponder
is comprised of a single microwave device serving as both a detector of
microwave energy and a source of transmitted microwave energy, being
operated as one or the other sequentially by a d.c. bias across said
device.
10. Same as claimed in claim 9 in which microwave transponder device is
comprised of a microwave tunnel diode, a tuning inductor, a by-pass
capacitor and two series quarter wave sections with a shunt microwave
resistor between them. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The maximum cost benefit factor that can be derived from an automatic toll
paying system is achieved when the system is universally applicable. Toll
facilities differ in means of collection and in base rates, the rates
often depending on the number of vehicle axles as well as distance
traveled. A convenient system would have a motorist pay a lump sum of any
amount to any toll authority, and be credited for that amount against
future tolls. Any automatic toll paying method must have a relatively
simple and efficient means of transferring funds, with appropriate checks
and balances. The system must be relatively tamper-proof, fool-proof,
enforceable and must operate through snow, ice, rain, fog, dirt and for
any expected speed of the vehicle. A properly implemented system would
also reduce toll facility operating expenses, save the driver time and
fuel, and generate less air pollution for the toll facilities' neighbors.
Present methods aimed at implementing such a service employ only automatic
vehicle identification. Such methods require intricate centralized
computer facilities for storing and extracting billing information from
potentially tens of millions of possible users for each toll transaction.
These methods lack flexibility and user connection. They also can create
massive operational failures and a feeling on the part of users of being
dependent on large, complex and silent computers.
SUMMARY OF THE INVENTION
The universally applicable, automatic system for paying tolls from moving
vehicles, described by this invention, would operate in the following
manner. Each vehicle using the system would use clearly marked toll lanes
that are equipped with a microwave transponder-computer. The vehicle would
have a microwave transponder-data-processor on board which carries in its
memory a pre-paid balance. As the vehicle approaches the toll facility, it
is interrogated by a microwave transponder located at the toll booth. This
interrogation releases the vehicle's permanently stored identification
code, payment agent's code, vehicle class and, if required, the vehicle's
entry location to the facility. A computer at the toll booth calculates
the toll from the received information and transmits the amount to the
vehicle's transponder. This toll is then subtracted from the stored
pre-paid balance. If the balance is not negative, the vehicle is passed
through.
The pre-paid balance is paid to a specified agent or authority whose
identity is established via a permanently inserted number into the vehicle
transponder's memory. Only this agent would have the ability to increase
the stored, pre-paid balance for that vehicle using equipment which
includes a crypto entry code derived from the vehicle's ID number and a
microwave data injection means. Batteries are charged up during this stop.
The cash collection agency is then billed by each toll facility that the
vehicle might subsequently use. A complete double entry computerized
record system can be established from the available data.
The automatic toll paying system is comprised of three major components,
the vehicle borne transponder-data-processor, the toll booth
transponder-computer and an increasing-cash-balance register. The vehicle
borne transponder includes a microwave antenna, detector and transmitter
means, memories, logic and computational circuitry and a visual display.
The toll booth transponder includes a directional antenna, a
superheterodyne receiver, a transmitter, a computer connected to a means
for waiving or inhibiting the passage of vehicles that have an
insufficient balance or do not have a transponder.
The pre-paid balance is always displayed to the driver by a liquid crystal
display. A negative balance can be indicated by a tone when approaching
the toll booth. A weak battery is indicated by the display. The preferred
vehicle transponder's detector-transmitter described uses a tunnel diode.
The power drain of the transponder is near zero until the tunnel diode
detector is illuminated. This illumination latches the battery on so it
powers the rest of the transponder. When the transaction is complete, the
power is turned off except to the pre-paid balance memory and liquid
crystal display. The battery latch cannot be turned on again for some
designated period thereafter.
The use of very low power microwave has no known health hazard and will
penetrate snow, ice, rain, fog and dirt. The transaction is, within
reason, independent of vehicular speed, taking several milli-seconds to
complete. The computerized bookkeeping system, made possible by this
system, can account for unauthorized pre-paid balance credits, stolen
transponders, and failed batteries that lose the paid up balance
information. The various aspects and advantages of this invention will be
more fully understood from a consideration of the following detailed
description in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a pictorial representation of the toll facility with microwave
transponder, approaching vehicle and transponder.
FIG. 2 illustrates a preferred digital modulation for communicating clock
and data information and
FIG. 2a illustrates a diplexing circuit for separating clock and data
signals.
FIG. 3 illustrates a functional block diagram of a preferred vehicle
transponder.
FIG. 3a illustrates circuit details of a tunnel diode transponder.
FIG. 3b illustrates a self-timed decoder and actuator.
FIG. 3c illustrates detail of a permanent memory means for vehicle and
payment agency identification.
