MULTI-CHANNEL INTEGRATED MRI TRANSMITTER SYSTEM FOR A MAGNETIC RESONANCE IMAGING DEVICE

Abstract

A multi-channel RF transmitter system including a magnetic resonance imaging device, a multi-channel RF coil array, a control computer receiving required parameters from a user, producing triggering and clock signals and synthesizing input data required for each channel of RF coil array according to imaging scenario to be realized, an interface control module producing basic band MRI signals according to data from the control computer, a signal modulator and control module for modulating MRI signals produced at the interface control module into radio frequency and distribution to channels, a power/data distribution module distributing the produced signals and required DC power, a RF power amplifier module converting digital signal coming from the power/data distribution module into analog signal, amplifying it and transmitting to members of the coil array, a feedback line for track and correction of any errors in RF signal transmitted to the coil array by the power amplifier module.

Claims

1. A multi-channel RF transmitter system for magnetic resonance imaging device, characterized in comprising: a multi-channel RF coil array having N pieces of members, located inside a magnetic resonance imaging device; a control device having a data input interface for receiving required system parameters from the user, and adapted for synthesizing input data required for each channel of RF coil array selected by user or an algorithm depending on imaging scenario to be realized and generation of trigger and clock signals required for simultaneous working of all units of the magnetic resonance imaging device; an interface control module adapted to generate basic band MRI signal sequence according to imaging scenario produced by user in control device; a signal modulator and control module using trigger and clock signals from control device, synchronously working with magnetic resonance imaging device, taking basic band MRI signal sequence generated at the interface control module, adapted for increasing it to a predetermined RF carrier frequency by means of digital modulation method and transmission of this digital RF modulation signal to RF coil channels; a fibre optic line providing transfer of signals to be transmitted from interface control module to the signal modulator and control module; a Power/data distribution module buggering digital RF modulation MRI signal sequence generated by the signal modulator and control module and transmitting to an RF power amplifier module via a RF driver module through the RF coil array and filtering DC power required for this RF power amplifier module on RF coil array; a RF power amplifier module converting digital RF modulated MRI signal sequence having desired modulation, phase and amplitude coming from power/data distribution module into analogue signal, and amplifying and transmitting to members of the coil array, integrated with the coil array and comprising a power amplifier block in number equal to number of channels of the coil array; a RF driver module driving a RF power amplifier module after raising signal level at input of the RF power amplifier module to a required power level; a feedback line comprising a RF switching module selecting channels of which data will be read for track and correction of errors that might occur in RF signal transmitted to the coil array by the power amplifier module, and a demodulator module minimizing the signals received from selected channels to basic band and sending them to the signal modulator and control module and; a power supply providing the power to be distributed by power/data distribution module.

2. A multi-channel RF transmitter system for a magnetic resonance imaging device according to claim 1, characterized in comprising a coil array driven by a RF power amplifier block of each member having a digital input and analog output.

3. A multi-channel RF transmitter system for magnetic resonance imaging device according to claim 1, characterized in comprising power amplifier module comprises RF power amplifier blocks driven by DSM based amplitude, phase and frequency modulation signals independent of each other.

4. A multi-channel RF transmitter system for magnetic resonance imaging device according to claim 1, characterized in comprising a control device comprising a data input interface having a mouse, keyboard and/or touch screen.

5. A multi-channel RF transmitter system for magnetic resonance imaging device according to claim 4, characterized in comprising a control device consisting of a data input interface providing selection of channel and providing inputting phase, amplitude, frequency and RF pulse envelope form data of selected channel

6. A multi-channel RF transmitter system for magnetic resonance imaging device according to claim 1, characterized in comprising a RF coupler located at output of each RF power amplifier module and sending the power both transmitted to each coil array member upon amplifying and power returning from each coil array member to analogue digital converters at demodulator module via a return feeding line.

7. A multi-channel RF transmitter system for magnetic resonance imaging device according to claim 6, characterized in comprising a signal modulator and control module adapted for receiving and processing MRI signal sample received from feedback line by a coupler located at output of each RF power amplifier module and transmitting to control device.