FIG. 4 illustrates a functional block diagram of the apparatus that adds
the pre-paid amount into a vehicle transponder.
FIG. 5 illustrates external details of the vehicle transponder.
FIG. 6 illustrates a functional block diagram of a payment toll booth
transponder.
FIG. 7 illustrates a functional block diagram of an entrance location
identifying toll booth transponder.
DETAILED DESCRIPTION OF THE INVENTION
This invention describes a system for automatically paying all types of
tolls without the need for individual cash transactions or vehicle stops.
It consists of both a system and preferred apparatus to implement the
system. The apparatus includes a vehicle borne microwave
transponder-data-processor, a toll both transponder-computer and
registration equipment for increasing the pre-paid cash balance stored in
the vehicle transponder's memory.
FIG. 1 is a pictorial diagram illustrating the physical locations of the
apparatus required for this automatic toll paying system. A vehicle, 10,
is shown approaching a toll facility transponder 12. The vehicle has its
transponder 14 located so it is visible through its front window. The
vehicle may have been interrogated earlier to warn the driver if his
pre-paid cash balance is too low. Vehicle sensor, 15, is optional and used
to spot check or verify vehicle classification, such as number of axles,
this information being normally transferred from vehicle transponder's
memory. Toll transponder 12 initiates the transaction by transmitting a
microwave signal modulated with a transaction initiating code which is
then acknowledged by vehicle transponder 14 with its stored identification
codes plus other information. From this information, a toll is computed by
a computer at the toll booth. The amount of this toll is then transmitted
via microwave back to vehicle transponder 14 and is subtracted from the
pre-paid balance stored in the vehicle transponder's memory. If the
balance is not negative, a transaction approval code is transmitted which
activates a pass permission signal. If the balance is negative, a code is
sent which activates a pass denying action.
The automatic toll paying process begins with a cash payment for the
vehicle transponder with a balance registered in its memory, usually equal
to the cash payment. When the transponder is initially issued, a vehicle
and owner identification code plus the cash collection agency's code, if
pertinent, is permanently inserted into the transponder's
read-only-memory. Along with this code a number is stored indicating the
vehicle's class and a cryptographically derived balance increasing entry
code. The permanent method of vehicle classification requires that cars
pulling trailers cannot use the automatic toll lanes and truck cabs
without their trailers would not want to use the automatic toll lanes.
Some independent means of vehicle class verification may also be required.
When a vehicle enters a turnpike, where the toll depends on knowing entry
and exit locations, the entry location is registered in the vehicle
transponder's memory as the vehicle enters such a roadway. A toll gate
transmitter reads out its location to each entering vehicle's transponder.
This is stored in a read-write memory. When the vehicle leaves the road
system, this entry location is read out and transmitted along with the
vehicle classification and identification codes. The transponder has a
visual display to indicate the current balance and state of the battery to
the driver. Also a tone can be emitted, if upon toll booth interrogation,
the balance become negative.
When the driver wishes to increase his pre-paid balance, he drives to a
cash collection agent representative's booth in whose name the transponder
was issued. The agent could be a local toll facility authority. The agent
increases the stored balance by the amount of cash paid which is inserted
into the vehicle's transponder by special apparatus. The battery is also
recharged, and the transaction results are transferred to a permanent
bookkeeping system. All subsequent tolls charged to this vehicle will be
paid to each billing toll authority by the collection agency that received
the cash payment. Since the vehicle's identification and its toll charges
are available, an independent automatic double entry bookkeeping system
can be set up for transferring funds, for balancing books, for
compensating drivers whose battery might have died losing the pre-paid
balance or to spot stolen transponders or users in arears.
The apparatus to implement this automatic toll paying system uses microwave
transmissions because of their relative immunity to snow, ice, rain, fog
and dirt. The microwave communications used is half duplex, meaning
transmission and reception occur at the same approximate frequency but
never simultaneously. This provides the simplest transmission means. Since
interactive computer processes are carried out in short sequential data
bursts, there is no inexpensive conventional method to clock the data in
and out. Therefore, the data modulation to be employed, which will be
amplitude modulation, includes quickly accessible clock information sent
with the data. The preferred method of sending this information is
illustrated in FIG. 2. Clock pulses 20 are narrow occurring periodically
at the clock rate just prior to each data bit. The data pulse 22,
representing ones, have gradual ramp slopes, zeros are represented by an
absence of any ramp pulse, 24. Clock pulses 20 can be separated out from
the ramp data pulse by a differentiating capacitor-resistor and diode
combination, 25, shown in FIG. 2a. Integrating resistor-capacitor-diode
combination 26 separates out the data pulses. The complete circuit, called
a data diplexer is referred to frequently in the following detailed
description.