8. A multi-channel RF transmitter system for magnetic resonance imaging device according to claim 1, characterized in comprising a control device comprising a MRI control computer generating triggering and clock signals required for simultaneous operation of all units of magnetic resonance imaging device and having a data input interface for control of magnetic resonance imaging device by user, and an interface control computer having a data input interface for receiving required system parameters from user, a data interface for connection to MRI control computer and synthesizing input data required for each channel of the RF coil array selected by user or an algorithm according to imaging scenario to be realized.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0008] In order to achieve the purpose of the invention, multi-channel RF transmitter coil chain system for a magnetic resonance imaging device is shown in the attached figures, which are:

[0009] FIG. 1 is a schematic view of RF transmitter system for magnetic resonance imaging device.

[0010] FIG. 2 is a schematic view of internal structure of RF power amplifier module.

[0011] The parts indicated in the figures have been designated separate numbers and said numbers are given below: [0012] 1. Multi-channel RF transmitter system [0013] 2. Magnetic resonance imaging device [0014] 3. Coil array [0015] 4. Control device [0016] 4.1. Interface control computer [0017] 4.2. MRI control computer [0018] 5. Interface control module [0019] 6. Signal modulator and control module [0020] 7. Fibre optic line [0021] 8. Power/data distribution module [0022] 9. RF driver module [0023] 10. Power amplifier module [0024] 10.1. Power amplifier block [0025] 10.2. Coupler [0026] 10.2.1. Transmitted Power measurement channel [0027] 10.2.2. Returning Power measurement channel [0028] 11. Feedback line [0029] 11.1. RF switching module [0030] 11.2. demodulator module [0031] 12. Power supply [0032] F. Faraday cage [0033] N. Object to be imaged

[0034] A multi-channel RF transmitter system (1) for a magnetic resonance imaging device (2) basically consists of [0035] a multi-channel RF coil array (3) having N pieces of members, located inside a magnetic resonance imaging device (2), [0036] a control device (4) providing control of magnetic resonance imaging device (2) by user, having a data input interface for receiving required system parameters from the user, and adapted for synthesizing input data required for each channel of RF coil (3) array selected by user or an algorithm depending on imaging scenario to be realized and generation of trigger and clock signals required for simultaneous working of all units of the magnetic resonance imaging device (2) [0037] an interface control module (5) adapted to generate base band MRI signal sequence according to imaging scenario produced by user in control device (4), [0038] a signal modulator and control module (6) using trigger and clock signals from control device (4) synchronously working with magnetic resonance imaging device (2), taking basic band MRI signal sequence generated at interface control module (5), adapted for increasing it to a predetermined RF carrier frequency by means of digital modulation method and transmission of this digital RF modulation signal to RF coil channels, [0039] A fiber optic line (7) providing transfer of signals to be transmitted from interface control module (5) to signal modulator and control module (6), [0040] a Power/data distribution module (8) buggering digital RF modulation MRI signal sequence generated by signal modulator and control module (6) and transmitting to RF power amplifier module (10) via a RF driver module (9) through RF coil chain (3) and filtering DC power required for this RF power amplifier module (10) on RF coil chain (3), [0041] A RF power amplifier module (10) converting digital RF modulated MRI signal sequence having desired modulation, phase and amplitude coming from power/data distribution module (8) into analogue signal by use of a filter, and using a dynamic envelope modulator to increase power efficiency and thus amplifying MRI signal sequence, transmitting analogue MRI signal amplified efficiently to elements of RF coil array (3), integrated with coil array (3) and consisting of power amplifier block (10.1) in number equal to number of channels of coil array (3), [0042] A RF driver module (9) driving a RF power amplifier module (10) after raising signal level at input of RF power amplifier module (10) to required power level, [0043] A RF coupler (10.2) located at output of each RF power amplifier block (10.1) and sending the power both transmitted to each coil array element upon amplifying and power returning from each coil array element to analogue to digital converters at demodulator module (11.2) via return feeding line, [0044] A feedback line (11) consisting of a RF switching module (11.1) selecting channels of which data will be read for track and correction of errors that might occur in RF signal transmitted to coil array (3) by power amplifier module (10), and a demodulator module (11.2) converting the signals received from selected channels to base band by an analogue to digital converter and sending them to signal modulator and control module (6), [0045] A power supply (12) providing the power to be distributed by power/data distribution module (8).

[0046] FIG. 1 shows a block diagram of novel system consisting of multi-channel RF transmitter equipment located onto RF coil array (3) for magnetic resonance imaging device (2). This system contains a magnetic resonance imaging device (2) and a signal modulator and control module (6) in a faraday cage (F). Aforementioned magnetic resonance imaging device (2) consists of a multi-channel RF coil array (3) a power amplifier module (10) integrated with the coil array (3), a RF driver module (9) connected to power amplifier module (10), power/data distribution module (8) connected to signal modulator and control module (6) and feedback line (11) connected to power amplifier module (10) by signal modulator and control module (6). Outside of aforementioned faraday cage (F), there are an interface control module (5) connected to signal modulator and control module (6), a control device (4) connected to interface control module (5) and a power supply (12) connected to power/data distribution module (8).

[0047] In a preferred embodiment of the invention, each member of multi-channel coil array (3) developed for magnetic resonance imaging device (2) has a RF power amplifier block (10.1) with digital input and analog output. Aforementioned each RF power amplifier block (10.1) in power amplifier module (10) can be driven by DSM based amplitude, phase and frequency modulated digital signals independent of each other. RF signals intended to be sent to RF coil array (3) come to power amplifier module (10) in digital form and the digitally modulated signal is converted to analog RF signal by power amplifier module (10) and amplified and is sent to elements of RF coil array (3) via transmitted power measurement channel (10.2.1). Since coils used in magnetic resonance imaging device (2) are narrow band having high Q factor, they recover Signal Noise Rate of output signal.

[0048] Trigger and clock signals are required for synchronization of new multi-channel RF transmitter system (1) with magnetic resonance imaging device (2) are transmitted from control device (4) to signal modulator and control module (6). System parameters (for instance selection of channels, phase, amplitude, frequency of selected channels and RF pulse envelope form details etc. inter-channel settings entered by user) determined by use of a data input interface (for instance, mouse, keyboard and/or touch screen . . . ) on control device (4) by user from interface control module (5) are collected and sent to interface control module (5) firstly; then the formed base band MRI signal according to the received information transferred to signal modulator and control module (6) via fiber optic lines (7). Signal modulator and control module (6) modulates modulation, amplitude, phase, frequency and pulse envelope form data coming from interface control module (5) into radio frequency and produces signal to be applied to each channel and transmits to power/data distribution module (8). Power/data distribution module (8) buffers the coming digital signals and distributes to related RF driver module (9). Power amplifier module (10) driven by RF driver module (9) sends the signal carrying the desired modulation, phase and amplitude values to coil array (3) elements and forms required stimulation distribution in the area to be imaged in this way.

[0049] While the above operations are ongoing, MRG signals which are obtained via couplers, which are located at the output of each RF power amplifier modules (10), are processed by signal modulator and control module (6) and are transmitted to control computer (4) for controlling patient safety during MRI as well as track-correction of errors that might occur in given MRI signal. Control computer (4) estimates the S-parameters of coil array (3) in line with the coming data and may produce signal for generation of desired current on members of the coil array (3).

[0050] In an embodiment of the invention, control device (4) is designed as a single computer. In another embodiment of the invention, aforementioned control device (4) consists of MRI control computers (4.2) consisting of an interface control computer (4.1) instead of a single computer and MRI control computer (4.2) used in present magnetic resonance imaging devices (2) connected to this interface control computer (4.1). In this embodiment of the invention, MRI control computer (4.2) is a unit having a data input interface producing triggering and clock signals required for simultaneous operation of all units of the magnetic resonance imaging device (2). Interface control computer (4.1) is the unit having a data interface for connection to a data input interface, MRI control computer (4.2) for receipt of required system from user, synthesizing input data required for each channel of RF coil array (3) by user or an algorithm according to imaging scenario to be realized, in other words, separately programming each coil channel.