FIG. 3 illustrates a functional block diagram of the vehicle transponder.
Antenna 30 receives and transmits microwave energy over a wide angular
sector. In this illustrative example, a tunnel diode is used for both
detection of received signals and for transmitting amplitude modulated
microwave energy. The details of receiver-transmitter 32 and amplifier 34
are shown in FIG. 3a. The preferred receiver/transmitter consists of
tunnel diode 36, tuning inductor 37, by-pass capacitor 38, and a microwave
circuit comprised of two series quarter wave line sections, 39 and 39a,
and shunt microwave resistor 40 inserted between them. The quarter wave
sections 39 and resistor 40 prevent moding of tunnel diode oscillation and
fix the frequency more precisely. Transistor 41 applies a positive
modulation voltage to the tunnel diode, assuring a low impedance across
the diode while biasing the diode into oscillation. Diode 42 clamps that
voltage. When the tunnel diode is biased into oscillation, transistor 43
is turned off. When there is no voltage applied to the tunnel diode, it
acts as a detector. Diode 44 maintains a near zero emitter base voltage,
on transistor 43. When a microwave signal is detected, a negative voltage
is generated across the tunnel diode causing transistor 43 to conduct
current. This conduction is further amplified in subsequent amplifier 34
providing adequate output signal to operate all subsequent transponder
functions. An equivalent design can be derived for a GaAs FET transistor
in place of the tunnel diode which can also serve both as a detector and
oscillator.
Amplifier 34 draws negligible current until a microwave signal is detected
in R/T 32. The receipt of signal turns on the amplifier and latches switch
46 into a closed position, to power all circuits from battery 47.
Normally, without a received signal, only the liquid crystal display 98,
its memory 92, and amplifier 34, receive battery power.
The first possible transaction occurs when a vehicle enters a turnpike, for
example. The toll booth transmitter, at an entry point, sends a coded
message comprised of entry code #1 and the entry point's location code.
This code is received by decoder 48 described in FIG. 3b. It is comprised
of data diplexer 28, decoder 50 and flip flop 51, which is reset by
terminal lead 52. Decoder 43 recognizes its code and places memory 54 in a
read-in status and opens gate 56. The data is then clocked into read-write
memory 54, by data diplexer 58, entry gates 58a, b and c and stepping
counter 60. Transmissions from the initial address code are blocked by
gate 62 at this time. When step 7 of stepping counter is reached, decoder
48 is turned off. The turn-off is marked by differentiator 64, whose
impulse feeds through gate 66, which has also been opened by step 7. This
process clears stepping counter 60 and completes the data entry.
The next possible transaction occurs at a toll payment gate. At such a
gate, code #2 is transmitted periodically with empty time allocated to
receive responses. When code #2 is received, decoder 68 opens gate 70,
biases data diplexer 58, on and puts memory 54 into its read-out mode. As
clock 72 feeds in its narrow clock pulses, a binary word is generated by
stepping counter 60, each data bit actuated by the trailing edge of the
narrow clock pulses. Timing clock pulses that precede each data bit are
added to the transmitted data stream through gate 74. These pulses
combined with the data pulses create the modulation illustrated in FIG. 2.
As step counter 60 progresses, it first generates addressing code A, then
the vehicle's entry point to the toll facility, if stored, and then the
vehicle's classification and identification codes and cash collection
agent's code, which are permanently stored in the ROM positions marked 76.
When this read-out is completed, decoder 68 is reset. FIG. 3c, illustrates
one means of permanently inserting the vehicle's and agent's codes. This
consists of a plastic card with a conductive surface marked by darkened
areas 78. Holes, 80, punched in the card mark zeros and no holes mark
ones. Contact fingers connect with each conductive mark. The word
illustrated here is 00110.
When code 3 is received by decoder 32, gate 84 opens to clock pulses into
sequencer 86, which controls the steps required to computer a new balance.
Step 1 reads in the toll charge into shift register 88 through gate 89 and
data diplexer 90. Step 2 reads out and clears display memory 92, reading
its contents into register 94 through gate 95. Step 3 carries out the
subtraction process. Step 4 reads the new number from register 96 into
display memory 92 through gate 97. Memory 92 also activates liquid crystal
display 98 indicating the new balance. Step 5 reads out an
end-of-transaction code from coder 100 which includes information if the
balance is a negative number or not. If a negative balance occurs, an
optical tone generator 101 can be actuated by gate 102 to warn the driver
that he should seek a cash toll collection lane. This tone can also be
activated early in the toll booth approach phase. The end-of-transaction
code opens battery latching switch 46, activated by flip flop 104, which
is fired by output of coder 100. Latching switch 46 cannot be closed again
for several minutes being inhibited by counter 103 thereby avoiding double
billing for slow traffic. Decoder 110 and gate 112 are used to increase
the stored balance in memory 92. Decoder 110 has an individualized code
stored in it that is related to the vehicle's ID code. The process of
inserting a new pre-paid balance is carried out by register equipment
described by the functional block diagram illustrated in FIG. 4 and some
of the circuits described in FIG. 3.
When a lump sum cash payment is made, the driver hands over his vehicle's
transponder to the collection agent who places the transponder into a
register (Please see FIG. 4) that connects into pins a, b, c, d, e and f,
open normally closed pin jack 106 and also charging battery via pin 108.
The cash payment is registered on register key board 120 and flashes on
display 122. Push button 124a enters the pre-paid cash amount into adder
126 and also actuates code 2 from coder 127, which modulates the microwave
transmitter in R/T 128, which is connected to transducer 130 that is
placed in proximity with antenna 30. Transmission of code 2 actuates
transmission of the vehicle's identification and agent codes from the
vehicle's transponder. These identification codes are received by the
detector in R/T 128. Entry code A is identified by decoder 132, opening
gate 138, feeding its received signals to data diplexer 140 which enters
the identification codes into computer 142. Computer 142 determines entry
code 4 from that transponder's identification code, using a cryptographic
sequence and then resets decoder 132. If the collection agent's code is
correct, computer 142 reads out derived entry code 4, and code 3 followed
by a string of zeros which is modulated onto the microwave transmitter in
R/T 128.
A new balance is determined in adder 126 by the following sequence. Clock
signals from clock 72 are transferred to the register via pin f. Switch
106 is opened by pin pressure. This open position prevents data stored in
memory 92 from being transferred to register 96. Instead the current
balance is read-out into adder 126 through pin c. The read-in and addition
sequence is signaled by a voltage appearing on pins a and b from sequencer
86. When the addition is completed, the sum is read into memory 92 via pin
d and through gate 112, which is opened by SDA 110. When this step is
complete, decoder 110 is reset to zero by a signal on pin e. The
transponder is now removed from the register and all normal functions are
restored. The data from the transaction is transferred from computer 142
to a permanent computerized bookkeeping system.
FIG. 5 illustrates the exterior of a typical vehicle transponder. It is
about 4".times.2".times.3/4", encased in plastic. Antenna array 30 is
imbedded in the plastic case located a quarter wavelength above a ground
plane. The antenna is a metal foil, end fed tapered array with 90.degree.
bends to make the physical orientation of the transponder not important to
its function. Liquid crystal display 98 indicates the current balance and
the battery condition. The pin array, 150, contains all the pins described
previously for increasing the pre-paid balance. The permanent cash
collection agent's name is also inscribed on the plastic case.
FIG. 6 illustrates a preferred functional block diagram of the toll payment
transponder. Antenna 160 generates a beam that is approximately 15.degree.
wide in all directions. Ferrite duplexer 162 connects Gunn oscillator
transmitter 164 and super-heterodyne receiver 166 to antenna 160. Receiver
166 is squelched whenever transmissions occur. Clock 168 controls the
transponder. It periodically actuates code 2 generator, 170. The transmit
period being determined by divider 172. When code A is received from a
vehicle transponder it is identified by decoder 174 which closes gate 176
and opens gate 178, passing the vehicle's identification numbers into
computer 180 through data diplexer 182. When the toll is computed, code 3
is generated and is followed by the toll amount. The vehicle-owner
identification code and the toll is read out of computer 180 into an
independent bookkeeping system. When the end of message code is received
by decoder 184 with a negative balance indication, a vehicle
non-admittance sequence is actuated, otherwise a vehicle pass indication
is actuated. The end of message code resets decoder 174. If vehicles
remain stopped at a toll entrance for periods of more than several
minutes, a stopped vehicle detector closes gate 177 and stops all
transactions until suitable vehicle motion is detected. This prevents
stalled vehicles from being billed several times.
FIG. 7 illustrates a preferred functional block diagram of a turnpike entry
location read-in transponder. Antenna 160 and transmitter 164 comprise the
microwave components. Clock 189 periodically activates coder 188 through
divider 190. Coder 188 generates entry code 2 and the entrance location
code.
Although the preferred system described here depends on an advance payment,
a credit system can also be adapted where instead of subtracting from a
pre-paid balance a sum is continually added to the memory. The system, as
a pre-paid system, is also useful in parking lots, high speed refueling
stations, as a pass to enter restricted areas or for any other billing or
paying system where the speed of the transaction is significant. The
system can also be modified for receiving roadway information. Most of the
illustrative circuits described use hard wired logic. Microprocessors with
software can also be programmed to do the same functions.
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